Measurements of Neutrino Mass: Volume 170 International School of Physics 'Enrico Fermi' (Proceedings of the International School of Physics 'enrico Fermi' Course)

` ITALIANA DI FISICA SOCIETA

RENDICONTI DELLA

SCUOLA INTERNAZIONALE DI FISICA “ENRICO FERMI”

CLXX Corso a cura di F. Ferroni e F. Vissani Direttori del Corso e di C. Brofferio

VARENNA SUL LAGO DI COMO VILLA MONASTERO

17 – 27 June 2008

Misure della massa del neutrino 2009

` ITALIANA DI FISICA SOCIETA BOLOGNA-ITALY

ITALIAN PHYSICAL SOCIETY

PROCEEDINGS OF THE

INTERNATIONAL SCHOOL OF PHYSICS “ENRICO FERMI”

Course CLXX edited by F. Ferroni and F. Vissani Directors of the Course and C. Brofferio

VARENNA ON LAKE COMO VILLA MONASTERO

17 – 27 June 2008

Measurements of Neutrino Mass 2009

AMSTERDAM, OXFORD, TOKIO, WASHINGTON DC

c 2009 by Societ` Copyright  a Italiana di Fisica All rights reserved. No part of this publication may be reproduced, stored in a retrieval system, or transmitted, in any form or any means, electronic, mechanical, photocopying, recording or otherwise, without the prior permission of the copyright owner. ISSN 0074-784X ISBN 978-1-60750-038-4 (IOS) ISBN 978-88-7438-047-3 (SIF) Library of Congress Control Number: 2009931830 Production Manager A. Oleandri

Copy Editor M. Missiroli

jointly published and distributed by: IOS PRESS Nieuwe Hemweg 6B 1013 BG Amsterdam The Netherlands fax: +31 20 620 34 19 [email protected]

` ITALIANA DI FISICA SOCIETA Via Saragozza 12 40123 Bologna Italy fax: +39 051 581340 [email protected]

Distributor in the UK and Ireland Gazelle Books Services Ltd. White Cross Mills Hightown Lancaster LA1 4XS United Kingdom fax: +44 1524 63232 [email protected]

Distributor in the USA and Canada IOS Press, Inc. 4502 Rachael Manor Drive Fairfax, VA 22032 USA fax: +1 703 323 3668 [email protected]

Propriet` a Letteraria Riservata Printed in Italy

Supported by Istituto Nazionale di Fisica Nucleare (INFN) Consiglio Nazionale delle Ricerche (CNR) CAEN, Viareggio, Lucca SIMIC, Camerana, Cuneo

(www.caen.it) (www.simic.it)

Dipartimento di Fisica, Universit` a di Genova INFN, Laboratori Nazionali del Gran Sasso Dipartimento di Fisica “G. Occhialini”, Universit` a di Milano-Bicocca

This page intentionally left blank

INDICE

C. Brofferio, F. Ferroni and F. Vissani – Preface . . . . . . . . . . . . . . . . .

pag.XVII

Gruppo fotografico dei partecipanti al Corso . . . . . . . . . . . . . . . . . . . . . . . . . .

XXII

E. Fiorini – Weak interaction in nuclei . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1

1. 2. 3. 4.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Parity violation in weak interactions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Neutrino oscillations and the problem of the neutrino mass . . . . . . . . . . . . . Direct and indirect ways to determine the neutrino mass . . . . . . . . . . . . . . . . 4 1. Single-beta decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2. Measurements on the Cosmic Ray Background . . . . . . . . . . . . . . . . . . . 4 3. Double-beta decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3.1. Experimental approach . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3.2. Present results and future experiments . . . . . . . . . . . . . . . . . . . 5. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1 2 5 7 7 7 8 10 12 17

A. Strumia – Phenomenology of neutrino masses . . . . . . . . . . . . . . . . . . . . .

21

1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12. 13. 14. 15. 16. 17. 18.

Massless neutrinos in the Standard Model . . . . . . . . . . . . . . . . . . . . . . . . . . . Detecting neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Massive neutrinos beyond the SM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pure Majorana neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Pure Dirac neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Oscillations in vacuum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Vacuum oscillations of 3 neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Atmospheric oscillations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Solar oscillations: KamLAND . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The MSW effect . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Matter oscillations of Majorana or Dirac neutrinos . . . . . . . . . . . . . . . . . . . . Oscillations in constant matter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Oscillations in a varying density . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Solar neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Known unknowns . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . β-decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Neutrino-less double-β decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cosmology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

21 21 22 25 27 29 33 34 35 36 37 38 40 42 43 44 46 47 VII

indice

VIII

P. Vogel – Nuclear physics aspects of double-beta decay . . . . . . . . . . . . . . .

pag.

49

1. Introduction to ββ decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Mechanism of the 0νββ decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . RPV SUSY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . LRSM . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Overview of the experimental status of the search for ββ decay . . . . . . . . . 4. Basic nuclear physics of ββ decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5. Decay rate formulae . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1. 2ν decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2. 0ν rate . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Exact expressions for the transition operator . . . . . . . . . . . . . . . . . . . . 6. Nuclear structure issues . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1. Nuclear shell model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2. QRPA basics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3. Generalization - RQRPA . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. Numerical calculations in QRPA and RQRPA . . . . . . . . . . . . . . . . . . . . . . . . . 7 1. Competition between “pairing” and “broken pairs” . . . . . . . . . . . . . . . . 7 2. Dependence on the radial distance . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8. Calculated M 0ν values . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Appendix A. Neutrino magnetic moment and the distinction between Dirac and Majorana neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

49 58 62 64 65 69 71 71 74 77 78 78 82 85 86 90 92 95

A. Bettini – The mass of the particles . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

105

1. 2. 3. 4. 5. 6. 7. 8. 9. 10.

97

Basic concepts: energy, momentum, mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wrong and confused concepts of energy, momentum and mass . . . . . . . . . . Energy, momentum and mass of the electromagnetic field . . . . . . . . . . . . . . Waves, dispersion relation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The masses of the flavoured neutral mesons . . . . . . . . . . . . . . . . . . . . . . . . . . Neutrinos . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The mass of strongly decaying hadrons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The quark masses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The mass of the hadrons . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

105 108 110 115 120 122 126 130 135 138

A. Giuliani – Neutrinoless double-beta decay: impact, status and experimental techniques . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

141

1. Neutrino mass and Double Beta Decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1. Neutrino flavour oscillations and neutrino mass . . . . . . . . . . . . . . . . . . . 1 2. The neutrino mass scale: a threefold concept . . . . . . . . . . . . . . . . . . . . 2. Experimental challenge and strategies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Experimental approaches and methods . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2. The experimental sensitivity . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Present experimental situation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 1. The Heidelberg-Moscow experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. The NEMO3 experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3. The CUORICINO experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

141 142 143 145 146 148 149 149 150 151

indice

IX

4. The future projects and the related technologies . . . . . . . . . . . . . . . . . . . . . . . 4 1. Selection of the candidates and of the technologies . . . . . . . . . . . . . . . . 4 2. Classification and overview of the experiments . . . . . . . . . . . . . . . . . . 5. Prospects and conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1. Quasi degenerate neutrino mass pattern . . . . . . . . . . . . . . . . . . . . . . . . . 5 2. Inverted Hierarchy neutrino mass pattern . . . . . . . . . . . . . . . . . . . . . . . 5 3. Directed Hierarchy neutrino mass pattern . . . . . . . . . . . . . . . . . . . . . .

´ndez, A. Poves, E. Caurier and F. Nowacki – Deformation J. Mene and the nuclear matrix elements of the neutrinoless ββ decay . . . . . . . . . . . . 1. 2. 3. 4. 5. 6.

pag. 152 152 154 160 160 161 161

163

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ISM vs. QRPA nuclear matrix elements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The influence of deformation in the NME’s . . . . . . . . . . . . . . . . . . . . . . . . . . 0ν (unphysical) mirror decays: a case study . . . . . . . . . . . . . . . . . . . . . . . . . . 2ν (unphysical) mirror decays: a case study . . . . . . . . . . . . . . . . . . . . . . . . . . Summary . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

163 164 166 168 171 171

D. Frekers – Charge-exchange reactions and nuclear matrix elements for ββ decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

175

1. 2. 3. 4. 5. 6.

Charge-exchange reactions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The case of 48 Ca and 64 Zn . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The case of 76 Ge . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The case of 96 Zr . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The case of 100 Mo . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

175 177 179 182 182 183

S. Pastor – Cosmological probes of neutrino masses . . . . . . . . . . . . . . . . . . .

187

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. The cosmic neutrino background . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Relic neutrino production and decoupling . . . . . . . . . . . . . . . . . . . . . . . 2 2. Background evolution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Neutrinos and primordial nucleosynthesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4. Extra radiation and the effective number of neutrinos . . . . . . . . . . . . . . . . . 5. Neutrino oscillations in the Early Universe . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1. Active-active neutrino oscillations: relic neutrino asymmetries . . . . . . 5 2. Active-sterile neutrino oscillations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6. Massive neutrinos as Dark Matter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. Effects of neutrino masses on cosmology . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 1. Brief description of cosmological observables . . . . . . . . . . . . . . . . . . . . . 7 2. Neutrino free streaming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3. Impact of massive neutrinos on the matter power spectrum . . . . . . . . . 7 4. Impact of massive neutrinos on the CMB anisotropy spectrum . . . . . 8. Current bounds on neutrino masses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 1. CMB anisotropies . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 2. Galaxy redshift surveys . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

187 188 188 191 193 194 195 196 197 198 201 201 202 204 206 207 207 208

indice

X

. 8 3. Lyman-α forest . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 4. Summary and discussion of current bounds . . . . . . . . . . . . . . . . . . . . . 9. Future sensitivities on neutrino masses from cosmology . . . . . . . . . . . . . . . . 10. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

C. Weinheimer – Direct determination of neutrino mass from 3 H β-spectrum

pag. 209 210 211 212

215

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Neutrino mass from the tritium β decay spectrum . . . . . . . . . . . . . . . . . . . . 3. Previous tritium neutrino mass experiments . . . . . . . . . . . . . . . . . . . . . . . . . . 3 1. MAC-E-Filter . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. The Mainz neutrino mass experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3. The Troitsk neutrino mass experiment . . . . . . . . . . . . . . . . . . . . . . . . . 4. The Karlsruhe tritium neutrino experiment KATRIN . . . . . . . . . . . . . . . . . . 5. Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

215 218 225 227 230 231 232 241

P. de Bernardis and S. Masi – Precision measurements of the Cosmic Microwave Background . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

245

1. 2. 3. 4.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Modern cosmology and the CMB . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CMB observables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CMB observation techniques . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 1. CMB observation sites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2. Detectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3. Optics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CMB anisotropy: current status and open issues . . . . . . . . . . . . . . . . . . . . . . Testing inflation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1. CMB polarization measurements . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . High-resolution CMB observations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 1. Sunyaev-Zeldovich effect . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 2. Wavelength spectrum of CMB anisotropy . . . . . . . . . . . . . . . . . . . . . . . . 7 3. CMB anisotropy and large-scale structure . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

245 245 249 250 251 253 255 258 259 260 262 262 264 265 265

´ – Theory of neutrino masses and mixings . . . . . . . . . . . . . . . G. Senjanovic

269

1. Foreword . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Standard Model review . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. The see-saw mechanism . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 1. Right-handed neutrinos: type-I see-saw . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. Y = 2, SU (2)L triplet Higgs: type-II see-saw . . . . . . . . . . . . . . . . . . . . . 3 3. Y = 0, SU (2)L triplet fermion: type-III see-saw . . . . . . . . . . . . . . . . . 4. Left-right symmetry and neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 1. Parity as L-R symmetry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 2. Left-Right symmetry and massive neutrinos . . . . . . . . . . . . . . . . . . . . . . 4 3. Charge conjugation as L-R symmetry . . . . . . . . . . . . . . . . . . . . . . . . . .

269 270 271 273 273 274 275 277 277 279 281

5. 6. 7.

8.

indice

XI

5. SU (5): A prototype GUT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1. Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1.1. Fermions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1.2. Interactions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2. Symmetry breaking . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Yukawa couplings and fermion mass relations . . . . . . . . . . . . . . . . . . . . 5 3.1. Generations and their mixings . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4. Low-energy predictions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4.1. Ordinary SU (5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 4.2. Supersymmetric SU (5) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 5. SU (5) and neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6. SO(10): family unified . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1. Yukawa sector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2. An instructive failure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 3. Non-supersymmetric SO(10) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 4. Supersymmetric case . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. Majorana neutrinos: lepton number violation and the origin of neutrino mass . 7 1. Neutrinoless double-β decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 2. Lepton number violation at colliders . . . . . . . . . . . . . . . . . . . . . . . . . . . 8. Summary and outlook . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Appendix A. Dirac and Majorana masses . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Appendix B. Majorana spinors: Feynman rules . . . . . . . . . . . . . . . . . . . . . . . . . . Appendix C. SU (N ) group theory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Appendix D. SO(2N ) group theory . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D 1. SO(2N ): spinors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D 2. The ket notation for spinors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D 3. SO(2): a prototype for SO(4n + 2) . . . . . . . . . . . . . . . . . . . . . . . . . . . . Dual representation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Yukawa couplings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D 4. SO(4) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . D 5. SO(6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Yukawa couplings in SO(6) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

F. Gatti – Calorimetric beta spectroscopy . . . . . . . . . . . . . . . . . . . . . . . . . . . 1. 2. 3. 4. 5. 6. 7.

pag. 282 282 282 283 284 286 287 289 289 290 292 295 297 298 299 302 306 307 308 311 312 313 314 315 316 317 318 318 319 319 320 321 323

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Towards the calorimetric single-event detection . . . . . . . . . . . . . . . . . . . . . . . The calorimetric measurement of neutrino mass . . . . . . . . . . . . . . . . . . . . . . The case of a Re metal detector for studying 187 Re decay . . . . . . . . . . . . . . First detector prototypes and pilot experiments . . . . . . . . . . . . . . . . . . . . . . Towards a sub-eV mν calorimetric experiment . . . . . . . . . . . . . . . . . . . . . . . Conclusion . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

323 325 329 331 334 337 339

A. Riotto – Leptogenesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

341

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. The Sakharov criteria . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Baryon number violation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1.1. B-violation in Grand Unified Theories . . . . . . . . . . . . . . . . . . . . 2 2. B-violation in the electroweak theory . . . . . . . . . . . . . . . . . . . . . . . . . .

341 343 344 344 345

indice

XII

3. Some necessary notions of cosmology and equilibrium thermodynamics . . . . 3 1. Expansion rate, number density, and entropy . . . . . . . . . . . . . . . . . . . . 3 2. Local thermal equilibrium and chemical equilibrium . . . . . . . . . . . . . . 4. The standard out-of-equilibrium decay scenario . . . . . . . . . . . . . . . . . . . . . . . . 4 1. The conditions for the out-of-equilibrium decay scenario . . . . . . . . . . . 4 2. The production of the baryon asymmetry . . . . . . . . . . . . . . . . . . . . . . . . 4 2.1. An explicit example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4 3. Baryon number violation within the SM and out-of-equilibrium baryogenesis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5. Baryogenesis via leptogenesis: one-flavour approximation . . . . . . . . . . . . . . . . 5 1. Strong wash-out regime . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2. Weak wash-out regime . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Implications of one-flavour leptogenesis . . . . . . . . . . . . . . . . . . . . . . . . 6. Comments on baryogenesis via leptogenesis when flavours are accounted for 7. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

pag. 347 347 351 353 354 356 360 362 363 367 367 369 371 374

A. Yu. Smirnov – Measurements of neutrino mass. Concluding remarks . .

377

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Phenomenology of neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Three observables . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 2. Mass-dependent processes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 3. Astrophysics and neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Analysing results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 1. Three conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2. Heidelberg-Moscow result . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3. Beyond the Standard Model . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4. Nature of neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5. Masses and mixing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 1. Test equalities . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2. Three lines in the bottom-up approach . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3. Absolute scale without measurements . . . . . . . . . . . . . . . . . . . . . . . . . . 6. Predicting neutrino mass . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 1. Koide relations . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 2. Main line . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7. Implications of the neutrino mass measurements . . . . . . . . . . . . . . . . . . . . . . . 7 1. Type of spectra and implications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 2. Quasi-degenerate spectrum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3. Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8. In conclusion of concluding remarks . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

377 379 379 381 381 382 382 383 384 384 387 387 387 389 389 389 390 391 391 391 392 393

POSTERS M. A. Acero, C. Giunti and M. Laveder – νe and ν¯e disappearance in Gallium and reactor experiments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1. 2. 3. 4.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Gallium experiments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Bugey and Chooz reactor experiments . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

395 395 396 396 397

indice

XIII

M. Antonello on behalf of the ArgoNeuT Collaboration – Feasibility study for a measurement of the QE νμ CC cross-section with the ArgoNeuT liquid-argon TPC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1. 2. 3. 4. 5.

pag. 399

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The cross-section problem . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The ArgoNeuT detector at the NuMI beam . . . . . . . . . . . . . . . . . . . . . . . . . . The QE νμ CC cross-section measurement . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

399 399 400 400 401

F. Cappella on behalf of DAMA Collaboration – Search for ββ decay modes at LNGS by DAMA experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

403

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Search for ββ decay with DAMA/LXe set-up . . . . . . . . . . . . . . . . . . . . . . . . 3. Search for ββ decay with DAMA/R&D set-up . . . . . . . . . . . . . . . . . . . . . . .

403 403 404

E. Carrara – Development of nuclear emulsions for the OPERA experiment 1. The OPERA experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 1. The CNGS neutrino beam . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Emulsion cloud chambers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Emulsion development . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Development facility . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

D. Di Ferdinando and G. Sirri – First events from the OPERA detector at Gran Sasso . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1. 2. 3. 4. 5.

407 407 408 408 409 409

411

The OPERA experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . The detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Strategy for ν event location . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . First physics run . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

411 412 413 413 414

D. Di Ferdinando and G. Sirri – Automated scanning of OPERA emulsion films . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

415

1. 2. 3. 4. 5.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Nuclear emulsions. OPERA target . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Automatic scanning system . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Scanning performances . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

415 416 416 417 418

A. di Vacri for the GERDA Collaboration – The GERDA experiment and first results from phase-I detector operation in LAr/LN2 . . . . . . . . . . . .

419

1. GERmanium Detector Array at LNGS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. 0νββ searches with HPGe detectors: experimental considerations . . . . . . . . 3. 76 Ge 0νββ decay: present status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

419 420 420

indice

XIV

4. GERDA phases and discovery potential . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5. GERDA phase-I prototype detectors . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

pag. 420 421 422

E. Ferri on behalf of the MARE Collaboration – MARE-1: A nextgeneration calorimetric neutrino mass experiment . . . . . . . . . . . . . . . . . . . . . .

423

1. 2. 3. 4.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . MARE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Detector performance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Enviromental background . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

423 424 425 425

L. Gironi, M. A. Carrettoni, C. G. Maiano and L. M. Pattavina – Different approaches to CUORE background analysis . . . . . . . . . . . . . . . . . . .

427

1. 2. 3. 4. 5.

Introduction - 0νdbd . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Double-beta decay with TeO2 bolometers . . . . . . . . . . . . . . . . . . . . . . . . . . . . Coincidences and pulse shape analysis . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CUORE Background . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Surface contaminations and recontaminations . . . . . . . . . . . . . . . . . . . . . . . .

427 428 428 429 429

I. Gnesi on behalf of PAINUC Collaboration – Intermediate-energies π-induced reactions studied with a streamer chamber . . . . . . . . . . . . . . . . . . .

431

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Brief description of the experimental apparatus . . . . . . . . . . . . . . . . . . . . . . . 3. Experimental results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

431 432 432

A. A. Machado, G. Pagliaroli, F. Vissani and W. Fulgione – Features of SN signal for massive neutrinos using LVD simulated events . . . . . .

435

1. The LVD experiment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Events simulation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1. Time delay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3. Conclusions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

435 437 438 438

M. Nemevˇ sek, B. Bajc and I. Dorˇ sner – Minimal renormalizable SO(10) splits supersymmetry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

439

1. Minimal renormalizable supersymmetric SO(10) . . . . . . . . . . . . . . . . . . . . . . 2. The overall neutrino scale and proton decay lifetime . . . . . . . . . . . . . . . . . . . 3. MSSM vs. split supersymmetry . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

439 441 441

C. C. Nishi – Absolute neutrino mass from helicity measurements . . . . . . .

443

1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2. Pion decay . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

443 444

indice

XV

P. Risso on behalf of the Borexino Collaboration – First year of Borexino data acquisition: Background analysis . . . . . . . . . . . . . . . . . . . . . . . 1. 2. 3. 4. 5. 6.

pag. 447

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Physics of Borexino . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Borexino detector . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Background components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Data analysis and results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Future perspectives . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

447 447 448 449 450 451

Elenco dei partecipanti . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

443

This page intentionally left blank

Preface

In the early days, neutrinos were regarded with suspicion. The correspondence of Heisenberg and Pauli, recalled in the lecture of F. Gatti, has not been published; the first version of Fermi’s theory of weak interactions was rejected by Nature; one year later, a paper of Bethe and Peierls argued that neutrinos were not observable in practice. It took 20 years to change the general pessimistic attitude. This was eventually demonstrated by the Savannah Rivers experiment, recognized by the Nobel prize awarded to Reines. Subsequently, it was realized that it was possible to learn a lot from these particles. We recall three outstanding and relatively recent achievements in neutrino physics. Their neutral current interactions, as seen in Gargamelle, provided the first proof of the correctness of the Standard Model. Neutrino astronomy made its first steps with solar and supernova neutrino observations, as recognized by the Nobel prize awarded to Davis and Koshiba. Finally, and most importantly for us, the fact that neutrino oscillations have been convincingly seen in atmospheric neutrinos closed the discussion on solar neutrino anomaly, present since late sixties in Homestake data. Nowadays, it is a common opinion that there are 3 massive neutrinos with mass difference squared (50 meV)2 and (9 meV)2 . These lead to oscillations as predicted by Pontecorvo and then, precisely accounted for by Wolfenstein, Mikheyev and Smirnov. The moral is that the study of neutrinos was and remains demanding but also rewarding, as argued by E. Fiorini in this School(1 ). The new frontier is the search for other effects of neutrino masses, besides those seen with oscillations; but the search for these effects turned out to be particularly difficult and remains a goal to be achieved. The difficulties were immediately evident to early investigators. It is remarkable that, just after his seminal papers on oscillations (conceived as a quantum phenomenon that provides experimental access to tiny neutrino (1 ) A remarkable review is Pontecorvo’s “Pages in the development of neutrino physics”. XVII

XVIII

Preface

masses) Pontecorvo wrote the theoretical paper “Superweak interactions and double beta decay”, to remark the possibility that the rate of the neutrinoless double-beta transition is not the small rate controlled by neutrino masses, but much larger and potentially observable. After so many years, we are continuing not only to pursue Majorana’s original ideas, but also to elaborate and update the hypothesis that the transition is dominated by other contributions, besides those due to neutrino masses. This was addressed, in particular, in the lectures of P. Vogel. But neutrinoless double-beta experiments show impressive progresses and we are nearing the mass scales suggested by oscillations. Indeed, we will soon explore the 100 meV region of neutrino masses with a new generation of experiments, including CUORE and GERDA at the Gran Sasso Laboratory, possibly improvable to even smaller values —see the lectures of A. Giuliani. These developments come with many promises, such as clarifying the meaning of the result of Klapdor-Kleingrothaus, probing the Majorana nature of neutrinos, observing for the first time lepton number violating effects, searching for glimpses of new physics, etc. The crucial preliminary need will be to quantify the impact of the nuclear structure on the neutrinoless double-beta transition rate, as stressed by P. Vogel and A. Poves. Signals of improvement with respect to the situation of the recent past, when the uncertainties amounted to a factor of two or larger, are apparently emerging. Certain concrete hopes to solve some aspects of this difficult problem by a campaign of experimental measurements have been discussed by D. Frekers(2 ). The oldest method to search for neutrino masses, namely to look for features in beta decay spectra (as already proposed by Fermi) is still very actively pursued and has been widely discussed at the School. C. Weinheimer focused on the study of the end point of the spectrum and explained the impressive effort of KATRIN to cover the region of masses above 200 meV in the next few years. A similar goal in the more distant future is the one of the MARE experiment, based on different experimental principles and covering the whole beta spectrum: this has been discussed in the lecture of F. Gatti. Both lecturers enriched their lecture notes with rich historical overviews and precious introductory material. The rapid advances of cosmology transformed a field that till recently was dominated by theoretical speculations into a quantitative branch of physics, where the possibility of performing increasingly precise measurements is becoming a reality. This was discussed by P. de Bernardis, whose experiment, BOOMERanG, opened the way to “precision cosmology”. The lectures of S. Pastor provided further introduction to the matter, addressing the question on whether it is possible to measure neutrino masses in cosmology. Despite the observational and theoretical systematics, on which we need to work further, (2 ) A specific remark is in order; the neutrinoless double-beta transition rate varies quadratically with its nuclear matrix element. By increasing the time (or the mass) of measurement we can improve on it but much more slowly, the scaling in the presence of background being with the square root. Thus, a 20% difference in the nuclear matrix element is equivalent to a factor two difference in the time of measurement. In this important case, a theoretical improvement is more urgent than the experimental one to know if we will be able to achieve a measurement.

Preface

XIX

there are ambitious but realistic chances to probe, in the next decade and using different techniques, the minimal neutrino mass of the inverse hierarchy case (i.e., whether the sum of the three neutrino masses exceeds 100 meV). Surely enough, the study of cosmology remains a very exciting field where the numerous links of neutrinos with astroparticle physics get continuously renewed; all this made these two lectures enthusiastically attended. A large space at the School has been allocated for theoretical topics. A. Bettini gave a learned and stimulating lecture on the evolution of the concept of mass in particle physics. A. Strumia offered a status report of oscillations neutrinos and collected the basic essential material to fully appreciate the other lectures and the current discussion on neutrino masses. A. Yu. Smirnov provided a wide view on the many possible situations that we may be meeting in future years, that now we can only conceive as theoretical possibilities. G. Senjanovi´c lectured on the continuing efforts to understand neutrinos in gauge theories and reminded us of many deep links of the physics of neutrino masses with other lines of research, including the search for new particles in LHC and future accelerators. A. Riotto recalled to us that neutrino masses may also have something to do with the very origin of the matter among us, which is a remarkable fruit of the ideas of Sakharov(3 ). Finally, as already recalled, we had extensive lectures on the nuclear physics aspects relevant to the measurement of neutrino masses. The overall impression is that, although the daily business of theorists (i.e., publishing papers) is comparably easier, the challenges and the difficulties to obtain non-superficial physics results on neutrinos make the best theoretical efforts of similar value as those of their experimental colleagues. Moreover, the time needed to fully develop valid ideas —e.g., neutrino oscillations— often ranges in the ten year scale or longer, that again is comparable with the time of a typical neutrino experimental enterprise. These considerations emphasize the importance that theory and experiment proceed hand in hand toward the understanding of neutrino masses and, finally, toward their measurement. Various participants in the School enriched the discussion by contributing to the poster session, that permitted to perceive each other’s scientific interest immediately. Particularly precious was the time dedicated to discussion and the session when exercises were solved together at the blackboard. In brief, we feel that the main scientific and didactic goals of the School have been reached. As a side remark, we cannot but note that we aimed to perfection also during the moments of free time. This is testified by a number of tough competitions: the prize “B. Slinsega” for the best poster; the “Top Isospin” ping-pong international tournament for physicists; the “Mr. Neutrino” contest (the toughest, arguably), won respectively by E. Ferri, X. F. Navick and G. Senjanovi´ c. We enjoyed the School a lot and the time we spent together. (3 ) Indeed, they are a natural low-energy manifestation of the leptogenesis scenario originally suggested by Fukugita and Yanagida; but, in the absence of further theoretical progresses or experimental inputs, a precise prediction of neutrino masses seems to be very difficult or even impossible at present.

XX

Preface

We would like to conclude by thanking the many people who made this event possible, beginning with the President of SIF, L. Cifarelli for continuous help, encouragement and support. Immediately after, B. Alzani who has been our Guardian Angel, perfectly assisted by R. Brigatti and G. Bianchi Bazzi. A particularly warm “grazie” goes to the Editorial Office of SIF and in primis to A. Oleandri, M. Missiroli and M. Bonetti, for patience and very professional work done with editing. Next, we are glad to thank our sponsors, namely, CAEN of Viareggio, and SIMIC of Camerana, two well-known enterprises with important roles for the success of our experiments. Finally and most importantly, we are most grateful to all our Students, Speakers and Lecturers who worked for the scientific success of the School and apologize to them for any occasional disappointing situations. Now it is time to offer you the efforts of a community, condensed in this Volume, in the hope that it will be a useful guide to progress toward the measurement of neutrino masses. We wish to meet next time to discuss accomplished measurements, perhaps again in the wonderful scenery of Villa Monastero.

C. Brofferio, F. Ferroni and F. Vissani

This page intentionally left blank

Società Italiana di Fisica SCUOLA INTERNAZIONALE DI FISICA «E. FERMI» CLXX CORSO - VARENNA SUL LAGO DI COMO VILLA MONASTERO 17 - 27 Giugno 2008

4 3 1

9

6

10

7 8

2

11

12

13

15

14

47

1) M. Antonello 2) A. Di Vacri 3) G. Sirri 4) X. F. Navick 5) D. Di Ferdinando 6) A. Bryant 7) L. M. Pattavina 8) C. Salvioni

44

43

42

41

40

39

46

18

20 19

17) D. Bagliani 18) A. Giachero 19) F. Orio 20) M. Vignati 21) F. Bellini 22) I. Gnesi 23) P. M. Gore 24) E. F. Jones

22

38

25

23

26

27

24 37

34

36 35

9) E. Carrara 10) S. Di Domizio 11) M. Dolinsky 12) P. Risso 13) L. Gironi 14) G. Senjanovic 15) M. A. Carrettoni 16) E. Ferri

21

17

16 45

48

5

25) V. Tello 26) P. Ittisamai 27) F. Cappella 28) A. A. B. Machado 29) G. Pagliaroli 30) C. G. Maiano 31) M. Pedretti 32) M. Nemevsek

33

31

30

29

28

32

33) L. Kogler 34) A. Giuliani 35) J. Liu 36) C. Brofferio 37) F. Ferroni 38) E. Fiorini 39) F. Vissani 40) P. Vogel

41) A. Poves 42) M. A. Acero Ortega 43) C. C. Nishi 44) E. Frank 45) C. Langbrandtner 46) B. Alzani 47) R. Brigatti 48) G. Bianchi Bazzi

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-1

Weak interaction in nuclei E. Fiorini(∗ ) Dipartimento di Fisica “G.P.S. Occhialini”, Universit` a di Milano-Bicocca e INFN Sezione di Milano-Bicocca - Piazza della Scienza 3, 20126 Milano, Italy

Summary. — A few examples will be given of the essential role played by lowenergy nuclear physics in the fundaments of elementary particles and in particle astrophysics. The crucial impact in weak-interaction physics by the discovery of parity violation, which is now fifty years old, and the corresponding experiments will be summarized. A brief discussion will be devoted to the recent experiments on neutrino oscillations which prove that the difference between the square masses of two neutrinos of different flavour is different from zero. As a consequence, the mass of at least one neutrino has to be finite, but oscillations cannot provide a direct indication of its value. Stimulated by these exciting results a vast series of experiments aiming to determine directly the neutrino mass has been carried out and is running or planned.

1. – Introduction A fundamental step in the history of weak interactions dates back to the years “thirty” of the last century and is closely bound to the suggested properties of the then still hypothetical particle, named neutron by Wolfang Pauli and later neutrino (in Italian) (∗ ) E-mail: [email protected] c Societ`  a Italiana di Fisica

1

2

E. Fiorini

by Enrico Fermi. In fact it was only shortly after the suggestion by Pauli that Enrico Fermi constructed the beautiful theory where beta decay was studied as a local process with charged parity-conserving currents. I would like to stress that it was impossible in those times to think of a mediator as massive as the W and Z particles, and thus we can consider the locality of Fermi as a more than reasonable assumption. A second fundamental step about twenty years after was the discovery of parity nonconservation in weak interactions to which I will devote here some attention. As a consequence of this discovery, the neutrino was assumed as a mass-less particle, totally different from its antineutrino with full conservation of the total lepton number. Conservation was later assumed also for a new quantum number: the flavour which distinguishes the three types (electronic, muonic and tauonic) of the neutrino. A third step which occurred about thirty years ago was the discovery of the existence of neutral currents in weak interactions and of the presence of the above-mentioned heavy mediating particles, the W and Z bosons. As a consequence, many processes and in particular many neutrino interactions, which were considered as totally forbidden before, where actually found, but neutrino was still considered as a mass-less lepton and flavour-conserving particle. The last step dates to the beginning of this millennium and is the consequence of a series of experiments initiated decades before on neutrino oscillations. This process, suggested by Bruno Pontecorvo about fifty years ago, consists in the spontaneous transformation of neutrinos in neutrinos of a different flavour. Its existence implies that the difference of the squared masses of neutrinos of different flavours is different from zero and that, as a consequence, at least one neutrino has a finite mass. A massive neutrino indicates that the lepton number is not conserved and that therefore there is a certain equality between the neutrino and its antiparticle as suggested by Ettore Majorana in 1937, only one year before his tragic disappearance. This fact brings us back again to the discovery of parity violation just at the beginning of these last exciting fifty years of weak interactions. 2. – Parity violation in weak interactions The suggestion of parity violation in weak interactions was introduced in 1956 in a beautiful theoretical paper [1] aiming to cure the so-called θ-τ puzzle. The θ particle, which we now call K + , decays into π + + π o . It was however found to have exactly the same mass as the τ , which decays into π + + π o + π + , namely in a different parity state. T.D. Lee and C.N. Yang [1] noticed that no evidence existed for parity conservation in β decays and in hyperon or meson decays, namely in all weak-interaction processes known at that time. As a consequence, they brilliantly suggested a series of possibile experiments to test parity conservation in various weak interaction processes. I believe that one should particularly appreciate a theoretical paper like this, which is not based on existing results, but indeed suggests a priori experiments on a process non yet found. The suggestion of Lee and Yang stimulated experiments which started immediately [2, 3] and whose results were all published within one year in 1957. The first of these has been

3

Weak interaction in nuclei

Fig. 1. – C.S. Wu.

carried out by a group led by the great physicist C.S. Wu (fig. 1) with the experimental set-up shown in fig. 2. The decay investigated is (1)

60

Co → 60 Fe∗ + e− + ν¯e ,

followed by the electromagnetic decay of 60 Fe∗ into two gamma rays. The angular distribution of the gamma rays at temperatures above 110 mK is isotropic, but at lower temperature, where the cobalt crystal is polarized, it becomes more and more anisotropic. This is incidentally an excellent way to measure the temperature of the crystal. The angular distribution is however symmetric with respect to the polarization direction, since the γ decay is a parity-conserving electromagnetic process. The angular distribution of the electrons was on the contrary not only anisotropic, but also asymmetric: this is a clear prove of parity non-conservation. Three other experiments almost immediately confirmed this results, but it is inter-

4

E. Fiorini

Fig. 2. – The experiment by C.S. Wu et al.

esting to note that all authors thank Ms. Wu for informing them of her result prior to publication. In the decay (2)

π + ⇒ νμ + μ+

followed by μ+ → e+ + νe + ν¯μ ,

the angular distribution of the electron is found to be asymmetric with respect to the spin of the muon. Asymmetry was also found in nuclear emulsion in the chain (3)

π + → νμ + μ+ → e+ + νe + ν¯μ

and in the decay (4)

Λ → π − + p,

where a polarized Λ particle is produced in the reaction (5)

π− + p → Λ + K 0 .

Weak interaction in nuclei

5

Fig. 3. – Chirality, namely the alignment of neutrino spin towards the sense of motion.

Of considerable interest are experiments carried out, also recently, searching for a parity-violating impurity in strong and electromagnetic interactions. One has in fact to note that a strong interaction like, for instance, an α decay contains a weak component, proportional to the pariting-violating term ϕϕ∗ . This contribution is generally of the order of 10−13 –10−14 with respect to the strong cross-section. When looking for an angular distribution or for a polarization, one expects a weak impurity which is on the contrary of the order of ϕ. Parity-violating effects were found in experiments on the angular distribution of γ rays from polarized nuclear states or weak and unexpected circular polarization of γ rays from decays of excited nuclear states [3, 4]. Of considerable interest in nuclear physics are experiments searching for parityforbidden α decays [5]. An interesting example is the search for the α decay into carbon of the 2− excited state of 16 O at 8.87 MeV. Since both 12 C and 4 He are 0+ states, this decay is forbidden by parity conservation and can only be produced by an impurity of weak interactions. Very delicate optical experiments are also carried out [6] to search for the anomalous presence in circular polarization of an effect due to the contribution of weak interactions in a parity-conserving electromagnetic interaction process. The discovery of parity non-conservation led to the above-mentioned two-neutrino theory (fig. 3). 3. – Neutrino oscillations and the problem of the neutrino mass As mentioned before, the three neutrino families are identified by a quantum number named flavour (electronic, muonic or tauonic). In the Standard Model of weak interactions this number is conserved. A very important event in fundamental physics has been the discovery of neutrino oscillations in the last years [7, 8] which were predicted since

6

E. Fiorini

Fig. 4. – The various experiments showing neutrino oscillations, as suggested by B. Pontecorvo (center).

almost fifty years by the great physicist Bruno Pontecorvo. Let us consider as an example the neutrinos produced by the fusion processes which take place in the central region of the Sun and which are the source of the great energy produced in this and in all other stars. The copious flux of these neutrinos, which are of the electronic type, is such that their interactions, even if indeed rare, can be revealed in a very massive detector placed underground to avoid the “noise” due to cosmic rays. A pioneering experiment carried out in the United States and further searches performed in Japan, Russia, in the Gran Sasso Laboratory in Italy and more recently in Canada have clearly shown the presence of these neutrinos, but with a flux definitely lower than the expected one. This is due to the fact that solar neutrinos oscillate inside the Sun and in their long path toward the Earth transform themselves into the neutrinos of muonic or tauonic flavours. As a consequence, the flux of electronic neutrinos on the Earth is lower than predicted by the so-called Solar Model. Neutrino oscillations have been confirmed with neutrinos produced by cosmic rays in the atmosphere, and artificially by particle accelerators and nuclear reactors (fig. 4). These oscillations, which obviously violate the conservation of the flavour number, can only occur if the difference of the squared masses of two neutrinos of different flavours is finite. This obviously means that at least one neutrino has a mass different from zero, but neutrino oscillations are unable to determine its absolute value.

Weak interaction in nuclei

7

Fig. 5. – Deformation of the beta decay spectrum due to the neutrino mass.

The problem of the neutrino mass is crucial in fundamental physics: if it is finite the neutrino can propagate with a velocity lower than the velocity of light and the alignment of its spin (fig. 3) with respect to the direction of motion would be less than 100% etc. Another consequence would be that the total lepton number is likely violated and that there is not an absolute distinction between a neutrino and an antineutrino, as suggested since 1937 by Ettore Majorana. 4. – Direct and indirect ways to determine the neutrino mass Various experimental and cosmological approaches were and are considered for the direct and indirect measurement of the neutrino mass. . 4 1. Single-beta decay. – The most direct method to determine the mass of the neutrino [7,8] is the study of the deformation at the end point of the spectrum of the electron in single-beta decay (fig. 5). No evidence for a finite neutrino mass has been obtained, but the present upper limits of about 2 eV are still far from what is suggested by neutrino oscillations. A new experiment, KATRIN, to be carried out, as most of the previous ones, on the decay of tritium is being designed in Germany (fig. 6) and aims to reach a sensitivity of 0.2 eV. . 4 2. Measurements on the Cosmic Ray Background. – A more powerful, but modeldependent, method to determine the mass of the neutrino comes from cosmology. Our Universe is presently embedded in a “sea” of photons decoupled from matter about 400 000 years after the Big Bang. It represents the so-called Cosmic Microwave Background (CMB). We are also swimming in a sea of relic neutrinos decoupled much before, about a second after the Big Bang. The mass of these neutrinos would modify the distribution in space of CMB. Recent measurements on this CMB background have set a model-dependent upper limit on the neutrino masses slightly lower than that obtained in the direct measurements mentioned before. They are, however, still far from the values predicted by oscillations.

8

E. Fiorini

Fig. 6. – Arrival of the KATRIN structure.

. 4 3. Double-beta decay. – A third method to determine the effective neutrino mass is connected to a fundamental puzzle in neutrino physics: is neutrino a Dirac or a Majorana particle? (fig. 7). In the former hypothesis neutrino would be totally different from the antineutrino, its chirality, namely the property reported in fig. 3, would be 100% and its mass most likely null. In the latter, based on a brilliant theory suggested in 1937 by Ettore Majorana, the neutrino would not be distinct from its antiparticle, its mass would be finite and the lepton number would be violated. The most powerful method to investigate lepton number conservation is double-beta decay (DBD), a rare nuclear process suggested by Maria Goeppert Majer [9] in 1935, only one year after the Fermi weak-interaction theory (fig. 8). This process (fig. 9) consists in the direct transition from a nucleus (A, Z) to its isobar (A, Z + 2) and can be investigated when the single-beta decay of (A, Z) to (A, Z + 1) is energetically forbidden or at least strongly hindered. The decay can occur in three channels (6)

(A, Z + 2) → (A, Z + 2) + 2e− + 2¯ νe ,

(7)

(A, Z + 2) → (A, Z + 2) + 2e− + (1, 2, . . . , χ),

(8)

(A, Z + 2) → (A, Z + 2) + 2e− ,

Weak interaction in nuclei

9

Fig. 7. – Dirac and Majorana.

Fig. 8. – Maria Goeppert Majer and Enrico Fermi.

In the first channel two antineutrinos are emitted. This process does not violate the lepton number, it is allowed by the Standard Model, and has been found in ten nuclei. We will not consider the second channel which violates the lepton number with the emission of one or more massless Goldstone particles named “majoron”. Our interest will be devoted to the third process which is normally called neutrinoless DBD, even if also in process (7) no neutrino is emitted. This process would strongly dominate on the two-neutrino channel if lepton number is violated. From the experimental point of view, in neutrinoless DBD the two electrons would share the total transition energy since the energy of the nuclear recoil is negligible. A peak would therefore appear in the spectrum

10

E. Fiorini

Fig. 9. – Scheme of two-neutrino and neutrinoless DBD.

of the sum of the two electron energies in contrast with the wide bump expected, and already found, for the two-neutrino DBD. The presence of neutrinoless DBD almost naturally implies that a term mν  called the “effective neutrino mass” is different from zero. DBD is a very rare process both in the case of two neutrino and of neutrinoless channel. In the latter its rate would be proportional to a phase space term, to the square of the nuclear matrix element and to the square of the above-mentioned term mν . While the phase space term can be easily calculated, this is not true for the nuclear matrix element whose evaluation is a source of sometimes excited debates. The calculated values could vary by factors up to two. As a consequence, the discovery of neutrinoless DBD should be made on two or more different nuclei. From the experimental point of view there is an even more compelling reason to do that. In a common background spectrum many peaks appear due to radioactive contaminations and many of them can hardly to be attributed to a clear origin. It is not possible therefore to exclude that a peak in the region of neutrinoless DBD could be mimicked by some unknown radioactive event. Investigation of spectra obtained from different nuclear candidates, where the neutrinoless DBD peak is expected in different regions, would definitely prove the existence of this important phenomenon. The value of mν  and therefore the rate of neutrinoless DBD is correlated to properties of oscillations As shown in fig. 10 values of a few tens or units of meV are expected in the case of two different orderings of neutrino masses named “inverted” and “normal” hierarchy, respectively. . 4 3.1. Experimental approach. Two different experimental approaches can be adopted to search for DBD [10-14]: the indirect and the direct one.

Weak interaction in nuclei

11

Fig. 10. – Effective neutrino mass expected in DBD experiments from neutrino oscillations. The upper and lower curves refer to the so-called inverted and normal hierarchies.

Indirect experiments. The most common indirect approach is the geochemical one. It consists in the isotopic analysis of a rock containing a relevant percentage of the nucleus (A, Z) to search for an abnormal isotopic abundance of the nucleus (A, Z + 2) produced by DBD. This method was very successful in the first searches for DBD and led to its discovery in various nuclei, but could not discriminate among the various DBD modes (two-neutrino or neutrinoless decay, decays to excited levels, etc.). The same is true for the radiochemical methods consisting in storing for long time large masses of DBD candidates (e.g., 238 U) and in searching later the presence of a radioactive product (e.g., 238 Th) due to DBD. Direct experiments. Direct experiments are based on two different approaches (fig. 11). In the calorimetric or source = detector one, the detector itself is made of a material

Fig. 11. – The two different approaches to direct search for DBD.

12

E. Fiorini

Table I. – Present results on neutrinoless DBD and limits on neutrino mass (eV). Nucleus

τ0ν (y)

Sym

Rodin old

Civit

5

Rodin (New)

0.97

0.84

0.36 ± 0.07

1.1

0.91

0.40 ± 0.08

0.52

1.2

1.1

0.46 ± 0.09

1.8

2.8

3.7

1.9 ± 2.0

11

1.1 ± 0.3

48

Ca

> 1.4 × 1022

76

Ge

> 1.9 × 1025

0.47

0.55

0.41

76

Ge

> 1.6 × 1025

0.51

0.60

0.44

76

Ge

1.2 × 1025

0.59

0.69

82

Se

> 2.1 × 1023

2.2

2.9

4 22

100

Mo

> 5.8 × 1023

0.97

2.7

1.1

116

Cd

> 1.7 × 1023

2.4

3.5

1.4

128

Te

> 7.7 × 1024

1.8

2.5

130

Te

> 3 × 1024

0.7

0.85

136

Xe

> 1.2 × 1024

2.9

2.0

150

Nd

> 1.2 × 1021

2.7

4.4

2.7

2.3 ± 0.8

4.6

2.0

1.5 ± 0.6

0.37

1.1

1.8

0.16 ± 0.84

0.42

2.6 1.0

1.2 ± 0.5 0.84

2.3 ± 1

containing the DBD candidate nucleus (e.g., 76 Ge in a germanium semiconductor detector or 136 Xe in a xenon TPC, scintillation or ionization detector). In the source = detector approach sheets of the DBD source are interleaved with suitable detectors of ionizing particles. A weak magnetic field could be present to eliminate various sources of background. Thin sheets have to be used to optimize the resolution in the measurement of the sum of the two electron energies. Thermal detectors. A new approach [15-18] based on the calorimetric detection of DBD is the use of thermal or cryogenic detectors, amply adopted also in searches on Dark Matter particles and for direct measurements of the neutrino mass in single-beta decay. An absorber is made of a crystal, possibly of diamagnetic and dielectric type, kept at low temperature where its heat capacity is proportional to the cube of the ratio between the operating and the Debye temperatures. As a consequence, in a cryogenic set-up like a dilution refrigerator this heat capacity could become so low that the increase of temperature due to the energy released by a particle in the absorber can be detected and measured by means of a suitable thermal sensor. The resolution of these detectors, even if still in their infancy, is already excellent. In X-ray spectroscopy made with bolometers of a milligram or less the FWHM resolution can be as low as 3 eV, more than an order of magnitude better than in any other detector. In the energy region of neutrinoless DBD the resolution with absorbers of masses up to a kg is comparable to or better than that of Ge diodes. . 4 3.2. Present results and future experiments Present results. The present results [11-14] on neutrinoless DBD are reported in table I with the corresponding limits on neutrino mass, where the large uncertainties on nuclear matrix elements are taken into account. It can be seen that so far no experimental group has indicated the existence of neutrinoless DBD, with the exception of a subset of

Weak interaction in nuclei

13

Fig. 12. – NEMO 3.

the Heidelberg-Moscow collaboration led by H. Klapdor-Kleingrothaus who claims the existence of this process in 76 Ge. This evidence is amply debated in the international arena. NEMO 3 and CUORICINO. Two experiments are presently running with a sensitivity on neutrino mass comparable to the evidence reported by H. Klapdor-Kleingrothaus et al.: NEMO 3 and CUORICINO. NEMO 3 . It is a source = detector experiment (fig. 12) presently running in a Laboratory situated in the Frejus tunnel between France and Italy at a depth of ∼ 3800 meters of water equivalent (m.w.e). This experiment has yielded extremely good results on twoneutrino DBD of various nuclei. The limits on the neutrinoless channel of 100 Mo and 82 Se (table I) are already approaching the value of neutrino mass presented as evidence by Klapdor-Kleingrothaus et al. CUORICINO. It is at present the most sensitive running neutrinoless DBD experiment. It operates in the Laboratori Nazionali del Gran Sasso under an overburden of rock of ∼ 3500 m.w.e. (fig. 13). It consists in a column of 62 crystals of natural TeO2 to search for neutrinoless DBD of 130 Te. Its mass of 40.7 kg is more than an order of magnitude larger than in any other cryogenic set-up (fig. 14). No evidence is found for a peak in the

14

E. Fiorini

Fig. 13. – Location of CUORICINO and of R&D for CUORE in the Gran Sasso Laboratory.

region of neutrinoless DBD setting a 90% lower limit of 3 × 1024 years on the lifetime of neutrinoless DBD of 130 Te. The corresponding upper limit on mν  (0.16–0.84 eV) almost entirely covers the span of evidence coming from the claim of H. Klapdor-Kleingrothaus et al. (0.1–0.9 eV). Future experiments. A list of proposed future experiments [11-14] is reported in table II with the adopted techniques and the expected background and sensitivity. Only one of them, CUORE, has been fully approved, while GERDA has been funded for its first preliminary version. These and a few others will be briefly described here. GERDA and Majorana. Both these experiments (fig. 15) are based on the “classical” detection of neutrinoless DBD of 76 Ge in a source = detector approach with germanium diodes. They are logical continuations of the Heidelberg-Moscow and IGEX experiments, respectively. GERDA, already approved in its preliminary version, is going to be mounted in the Gran Sasso Underground Laboratory. An intense R&D activity is being carried out by the Majorana collaboration in view of the installation of this experiment. Its underground location has not been decided yet. The two experiments plan to join their forces in a future one ton experiment on 76 Ge. MOON is based on the source = detector approach to search for neutrinoless DBD of 100 Mo to be installed in the Oto underground laboratory in Japan. The set-up will be

15

Weak interaction in nuclei

Table II. – Future experiments on double-beta decay. %

Qββ

%E

B (c/y)

T (year)

Tech

m

Te

34

2533

90

3.5

1.8 × 1027

Bolometric

9–57

76

Ge

7.8

2039

90

3.85

2 × 1027

Ionization

29–94

Majorana

76

Ge

7.8

2039

90

0.6

4 × 1027

Ionization

21–67

GENIUS

76

Ge

7.8

2039

90

0.4

1 × 1028

Ionization

13–42

SUPERNEMO

82

2 × 10

Name CUORE

130

GERDA

Se

EXO

136

MOON 3

100

DCBA-2

150

Candles CARVEL

Xe

Mo

26

8.7

2995

90

1

Tracking

54–167

8.9

2476

65

0.55

1.3 × 1028

Tracking

12–31

3.8

1.7 × 10

Tracking

13–48

9.6

3034

85

Nd

5.6

3367

80

48

Ca

0.19

4271

-

48

Ca

0.19

4271

-

0.35

27

1 × 1026

Tracking

16–22

3 × 1027

Scintillation

29–54

3 × 1027

Scintillation

50–94

1 × 1026

Scintillation

65–?

GSO

160

Gd

22

1730

COBRA

115

Cd

7.5

2805

Ionization

SNOLAB+

150

Nd

5.6

3367

Scintillation

200

made (fig. 16) by thin sheets of enriched molybdenum interleaved with planes of scintillating fibers. The experiment is also intended to detect the low-threshold interactions of solar neutrinos on 100 Mo leading to 100 Rb. SUPERNEMO is also a source = detector experiment mainly intended to search for neutrinoless DBD of 82 Se, to be installed in a not yet decided underground laboratory in Europe. The system is similar to the one adopted by NEMO 3, but with a considerably different geometry. XENON is an experiment to be carried out in Japan with a large mass of enriched xenon based on scintillation to search for neutrinoless DBD of 136 Xe. Due to the large mass, it will be also used to in a search for interactions of Dark Matter particles (WIMPS). EXO is also intended to search for neutrinoless DBD of 136 Xe-136 Ba, but with a totally new approach: to search for DBD events by detecting with the help of LASER beams single Ba++ ions produced by the process. The option of liquid or gas xenon and the underground location has not been decided yet, but a 100 kg litre liquid-xenon experiment without Ba tagging is going to operate soon in the WIPP underground laboratory in USA. CUORE (for Cryogenic Underground Observatory of Rare Events) is the only secondgeneration experiment approved so far. It will consist of 988 crystals of natural TeO2 arranged in 19 columns practically identical to the one of CUORICINO, with a total mass of about 750 kg (fig. 17). The experiment has already been approved by the Scientific Committee of the Gran Sasso Laboratory, by the Italian Institute of Nuclear Physics and by DOE and NSF. The basement for its installation has been prepared in Gran Sasso (fig. 13). As shown in table III 130 Te has been chosen for CUORE due to its high isotopic abundance, but the versatility of thermal detectors allows many other interesting, but expensive, double-beta active materials.

16

Fig. 14. – Mounting of CUORICINO.

Fig. 15. – GERDA and Majorana.

E. Fiorini

Weak interaction in nuclei

17

Fig. 16. – MOON I, a running prototype of MOON.

Fig. 17. – CUORE: an array of 988 crystals of TeO2 .

5. – Conclusions Low-energy nuclear physics has contributed in a substantial way to the development of the study of weak interactions since the very beginning, and also after the so-called particle astrophysics connection. Since this year is the 50th anniversary of the discovery

18

E. Fiorini

Table III. – Possible thermal candidates for neutrinoless DBD. Compound

Isotopic abundance

Transition energy (keV)

0.0187%

4272

Ge

7.44%

2038.7

MoPbO4

9.63%

3034

7.49%

2804

34%

2528

5.64%

3368

48

CaF2

76 100

116

CdWO4

130

TeO2

150

NdF3 150 NdGaO3

of parity non-conservation in weak interactions, I have decided to start with this subject which still plays an important role in neutrino properties, which covers the rest of this lecture. After 70 years the brilliant hypothesis of Ettore Majorana is still valid and is strongly supported by the discovery of neutrino oscillations which imply that the difference between the squared masses of two neutrinos of different flavours is different from zero. As a consequence at least one of the neutrinos has to be massive and the measurement of the neutrino mass becomes imperative. Double-beta decay is at present the most powerful tool to obtain this result and also to clarify if the neutrino is a Majorana particle. The future second-generation experiments being designed, proposed and already in the case of CUORE under construction will allow in a few years to reach the sensitivity in the neutrino mass predicted by the results of oscillations in the inverse hierarchy scheme.

REFERENCES [1] Lee T. D. and Yang C. N., Phys. Rev., 104 (1956) 1. [2] See, for instance, Adelberger E. G. and Haxton W. C., Annu. Rev. Nucl. Part. Sci., 35 (1985) 501. [3] Ajzenberg-Selove F., Nucl. Phys. A, 490 (1989) 1 and references therein. [4] Gericke M. T. et al., Phys. Rev. C, 74 (2006) 065503. [5] Ajzenberg-Selove F., Nucl. Phys. A, 166 (1971) 1 and references therein. ´na J. and Bouchiat M.-A., Eur. Phys. J. A, 32 (2007) [6] See, for instance, Lintz M., Gue 525 and references therein. [7] For a recent review including neutrino properties and recent results, see: Review of Particle Physics, J. Phys. G: Nucl. Part. Phys., 33 (2006) 1. [8] Fogli G. L., Lisi E., Marrone A. and Palazzo A., Prog. Part. Nucl. Phys., 57 (2006) 742 and references therein. [9] Goeppert-Mayer M., Phys. Rev., 48 (1935) 512. [10] Aalseth C. et al., arXiv:hep-ph/04123000. [11] Zdesenko Y., Rev. Mod. Phys., 74 (2002) 663. [12] Avignone III F. T., King III G. S. and Zdesenko Yu. G., New J. Phys., 7 (2005) 6. [13] Elliott S. R. and Engel J., J. Phys. G: Nucl. Part. Phys., 30R (2004) 183 hepph/0405078.

Weak interaction in nuclei

19

[14] Avignone F. T., Elliott S. R. and Engel J., Double beta decay, Majorana neutrinos and neutrino mass, to be published in Rev. Mod. Phys. [15] Fiorini E. and Ninikoski T., Nucl. Instrum. Methods, 224 (1984) 83. [16] Twerenbold D., Rep. Prog. Phys., 59 (1996) 349. [17] Booth N., Cabrera B. and Fiorini E., Annu. Rev. Nucl. Part. Sci., 46 (1996) 471. [18] Enns C. (Editor), Topics in Applied Physics, Vol. 99 (Springer-Verlag) 2005, p. 453.

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-21

Phenomenology of neutrino masses A. Strumia Dipartimento di Fisica, Universit` a di Pisa and INFN, Italy

Summary. — We review experimental and theoretical results related to neutrino physics with emphasis on neutrino masses and mixings, and outline possible lines of development.

1. – Massless neutrinos in the Standard Model In all observed processes baryon number B and lepton number L are conserved. The SM provides a nice interpretation of these results: B and L automatically emerge as approximatively conserved charges, because no term of the most general Lagrangian that can be written with the SM fields can violate them. Consequently SM neutrinos ¯ / L, i.e. a kinetic term plus are massless and fully described by the Lagrangian term LiD gauge interactions with the massive vector bosons, ν¯Zν and ν¯W L . This determines if and how neutrinos can be detected. 2. – Detecting neutrinos The relevant Feynman diagrams are plotted in fig. 1. They can be estimated as follows [1]. The amplitude for scattering of neutrinos on electrons at rest is M ∼ GF me Eν . The total cross-section is σ ∼ |M|2 /s, where s = (Pe + Pν )2 in terms of the quadri-momenta P . If Eν me , one has s ∼ m2e and so σ ∼ G2F Eν2 . If Eν  me one has s ∼ me Eν and so σ ∼ G2F me Eν [2]. The scattered lepton typically gets an order one fraction of the neutrino energy. Some reactions are kinematically allowed only at high enough energies. c Societ`  a Italiana di Fisica

21

22

A. Strumia

νe

νe

νe, μ,τ

νe, μ,τ

W Z

e

e

e, q

e, q

Fig. 1. – Interactions of neutrinos with electrons and quarks.

For example, a νμ can be seen by detecting the μ in the νμ e → νe μ reaction one needs Eντ > m2τ /2me ≈ 11 GeV. The SM amplitude for scattering of neutrinos on nucleons (i.e. protons or neutrons) at rest is M ∼ GF mp Eν [2]. Therefore the total cross-section is σ ∼ G2F Eν2 for Eν mp (e.g. solar and reactor neutrinos), and σ ∼ G2F mp Eν for Eν  mp . Since mp  me , the hadronic cross-sections are bigger than the leptonic ones. Focussing on CC processes (so that the neutrino is converted into a charged lepton, that can be detected), at Eν mp only the reactions ν¯e p → e+ n and νe n → ep are possible, and only the first one is of experimental interest, because it is not possible to build a target containing enough free neutrons, that would decay. If Eν mp kinematics is simple, and the positron energy directly tells the neutrino energy: Eν = Ee+ + mn − mp > me + mn − mp . Enough free protons are obtained using targets made of water (H2 O), etc. Scattering on nuclei offers more possibilities. At Eν  mp the relevant scatterings become neutrino/quark and all neutrinos scatter on ordinary matter. ντ can be detected using the ντ n → τ p reaction, that is kinematically allowed at Eντ > mτ + m2τ /2mN ≈ 3.5 GeV. So far we approximated the W , Z propagators in the Feynman diagrams as 1/(p2 − 2 2 2 MW,Z ) ≈ −1/MW,Z . This is no longer true if Eν  MW,Z /mN ∼ 10 TeV. At much larger energies (above LHC energies) the cross-section simplifies again, becoming [3] (1)

σ ˆCC

2 G2F MW ≈ 1.07 · 10−34 cm2 . π

This constant partonic cross-section implies a nucleonic cross-section that slowly grows with Eν , and it corresponds to an interaction length of about 1000 kmwe, comparable to the thickness of the Earth. If cosmic rays contain enough neutrinos with high enough energy, their distribution in zenith angle will allow to measure the neutrino cross-section [4]. 3. – Massive neutrinos beyond the SM Observations of neutrino masses call for an extension of the SM, and plausible extensions of the SM suggested neutrino masses. The new physics needed to get neutrino

23

Phenomenology of neutrino masses

masses can be either i) heavier or ii) lighter than 100 GeV, the maximal energy that has been experimentally explored so far. Generic new physics too heavy for being directly studied manifests at low energy as non-renormalizable operators (NRO), suppressed by heavy scales Λ. NRO give small corrections, suppressed by powers of E/Λ, to physics at low energy E Λ, that is, therefore, well described by a renormalizable theory. Today we have three evidences for small nonrenormalizable effects. One is gravity: the non-renormalizable gravitational couplings, suppressed by E/MPl , sum coherently over many particles giving the well-known Newton force. The other two are the solar and atmospheric neutrino anomalies: small neutrino masses have been seen thanks to the fact that they violate lepton flavor. Indeed, adding NRO to the SM Lagrangian, Le , Lμ , Lτ , B are no longer accidentally conserved [5]: (2)

L = LSM +

 (LH)2 1  ¯¯ D)(QL) + · · · . + 2 (U 2ΛL ΛB

With only one light Higgs doublet there is only one kind of dimension-5 operator: (LH)2 = (νh0 − eL h+ )2 . Inserting the Higgs vev (vacuum expectation value) v, this operator gives a Majorana neutrino mass term, mν νL2 /2, with mν = v 2 /ΛL ∼ 0.1 eV for ΛL ∼ 1014–15 GeV. Neutrino masses might be the first manifestation of a new length scale ΛL in nature. Various dimension-6 operators violate B and conserve B-L giving rise to proton decay into anti-leptons: p → e¯π 0 , ν¯π + , . . ., with width τp−1 ∼ m5p /Λ4B . The strongest constraint on the proton lifetime τp comes from the SK experiment, which monitored about 1010 moles of protons for a few years. Therefore the present bound is τp  1010 NA yr ≈ 1034 yr, i.e. ΛB  1015 GeV. The other possibility of adding new light particles can only be realized by adding light right-handed neutrinos νR , i.e. fermions neutral under all SM gauge interactions, because LEP excluded new particles coupled to the Z boson and lighter than MZ /2. All other SM fermions have gauge interactions that forbid Majorana mass terms. Only right-handed neutrinos can have a Majorana mass MN , that together with the usual Yukawa coupling λN , breaks lepton number. Indeed the most generic Lagrangian is  (3)

¯i i∂ L = LSM + N /Ni +

λij N

 ij MN νRi νRj + h.c. , νRi L H + 2 j

such that neutrinos generically have a 6 × 6 Majorana/Dirac mass matrix

(4)

νL νR



νL 0 λN v

νR  λTN v , MN

where boldface reminds that λN and M N are 3 × 3 flavour matrices.

24

A. Strumia H

H

H

Singlet

L

H

L

Triplet

L

H Triplet

L

L

L

H

2

Fig. 2. – The neutrino Majorana mass operator (LH) can be mediated by tree level exchange of: I) a fermion singlet; II) a fermion triplet; III) a scalar triplet.

We focus on two interesting extreme limits: Pure Dirac neutrinos. If MN λN v the full 6 × 6 mass matrix gives 3 Dirac neutrinos Ψ = (νL , ν¯R ) with mass mν = λN v. The vanishing of MN can be justified if conservation of lepton number is imposed (rather than obtained, as in the SM). In order to get the observed neutrino masses, one needs λN ∼ 10−12 —much smaller than all other SM Yukawa couplings. Therefore the other limit is considered as more plausible: Pure Majorana neutrinos. If MN  λN v the full 6×6 mass matrix gives rise to 3 (almost) pure right-handed neutrinos with heavy Majorana masses M N , and to 3 (almost) pure left-handed neutrinos with light Majorana masses mν = −(vλN )T M −1 N (vλN ). We now rederive the same result proceeding in a different way. Integrating out the heavy neutrinos gives a non-renormalizable effective Lagrangian that only contains the observable low-energy fields. Figure 2a shows that νR exchange generates the Majorana mass operator (Li H)(Lj H)/2 with coefficient −(λTN M −1 N λN )ij . This “see-saw” mechanism generates the 9 measurable neutrino mass parameters (see later) from λN and M N , that contain 18 unknown parameters. In the intermediate case MN ∼ λN v one gets 6 mixed neutrinos with comparable masses: the extra neutrinos are called “sterile” and are disfavored by data. Extra fermion triplets. The extra fermion N added in the previous section could be a SU (2)L triplet with zero hypercharge rather than a singlet [6]. The Lagrangian contains analogous λN and M N flavour matrices  (5)

¯i iD L = LSM + N / Ni +

λij N

Nia (Lj

ij MN a a Ni Nj + h.c. . · τ · ε · H) + 2 a

The index a runs over {1, 2, 3}, τ a are the Pauli matrices and ε is the permutation tensor √ (ε12 = +1). The three components of N are N 3 with charge zero and (N 1 ± iN 2 )/ 2 with charge ±1. As long as MN  v (triplets lighter than MZ /2 have been excluded by LEP) everything works in the same way: triplet exchange generates the Majorana mass operator, (LH)2 . This mechanism is sometimes known as “type-III see-saw”.

25

Phenomenology of neutrino masses

Extra scalar triplet. We have seen how neutrino masses can be obtained adding new fermionic (“matter”) fields. Alternatively, one can add one scalar (“Higgs”) triplet T a (a = {1, 2, 3}) with hypercharge YT = 1 [6] (and so composed of three components with charge 0, +1, +2), such that the most generic renormalizable Lagrangian is (6)

1 L = LSM + |Dμ T |2 − MT2 |T a |2 + (λij Li ετ a Lj T a + λH MT Hετ a H T a∗ + h.c.), 2 T

where λT is a symmetric flavour matrix, ε is the permutation matrix, and τ a are the usual SU (2)L Pauli matrices. Integrating out the heavy triplet generates the Majorana neuij 2 2 trino masses operator (LH)2 (see fig. 2b) inducing neutrino masses mij ν = λT λH v /MT . This mechanism is sometimes known as “type-II see-saw”. A smaller number of unknown flavour parameters are needed to describe one extra scalar triplet than the extra fermion scalars or triplets. Many other renormalizable extensions of the SM can generate the Majorana neutrino mass operator (LH)2 . As illustrated in fig. 2, at tree level, it can be mediated by the exchange of 3 different types of new heavy particles: i) right-handed neutrinos; ii) scalar or iii) fermion SU (2)L triplets. These possible sources of neutrino masses are consistent with plausible extensions of the SM: gauge unification, supersymmetry and thermal leptogenesis. Mediation by loop effects is also possible, and can be realized by many ways. 4. – Pure Majorana neutrinos We now study in detail the special cases of pure Majorana neutrino masses. We extend the SM by adding to its Lagrangian the non-renormalizable operator (LH)2 and no new fields. Below the SU (2)L -breaking scale, (LH)2 just gives rise to Majorana neutrino masses. Charged lepton masses are described as usual by a complex 3 × 3 matrix mE , and neutrino masses by a complex symmetric 3 × 3 matrix mν : 1 −Lmass = TR · mE · L + νLT · mν · νL . 2 How many independent parameters do they contain? Performing the usual unitary flavour rotations of right-handed E = R and left-handed L = (νL , ) leptons, that do not affect the rest of the Lagrangian, we reach the standard mass eigenstate basis of charged leptons, where mE = diag(me , mμ , mτ ). It is still possible to redefine the phases of eL and eR such that me and mee ν are real and positive; and similarly for μ and τ . Therefore charged lepton masses are specified by 9 real parameters and 3 complex phases: the 3 real parameters me , mμ , mτ ; the 3 real diagonal elements of mν ; the 3 complex off-diagonal elements of mν . It is customary to write the mass matrices as (7)

mE = diag(me , mμ , mτ ),

mν = V ∗ diag(m1 e−2iβ , m2 e−2iα , m3 )V † ,

26

A. Strumia

where me,μ,τ,1,2,3 ≥ 0. The neutrino mixing matrix V , that relates the neutrinos with given mass, νi , to those with given flavour, (8)

ν = Vi νi ,

can be written as a sequence of Euler rotations (9)

V = R23 (θ23 ) · R13 (θ13 ) · diag(1, eiφ , 1) · R12 (θ12 ),

where Rij (θij ) represents a rotation by θij in the ij plane and i, j = {1, 2, 3}. In components ⎞ ⎛ ⎞ ⎛ c12 c13 Ve1 Ve2 Ve3 c13 s12 s13 (10) ⎝Vμ1 Vμ2 Vμ3 ⎠=⎝−c23 s12 eiφ − c12 s13 s23 c12 c23 eiφ − s12 s13 s23 c13 s23 ⎠ . Vτ 1 Vτ 2 Vτ 3 s23 s12 eiφ − c12 c23 s13 −c12 s23 eiφ − c23 s12 s13 c13 c23 . Within this standard parameterization, the 6 + 3 neutrino parameters are the 3 neutrino mass eigenvalues, m1 , m2 , m3 , the 3 mixing angles θij and the 3 CP -violating phases φ, α and β. φ is the analogous of the CKM phase, and affects the flavour content of the neutrino mass eigenstates. α and β are called “Majorana phases” and do not affect oscillations (see sect. 6). We now justify this parameterization. We order the neutrino masses mi such that m3 is the most splitted state and m2 > m1 , and define Δm2ij = m2j − m2i . With this choice, Δm223 and θ23 are the “atmospheric parameters” and Δm212 > 0 and θ12 are the “solar parameters”, whatever the spectrum of neutrinos (“normal hierarchy”, i.e. m1 m2 m3 so that Δm223 > 0; “inverted hierarchy”, i.e. m3 m1  m2 , so that Δm223 < 0 or “almost degenerate”). 1) Two parameters, θ23 and θ13 , are necessary to describe the flavour of the most splitted neutrino mass eigenstate |ν3  = s13 |νe  + c13 s23 |νμ  + c13 c23 |ντ . Complex phases can be rotated away by redefining the phases of Le,μ,τ and Ee,μ,τ leaving me,μ,τ real and positive. Physically, this means that two mixing angles, θ23 and θ13 , give rise to CP -conserving oscillations at the larger frequency Δm223 . 2) Since the flavours of |ν2  and |ν3  must be orthogonal, a single complex mixing angle (decomposed as one real mixing angle, θ12 , plus one relative phase, φ) are  ∗ needed to describe the flavour of |ν2  =  V2 |ν . Since there is no longer any freedom to redefine the phases of νe,μ,τ , the overall phase of |ν2 , α, is physical. 3) Finally, no more parameters are needed to describe the flavour of ν1 , that must be orthogonal to ν2 and ν3 . The overall phase of ν1 , β, cannot be rotated away and is a physical parameter.

27

Phenomenology of neutrino masses

ν3

(b)

νe

atm

ντ

sun

νμ

(a)

sun

νμ

ντ

ν2

νe

ντ

νe

ν2 ν1

atm

νe

νμ

νμ

ν1

ντ

ν3

Fig. 3. – Possible neutrino spectra: (a) normal (b) inverted.

Finally, we specify the full allowed range of the parameters. We order the neutrino masses mi such that m3 is the most splitted state and m2 > m1 , and define Δm2ij = m2j −m2i . With this choice, Δm223 and θ23 are the “atmospheric parameters” and Δm212 > 0 and θ12 are the “solar parameters”, whatever the spectrum of neutrinos (“normal hierarchy” so that Δm223 > 0; or “inverted hierarchy” so that Δm223 < 0, see fig. 3). With this choice the physically inequivalent range of mixing angles is 0 ≤ θ12 , θ23 , θ13 ≤ π/2,

0 ≤ φ < 2π,

0 ≤ α, β ≤ π.

The flavour composition of the neutrino mass eigenstates ν1,2,3 suggested by present data (see table I) is indicated in fig. 3 in a self-explanatory pictorial way. 5. – Pure Dirac neutrinos We extend the SM by adding three neutral singlets (one per family), named “right2 handed neutrinos”, νR . We forbid νR mass terms by imposing conservation of lepton number. The most generic renormalizable Lagrangian is eq. (3) with MN = 0. In this situation, charged lepton masses are described as usual by a complex 3 × 3 matrix mE , and neutrino masses by a complex 3 × 3 matrix mν = λTN v: −Lmass = TR · mE · L + νLT · mν · νR . Table I. – Summary of present information on neutrino masses and mixings from oscillation data. Oscillation parameter solar mass splitting atmospheric mass splitting

Central value

99% CL range

Δm212 =

(7.58 ± 0.21) 10−5 eV2

(7.1 ÷ 8.1) 10−5 eV2

|Δm223 | =

(2.40 ± 0.15) 10−3 eV2

(2.1 ÷ 2.8) 10−3 eV2

solar mixing angle

tan θ12 =

0.484 ± 0.048

31◦ < θ12 < 39◦

atmospheric mixing angle

sin2 2θ23 =

1.02 ± 0.04

37◦ < θ23 < 53◦

“CHOOZ” mixing angle

sin2 2θ13 =

0 ± 0.05

2

θ13 < 10◦

28

A. Strumia

Fig. 4. – Gedanken experiment that ideally illustrates the difference between a Majorana and a Dirac neutrino.

We have more matrix elements and more fields that can be rotated than in the pure Majorana case. One can repeat the steps 1, 2, 3 above, with the only modification that the “Majorana phases” can now be rotated away (reabsorbed in the phases of the νR ) leaving only the CKM phase. In fact, the flavour structure (2 mass matrices for 3 kinds of fields) is identical to the well-known structure present in quarks (2 mass matrices for the up- and down-type quarks, contained in the 3 fields uR , dR and Q = (uL , dL )). However, a numerical difference makes the physics very different: neutrino masses are small. Up- and downtype quarks and charged leptons are produced in ordinary processes as mass eigenstates, while neutrinos as flavour eigenstates. So far, we can produce a νμ , but we are not able of getting a ν3 . For this reason, tools analogous to the “unitarity triangle” (used to visualize CKM mixing among quarks, and useful because experiments can measure both its sides and its angles) have no practical use in lepton flavour. Before concluding, let us discuss the physical difference between Majorana and Dirac neutrinos. While Dirac masses conserve lepton number, that distinguishes leptons from anti-leptons, in the Majorana case there is no Lorentz-invariant distinction between a neutrino and an anti-neutrino. They are different polarizations of a unique particle that interacts mostly like a neutrino (an anti-neutrino) when its spin is almost anti-parallel (parallel) to its direction of motion. While ideally an anti-neutrino becomes a neutrino, if seen by an observer that moves faster than it, in practice these effects are suppressed by (mν /Eν )2 . This factor is usually so small that only in appropriately subtle situations it might be possible to detect it. A Gedanken experiment allows to appreciate the physical difference between Majorana and Dirac neutrinos in a simple way (fig. 4). Suppose that it were practically possible to put at rest a massive νμ neutrino with spin-down in the middle of the room. If accelerated up to relativistic energies in the up direction, when it hits the roof can produce a μ− trough a CC interaction. If accelerated up to relativistic energies in the down direction, when it hits the floor it can produce a μ+ (if it is a Majorana particle) or have no interaction (if it is a Dirac particle).

29

Phenomenology of neutrino masses

Coming to realistic experiments, in the next section we show that oscillation experiments cannot discriminate Majorana from Dirac neutrinos. It seems that the only realistic hope of experimentally discriminating Majorana from Dirac neutrino masses is based on the fact that Majorana masses violate lepton number, maybe giving a signal in future neutrinoless double-β decay searches (see sect. 17). Inverting the see-saw . Assuming that three heavy right-handed neutrinos mediate Majorana neutrino masses according to the see-saw Lagrangian of eq. (3), the most generic high-energy parameters that give rise to any desired neutrino masses mνi and mixings V can be parameterized as (11)

MN = diag(M1 , M2 , M3 ),

λN =

1 1/2 M · R · diag(mν1 , mν2 , mν3 )1/2 · V † . v N

One can always work in the mass eigenstate basis of right-handed neutrinos, where Mi is real and positive. R is an arbitrary complex orthogonal matrix (i.e. RT · R = 1), that can be written in terms of 3 complex mixing angles. In total the high-energy see-saw theory has 9 real unknown parameters. 6. – Oscillations in vacuum One gets easily confused by neutrino oscillations, because it is a quantum phenomenon: a neutrino can oscillate into another neutrino of different mass only thanks to the quantum uncertainty on its energy and momentum. We can derive a general and simple result if we restrict our attention to a stationary flux of neutrinos (e.g. the Sun) or to experiments that only look at time-averaged observables. It is then convenient to work in the basis of eigenstates of the Hamiltonian. The most generic pure state is a superposition of them. In stationary conditions all  interferences between states with different energy average to zero, ei(E−E )t  = 0, when computing any physical observable. Therefore the relative phases between neutrinos with different energies are not observable. This means that in these conditions a neutrino wave is fully described by its energy spectrum: a plane wave is the same thing as a mixture of short wave packets, just as the same light can be obtained as a mixture of circular or linear polarizations. We can to generalize this proof to a neutrino flux described by a density matrix ρ. In fact, let us consider, e.g., a neutrino produced in π decay, π → νμ μ ¯. A wave function describes the neutrino and the muon. As usual, when we want we restrict to a subset (the neutrino) of the full system (neutrino and muon), we are forced to introduce mixed states. Furthermore, the particle that produces the neutrino usually interacts in a non negligible way with the environment (e.g. a stopped π at FermiLab, or a 7 Be in the Sun): using a density matrix for neutrinos is simpler than studying the wave function of FermiLab, or of the Sun. Again, the result simply follows by the fact that the off-diagonal  terms of ρ oscillate in time as ei(E−E )t and therefore average to zero. More formally, iρ˙ = [H, ρ] = 0 in stationary conditions, so that the off-diagonal elements of ρ between

30

A. Strumia

states with different energy vanish. The diagonal elements of ρ tell the neutrino energy spectrum. Our simplifying conditions are valid in all realistic experiments: an experiment that can measure the time of neutrino detection with uncertainty Δt ∼ ns is not sensible to interference among neutrinos with E − E   1/Δt ∼ 10−6 eV, which is much smaller than any realistic energy resolution. Neutrinos with different mass and the same energy oscillate, as we now describe. We start considering the simplest case: two generation mixing, so that we just have one mixing angle, θ, and no CP violation. We assume that at the production region, x ≈ 0, νe are produced with energy E. To study their propagation it is convenient to utilize the basis of neutrino mass eigenstates ν1,2 , and write |ν(x = 0) = |νe  = cos θ|ν1  + sin θ|ν2 . Since ν1 and ν2 have different masses, the initial νe becomes some other mixture of ν1 and ν2 , or equivalently of νμ and νe . At a generic x |ν(x) = eip1 x cos θ|ν1  + eip2 x sin θ|ν2 . The probability of νμ appearance at the detection region x ≈ L is (12)

P (νe → νμ ) = |νμ |ν(L)|2 = sin2 2θ sin2

(p2 − p1 )L Δm212 L

sin2 2θ sin2 . 2 4E

Since in all cases of experimental interest E  mi , in the final passage we have used the ultra-relativistic approximation pi = E − m2i /2E, valid at dominant order in the small neutrino masses and defined Δm212 ≡ m22 − m21 . By swapping the names of the two mass eigenstates, ν1 ↔ ν2 , one realizes that the couples (θ, Δm212 ) and (π/2 − θ, −Δm212 ) describe the same physics. On the contrary (θ, Δm212 ) and (π/2 − θ, Δm212 ) are physically different. However, eq. (12) shows that vacuum oscillations depend only on sin2 2θ and do not discriminate these two cases. Oscillation effects are maximal at θ = π/4. The νe disappearance probability is [7, 1] P (νe → νe ) = |νe |ν(L)|2 = 1 − P (νe → νμ ). A convenient numerical relation is found restoring  and c factors: (13)

Sij ≡ sin2

Δm2ij L GeV c3 Δm2ij L = sin2 1.27 .  4E eV2 Km E

The oscillation wavelength is (14)

λ=

E eV2 4πE = 2.48 km . Δm2 GeV Δm2ij

31

Phenomenology of neutrino masses

(a)

1

(b) L = 10000 km Survival probability

excluded

Δm 2

10− 1

10− 2 B 10− 3

A

10− 2

1000 100

20

1

C

10− 1 sin2 2θ

0.8 0.6 0.4 0.2 0

1

Fig. 5. – (Colour online) (a) Typical bound on oscillations. (b) Averaging oscillations over neutrinos with different energies (here represented with different colors) gives a smooth survival probability (thick curve). This plot holds for atmospheric neutrinos, where the path-length (upper axis) is measured from the direction of arrival (lower axis).

Like decays, oscillations are suppressed at large energy by the m/E “time-dilatation” Lorentz factor, well known from relativity. In order to see oscillations one needs neutrinos of low enough energy, that have small or vanishing detection cross-sections. In a realistic setup, the neutrino beam is not monochromatic, and the energy resolution of the detector is not perfect: one needs to average the oscillation probability around some energy range ΔE. Furthermore, the production and detection regions are not points: one needs to average around some path-length range ΔL. Including these effects, in fig. 5a we show a typical experimental bound on oscillations. We can distinguish three regions: A) Oscillations with short base-line, where Sij 1. In this limit oscillations reduce to first-order perturbations: P (νe → νμ ) (Heμ L)2

with

Heμ ≡

(mν m†ν )eμ Δm2 = sin 2θ. 2Eν Eν

This explains the slope of the exclusion region in part A of fig. 5a. Since P (νe → νμ ) ∝ L2 , and since going far from an approximatively point-like neutrino source the neutrino flux decreases as 1/L2 , choosing the optimal location for the detector is usually not straightforward. C) Averaged oscillations, where Sij  = 1/2 as illustrated in fig. 5b. In this limit one has (15)

P (νe → νμ ) =

1 sin2 2θ, 2

P (νe → νe ) = 1 −

1 sin2 2θ. 2

The information on the oscillation phase is lost due to the insufficient experimental

32

A. Strumia

C

θ

2

sin

c (e.g. Λ)

2

sin

θ

C

θ

c

co

θ

θ

s2

s2

s2

s2

θ

co

C

ν1

like

2

νe

co

θ

νe

d (π)

sin

2

ν2

sin

θ

resolution in E or L. Consequently, one can rederive the transition probabilities (15) by combining probabilities rather than amplitudes. Using the language of quantum mechanics, one refers sometimes to this case as the “classical limit”. The computation proceeds in full analogy to the usual computation of flavor-violating decays and detection of hadrons, as illustrated by the following equation:

s (K)

C

co

The down-type quark q produced in decays of charmed hadrons, c → q¯ ν , is |q = cos θC |d + sin θC |s, giving rise to a π with probability cos2 θC and to K with probability sin2 θC — not to π ↔ K oscillations. If the produced particle is later detected via a weak interaction, it can again be detected as a charmed hadron, with “charm survival probability” equal to sin4 θC + cos4 θC . Similarly, the computation of the νe → νe survival probability sketched in the figure can be performed as follows, without any reference to neutrino oscillations. At x ≈ 0 one produces: – a ν1 with probability cos2 θ (later detected as a νμ with probability sin2 θ, or as a νe with probability cos2 θ), and – a ν2 with probability sin2 θ (later detected as a νμ with probability cos2 θ, or as a νe with probability sin2 θ). Simple trigonometry allows to verify that the result is the same as in (15) P (νe → νμ ) = 2 sin2 θ cos2 θ,

P (νe → νe ) = sin4 θ + cos4 θ.

This implies that experimental bounds on oscillations can be approximatively summarized by reporting two numbers: the upper bound on Δm2 assuming maximal mixing, and the upper bound on θ assuming large Δm2 . If some effect is discovered, the most characteristic phenomenon appears in the intermediate region. B) The intermediate region. Due to the uncertainty ΔE on the energy E (and possibly on the path length L), coherence gets lost when neutrinos of different energy have too different oscillation phases φ ∼ Δm2 L/E, i.e. when (16)

Δφ ≈

ΔE φ1 E

Therefore one can see n ∼ E/ΔE oscillations before they average out.

33

Phenomenology of neutrino masses

7. – Vacuum oscillations of 3 neutrinos Some results follow from general arguments:   ν → ν¯ ) = 1. – Conservation of probability implies  P (ν → ν ) =  P (¯ – CPT invariance implies P (ν → ν ) = P (¯ ν → ν¯ ). – In many situations CP invariance approximately holds and implies P (ν → ν ) = P (¯ ν → ν¯ ). Together with CP T -invariance, CP -invariance is equivalent to T invariance P (ν → ν ) = P (ν → ν ). Therefore T conserving (breaking) contributions are even (odd) in the base-line L. Up to an irrelevant overall phase, the transition amplitude is A(ν → ν ) = ν |ν (L) = ν |U (L)|ν  =

(17)



V i Vi∗ e2iϕi ,

i

 m · m† L , U (L) = exp −i 2E 

where ϕi ≡ −m2i L/4E. We see that Majorana phases do not affect oscillations. The corresponding formulæ for antineutrinos are obtained by exchanging V ↔ V ∗ , so that in the final formula only the sign of the CP -violating term changes. Equation (17) can be used in numerical computations. With some trigonometry, it is possible to rewrite it in a longer but more explicit form: (18)

2 2 2 13 23 P ((ν ) → (ν ) ) = δ + p12  sin ϕ12 + p sin ϕ13 + p sin ϕ23  ±8J sin ϕ12 sin ϕ13 sin ϕ23   , 

where the − sign holds for neutrinos, the + sign for anti-neutrinos,  is the permutation tensor (123 = +1), and Sij = sin2 ϕij ,



∗ ∗ p ii = −4ReVi V i V i Vi ,

and in particular

2 p ii = −4|Vi Vi |

Oscillations depend only on one CP -violating phase and (19)

8J ≡ cos θ13 sin 2θ13 sin 2θ12 sin 2θ23 · sin φ ≤ 4/33/2 .

Up to a sign J equals to twice the area of the “unitarity triangle” with sides Vi Vi∗ and V i V∗ i . All such triangles have the same area. As expected the CP -violating contribution vanishes if  =  and is odd in L. In the small-L limit, it is proportional to L3 . It is small when any mixing angle θij or any oscillation phase ϕij is small; it averages to zero when some ϕij  1. These properties explain why it is difficult to observe CP -violation.

34

A. Strumia

Data indicate that |Δm213 | ≈ |Δm223 | = Δm2atm ≈ 3 · 10−3 eV2 ,

Δm212 = Δm2sun ≈ 10−4 eV2 .

Therefore it is interesting to consider the limit |Δm223 |  Δm212 , i.e. S13 ≈ S23 . In this limit vacuum oscillations no longer depend on the sign of Δm223 , which controls if neutrinos have “normal” or “inverted” hierarchy. Inserting the explicit parametrization of V in eq. (10), the oscillation probabilities can be simplified to (20a)

P (νe → νμ ) = s223 sin2 2θ13 S23 + c223 sin2 2θ12 S 12 + PCP ,

(20b)

P (νe → ντ ) = c223 sin2 2θ13 S23 + s223 sin2 2θ12 S 12 − PCP ,

(20c)

P (νμ → ντ ) = c413 sin2 2θ23 S23 − s223 c223 sin2 2θ12 S 12 + PCP ,

and (20d)

P (νe → νe ) = 1 − sin2 2θ13 S23 − c413 sin2 2θ12 S12 ,

(20e)

P (νμ → νμ ) = 1 − 4c213 s223 (1 − c213 s223 )S23 − c423 sin2 2θ12 S 12 ,

(20f)

P (ντ → ντ ) = 1 − 4c213 c223 (1 − c213 c223 )S23 − s423 sin2 2θ12 S 12 ,

where PCP = 8J sin2 ϕ13 sin ϕ12 . For simplicity we set θ13 = 0 in the coefficients of the underlined S 12 terms. 8. – Atmospheric oscillations The evidence for νμ → ντ oscillations is named “atmospheric” because it was established by the SuperKamiokande experiment studying atmospheric neutrinos [8], generated by collisions of primary cosmic rays. SK detects atmospheric neutrinos through CC scattering on nucleons, ν N → N  . SK is a cylindrical tank containing 50000 ton ˇ of light water surrounded by photomultipliers. Measuring the Cerenkov light, SK can ± ± distinguish an e from a μ and reconstruct its energy E and its direction ϑ . At high energy E  mN the scattered lepton roughly keeps the direction of the neutrino. The neutrino energy Eν  E cannot be measured. The main SK data are the angular distribution of e± and of μ± at energies of a few GeV. Without oscillations, these angular distributions must be up/down symmetric, since the Earth is a sphere. e-like events show no asymmetry, while the zenith-angle distribution of μ events is clearly asymmetric, The flux of upward-going muons is about two times lower than the flux of downward muons. Therefore the data can be interpreted assuming that nothing happens to νe and that νμ oscillate into ντ (or into sterile νs ). Neglecting Earth matter corrections, we assume that νe do not oscillate, P (νe → νe ) = 1, P (νe ↔ νμ ) = 0, and (21)

P (νμ → νμ ) = 1 − sin2 2θatm sin2

Δm2atm L . 4Eν

35

Phenomenology of neutrino masses

(a) 4

(b) NuMi

Δ m 2atm in 10-3 eV2

3.5

3 SK L / E 2.5

K2K

2 SK 1.5 0.5

0.6

0.7

0.8

0.9

1

2

sin 2θ atm

Fig. 6. – Global fits for atmospheric (a) and solar (b) oscillation parameters.

The main result can be approximately extracted from very simple considerations. Looking at the zenith-angle dependence, we notice that downward-going neutrinos (↓) are almost unaffected by oscillations, while upward-going neutrinos (↑) feel almost averaged oscillations, and therefore their flux is reduced by a factor 1 − 12 sin2 2θatm . This must be equal to the up/down ratio N↑ /N↓ = 0.5 ± 0.05, so that sin2 2θatm = 1 ± 0.1. Furthermore, multi-GeV neutrinos have energy Eν ∼ 3 GeV, and begin to oscillate around the horizontal direction (cos ϑ ∼ 0), i.e. at a path length of about L ∼ 1000 km. Therefore Δm2atm ∼ Eν /L ∼ 3 10−3 eV2 . SK cannot see a clear oscillation dip because it cannot measure the neutrino energy: the oscillation pattern gets washed when averaging over too different neutrino energies, as illustrated in fig. 5b. The global fit (performed including also the less safe input from MonteCarlo predictions of neutrino fluxes) gives the best-fit values shown in fig. 6a. The K2K [9] and NuMi [10] experiments detected a νμ beam with E ∼ few GeV sent from a distance of a few 100 km, chosen such that the atmospheric phase is maximal. Since its source is known, one can reconstruct the energy of each neutrino from the measured energy and direction of the scattered lepton. Although with poor statistics, these experiments can see an oscillation dip and confirm SK results. 9. – Solar oscillations: KamLAND ˇ KamLAND [12] is a Cerenkov scintillator composed by 1 kton of a liquid scintillator. KamLAND detects ν¯e emitted by mainly Japanese reactors using the ν¯e p → e+ n reaction. The detector can see both the positron and the 2.2 MeV γ-ray from neutron capture on proton. By requiring their delayed coincidence and being located underground and having achieved sufficient radio-purity, KamLAND reactor data are almost background-free.

36

A. Strumia

The effect of oscillations is (22)

P (¯ νe → ν¯e ) = 1 − sin2 2θsun sin2

Δm2sun L 2Eν

up to minor corrections due to Earth matter effects and to the small θ13 atmospheric mixing angle. KamLAND sees a deficit and more importantly confirms that the ν¯e survival probability depends on the neutrino energy as predicted by oscillations. In fact, KamLAND can measure the positron energy, directly linked to Eν¯e ≈ Ee+ + mn − mp . KamLAND 2008 spectral data give a 5σ indication for oscillation dips: the first one at Evis ≈ 7 MeV (where statistics is poor) and the second one at Evis ≈ 4 MeV. Taking into account the average baseline L ≈ 180 km, this second dip occurs at L/Eν¯e ≈ 45 km/MeV. This fixes Δm2sun = 6πEν¯e /L|2nd dip ≈ 8 10−5 eV2 . The global fit of fig. 6b shows that Δm2sun is presently dominantly fixed by KamLAND data, which precisely fixes (23)

Δm2sun = (7.58 ± 0.21) 10−5 eV2 ,

tan2 θsun = 0.56+0.14 −0.09 .

However, another solution exists with θsun → π/2 − θsun , or equivalently with Δm2sun → −Δm2sun : vacuum oscillations cannot discriminate the two cases. We now discuss how solar oscillations in matter tell that the right solution is the one in eq. (23). 10. – The MSW effect Neutrinos of ordinary energies cross the Earth or the Sun without being significantly absorbed. Still, the presence of matter can significantly affect neutrino propagation. This apparently unusual phenomenon has a well-known optical analogue. A transparent medium like air or water negligibly absorbs light, but still significantly reduces its speed: vphase = c/n, where n is the “refraction index”. In some materials or in the presence of an external magnetic field n is different for different polarizations of light, giving rise to characteristic effects, such as birefringence. The same thing happens for neutrinos. Since matter is composed by electrons (rather than by μ and τ ), νe interact differently than νμ,τ , giving rise to a flavour-dependent refraction index. We now compute it and study how oscillations are affected [13, 1]. Forward scattering of neutrinos interferes with free neutrino propagation, giving rise to refraction. Scattering of ν on electrons and quarks mediated by the Z boson is the same for all flavours  = {e, μ, τ }, and therefore does not affect flavour transitions between active neutrinos. The interesting effect is due to νe e scattering mediated by the W -boson, that is described at low energy by the effective Hamiltonian (its sign is predicted by the SM) 4GF Heff = √ (¯ νe γμ PL νe )(¯ eγ μ PL e). 2

37

Phenomenology of neutrino masses

In a background composed by non-relativistic and non-polarized electrons and no positrons (e.g. the Earth, and to excellent approximation the Sun) one has 

 Ne 1 − γ5 e = (1, 0, 0, 0)μ e¯γμ 2 2

and therefore

Heff  =

√ 2GF Ne (¯ νe γ0 PL νe ),

where Ne is the electron number density. Including also the Z-contribution, the effective matter Hamiltonian density in ordinary matter is (24)

Heff  = ν¯ Aγ0 PL ν ,

where A =

√

  Nn diag(1, 1, 1) 2GF Ne diag(1, 0, 0) − 2

is named “matter potential” and is a 3 × 3 flavour matrix. Adding the matter correction to the Hamiltonian density describing free propagation of an ultra-relativistic neutrino, one obtains a modified relation between energy and momentum, as we will now discuss. In ordinary circumstances the neutrino index of refraction n is so close to one, n − 1 A/Eν 1, that optical effects like neutrino lensing are negligible. On the contrary matter effects significantly affect oscillations, since A/(Δm2 /Eν ) can be comparable or larger than one. 11. – Matter oscillations of Majorana or Dirac neutrinos Pure Majorana neutrinos oscillate in vacuum in the same way as pure Dirac neutrinos: the additional CP -violating phases present in the Majorana case do not affect oscillations. In the realistic case of ultrarelativistic neutrinos, this unpleasant result continues to hold also for oscillations in matter. The equations for the neutrino wave functions in the two cases are: Majorana. Neutrinos have only a left-handed component, and are described by a single Weyl field νL . Adding the matter term the equation of motion for the neutrino wave function is (i∂ / − Aγ0 )νL = m¯ νL where m is the symmetric Majorana mass matrix. Squaring, in the ultrarelativistic limit one obtains the dispersion relation (E − A)2 − p2 mm† , i.e. p E − (mm† /2E + A). Dirac. Neutrinos have both a left- and a right-handed component. Their equation of motion is νR + Aγ0 νL , i∂ /νL = m¯

i∂ /ν¯R = m† νL ,

where m is the Dirac mass matrix. Eliminating νR and assuming that A is constant one gets [∂ 2 + mm† + A i∂ /γ0 ]νL = 0. In the ultrarelativistic limit i∂ /γ0 νL 2i∂0 νL , giving the dispersion relation p E − (mm† /2E + A). The density of ordinary matter negligibly changes on a length scale ∼ 1/E (which is even typically smaller than an atom) so that the gradient of A can indeed be neglected.

38

A. Strumia

earth

(a) 7

sun

(b) 102

6 10 N in NA / cm3

N e in NA / cm3

5 4 3

Core

1 10-1

Ne

Nn

2

0

10-2

Mantle

1 0

1

2 3 4 r in 1000 km

5

10-3

6

R = 6.95 108 m 0

0.2

0.4

0.6

0.8

1

r/ R

Fig. 7. – Electron number density profile of (a) the Earth (b) the Sun. The mass density can be obtained multiplying the number density Ne times the mass mN /Ye present for each electron, and remembering that mN NA = gram.

Summarizing, oscillations in matter of ultrarelativistic neutrinos are described by the equation

(25)

d i ν = Hν, dx

where

m · m† H= + A, 2E

⎛

⎞ νe ν = ⎝ν μ ⎠ , ντ

that can be solved starting from the production point knowing which flavour is there produced. A is given in eq. (24) and mm† = V ∗ · diag(m21 , m22 , m23 ) · V T , where V is the neutrino mixing matrix and m1,2,3 ≥ 0 are the neutrino mass eigenvalues. For antineutrinos one needs to change m → m∗ (such that m · m† gets replaced by m† · m = m† m = V ·diag(m21 , m22 , m23 )·V † ; this induces genuine CP -violating effects) and A → −A (the background of ordinary matter breaks CP ). In the case of Majorana neutrinos the mass matrix m is symmetric, so that m∗ = m† . Figure 7 shows the density profiles of the Earth and of the Sun.

12. – Oscillations in constant matter Usually the matter density depends only on the position (e.g. in the sun). Sometimes it is roughly constant (e.g. in the Earth mantle) and it is convenient to define effective energy-dependent neutrino mass eigenvalues m2m , eigenvectors νm and mixing angles θm in matter by diagonalizing H. These effective oscillation parameters depend on the neutrino energy, and of course on the matter density. In the simple case with only the

39

Phenomenology of neutrino masses 1

1- 1 sin2 2θ 2

P(νe

νe )

Non-adiabatic matter effects γ >> 1, PC ≅ cos2 θ

Adiabatic matter resonance γ >> 1, PC ≅ 0

Vacuum oscillations

sin2 θ

0

10-1

1

10

102

103

104

105

Neutrino energy in MeV

Fig. 8. – Behavior of P (νe → νe ) that illustrates the limiting regimes a), b), c) discussed between pages 40 and 41. a) At lower energies matter effects are negligible. b) At intermediate energies matter effects are dominant and adiabatic. c) At higher energies the MSW resonance is no longer adiabatic. The numerical example corresponds to solar oscillations. Absorption is neglected.

νe and νμ flavours one finds that the oscillation parameters in matter are (26) tan 2θm =

S , C

Δm2m =



S2 + C 2,

where

S ≡ Δm2 sin 2θ, √ C ≡ Δm2 cos 2θ ∓ 2 2GF Ne E

and θ and Δm2 are the oscillation parameters in vacuum. The − (+) sign holds for ν (¯ ν ). Figure 8 shows a numerical example. The most noticeable features are: – Unlike vacuum oscillations, matter oscillations distinguish θ from π/2 − θ. – Resonance. If Δm2 cos 2θ > 0 (< 0) the matter contribution can render equal the diagonal elements of the effective neutrino (anti-neutrino) mass matrix, so that θm can be maximal, θm = π/4, even if θ 1. At the resonance Δm2m = Δm2 sin 2θ. Matter effects resonate at (27)

Δm2 Δm2 1.5 g/cm3 Eν ∼ √ = 3 GeV −3 2 . ρYe 10 eV 2 2GF Ne

Numerically the matter potential equals (28)

√ eV2 eV2 Ye ρ Ne 2GF Ne = 0.76 10−7 = 0.76 10−7 . 3 MeV NA /cm MeV g/cm3

A3 . For example, The typical electron number density of ordinary matter is Ne ∼ 1/˚ the density of the mantle of the Earth is ρ ≈ 3 g/cm3 and therefore Ne = ρYe /mN ≈ 1.5NA /cm3 , where NA = 6.022 1023 is the Avogadro number, mN is the nucleon mass and Ye ≡ Ne /(Nn + Np ) ≈ 0.5 the electron fraction. Other characteristic densities are

40

A. Strumia

θ

θ

2

sin

ν2 PC

νe

2

ν2m

sin

m

1 – PC

νe

s2 co

PC

θm

ν1m

1 – PC

ν1

s2

θ

co

Fig. 9. – Propagation of a neutrino from the Sun to the Earth, that leads to eq. (29). See the text.

ρ ∼ 12 g/cm3 in the earth core, ρ ∼ 100 g/cm3 in the solar core, and ρ ∼ m4n ∼ 1014 g/cm3 in the core of a type-II supernova. – Matter-dominated oscillations. When neutrinos have high enough energy the matter term dominates: being flavour-diagonal it suppresses oscillations. In this situation, √ neutrinos oscillate in matter with an energy-independent wave-length λ = π/ 2GF Ne . In the earth mantle λ ∼ 3000 km, comparable to the size of the Earth. 13. – Oscillations in a varying density In order to study solar and supernova neutrinos it is useful to develop an approximation for the oscillation probabilities of neutrinos produced in the core of the star (where matter effects are important), that escape into the vacuum (where matter effects are negligible). At some intermediate point, matter effects can be resonant. Here, we discuss the case of two-neutrino generations in the Sun. Briefly, solar neutrinos behave as follows [13, 1]. 1) νe are produced in the core of the Sun, r ≈ 0. The probability of νe being ν1m (r ≈ 0) or ν2m (r ≈ 0) are cos2 θm and sin2 θm , respectively. When matter effects are dominant νe ν2m (i.e. sin2 θm = 1). 2) The oscillation wavelength λ is much smaller than the solar radius R. Therefore neutrinos propagate for many oscillation wavelengths: the phase averages out so that we have to combine probabilities instead of amplitudes. If the density changes very slowly (“adiabatic approximation”, see below) each neutrino mass eigenstate will remain the same. Otherwise neutrinos will flip to the other mass eigenstate with some level-crossing probability PC that we will later compute: ν2m (r ≈ 0) evolves to (and similarly for 1 ↔ 2).

 ν2m (r ≈ R) = ν2 with probability 1 − PC , ν1m (r ≈ R) = ν1 with probability PC ,

41

Phenomenology of neutrino masses

3) Neutrinos propagate from the Sun to the Earth, and possibly inside the Earth before reaching the detector. We can ignore the small Earth matter effects. 4) Finally, the ν1 (ν2 ) is detected as νe with probability cos2 θ (sin2 θ). Combining all these probabilities, as summarized in fig. 9, one gets (29)

1 P (νe → νe ) = + 2



1 − PC 2

 cos 2θ cos 2θm ,

where θm is the effective mixing angle at the production point. It is instructive to specialize eq. (29) to a few limiting cases: a) P (νe → νe ) = 1 − 12 sin2 2θ (averaged vacuum oscillations) when matter effects are negligible: θm = θ and PC = 0. This case is realized for solar neutrinos at lower energies. b) P (νe → νe ) = sin2 θ when cos 2θ2m = −1 and neutrinos propagate adiabatically (PC = 0). This case is realized for solar neutrinos at higher energies. c) P (νe → νe ) = 1 − 21 sin2 2θ when cos 2θm = −1 and in the extreme non-adiabatic limit (PC = cos2 θ). This value of PC can be computed by considering very dense matter that abruptly terminates in vacuum. The produced neutrino νe ν2m does not change flavour at the transition region, since it is negligibly short. Therefore PC = |νe |ν1 |2 = cos2 θ. To see why P (νe → νe ) is equal to averaged vacuum oscillations let us follow the neutrino path: matter effects are very large and block oscillations around and after the production point, until they become suddenly negligible. We intuitively expect that PC = 0 when the variation of the matter density is “smooth enough”, i.e. “adiabatic”. A precise computation can be done by writing the evolution equation i dν/dx = H(x)ν in the basis of instantaneous matter mass eigenstates νm . Let us just quote the more-or-less intuitive final result. A resonance is adiabatic if γ ∼ γ˜ θ2  1, where γ˜ is the number of vacuum oscillations (wavelength λ0 = 4πEν /Δm2 ) present in the typical length scale where the matter potential changes (r0 = |d ln A/dr|−1 res ). In the Sun γ˜ ≈

Δm2 /Eν , eV2 /MeV

10−9

having used the approximate density Ne (r) = 245NA /cm3 × exp[−10.54 r/R]. The solar neutrino anomaly is due to oscillations with large mixing angle and Δm2 ≈ 7 10−5 eV2 . The level crossing scheme is shown in fig. 10b and corresponds to a broad adiabatic resonance: at Eν ∼ 10 MeV one has γ  1 and consequently PC = 0. The resonance ceases to be adiabatic at Eν  10 GeV, much higher than the maximal solar neutrino energy. Figure 8 illustrates the behavior of P (νe → νe ).

42

A. Strumia

small mixing

12 10 8 6 4 2 0

ne nm,t

0

0.1

0.2

0.3 0.4 r/ R sun

tan2 θ = 0.4

(b) 14 m νm in meV

m νm in meV

(a) 14

0.5

0.6

12 10 8 6 4 2 0

0

0.1

0.2

0.3 0.4 r/ R sun

0.5

0.6

Fig. 10. – (Colour online) Variation of the matter neutrino eigenstates inside the Sun for Eν = 10 MeV, Δm2 = 7 · 10−5 eV2 and m1 = 0 (i.e. m2 ≈ 8 meV). Dark red (light blue) denotes the νe (νμ,τ ) flavour component.

We skip the computation of PC , which could be relevant in the case of atmospheric oscillations of supernova neutrinos, if θ13  few degrees [1]. 14. – Solar neutrinos Nuclear reactors produce energy via nuclear fission and thereby emit ν¯e . The Sun produces energy via nuclear fusion and thereby emits νe . In both cases, neutrinos have a typical MeV-scale nuclear energy. We have seen that it is experimentally difficult to detect neutrinos with such low energies. Lighter stars like the Sun shine by burning protons into helium: (30)

4p + 2e → 4 He + 2νe

(Q = 26.7 MeV).

Having 6 particles in the initial state the reaction proceeds in a sequence of steps giving a complex energy spectrum of neutrinos. The first step pp → de+ νe gives rise to ∼ 99% of the neutrinos. Their flux is precisely known (and can be computed from the luminosity of the Sun), but the maximal energy of such pp neutrinos is only 0.42 MeV ∼ 2mp −md −me , so that it is difficult to detect them. Most experiments focussed on the most energetic νe , up to almost 20 MeV, that arise from one of the last steps, decay of 8 B. Such boron neutrinos are a small fraction of all solar neutrinos, and for many years it was unclear if the observed deficit was due to oscillations or to solar model uncertainties. The SNO experiment settled the issue. SNO is a real-time experiment similar to SK and smaller than it. The crucial improvement is that SNO employs 1 kton of salt heavy water rather than water, so that neutrinos can interact in different ways, allowing to measure separately the νe and the total νe,μ,τ fluxes: SNO is the first solar neutrino appearance experiment. The most important SNO data are produced by two interactions not present in SK:

43

Phenomenology of neutrino masses

CC Only νe can produce νe d → ppe. SNO sees the scattered electron and measures its direction and energy. NC All active neutrinos can break deuterons: νe,μ,τ d → νe,μ,τ pn. Salt allowed to tag the n with enhanced efficiency, because neutron capture by 35 Cl produces multiple γ-rays. In this way SNO [11] confirmed the solar model prediction or the total neutrino flux, and measured the energy-averaged survival probability P (νe → νe ) ≡ Φ(νe )/Φ(νe,μ,τ ) = 0.357 ± 0.030. This should be compared with the theoretical prediction for P (νe → νe ), given by a simple expressions that does not depend on the solar density profile because solar oscillations are adiabatic to an excellent level of approximation. At Eν  MeV matter effects dominate such that νe produced around the center of the Sun coincide with the ν2 eigenstate in matter and exit as the ν2 eigenstate in vacuum, so that P (νe → νe ) sin2 θ12 . In the energy range explored by SNO, matter effects at the production region are not fully dominant, and the above approximation gets slightly corrected to (31)

P (νe → νe ) ≈ 1.15 sin2 θ12 ,

so that

tan2 θ12 = 0.45 ± 0.05.

Solar matter effects allowed to discriminate θ12 from π/2 − θ12 , finding that the lighter neutrino is more electron-like. These considerations allow to understand the result of the global fit of solar data in fig. 6b. 15. – Known unknowns The present results on oscillation parameters are summarized by table I and illustrated in fig. 3. The solar and atmospheric oscillations have been discussed as 2 independent two-neutrino oscillations, and this is obtained from the 3-neutrino framework because Δm2sun is too small to affect atmospheric oscillations, and θ13 is too small to affect solar oscillations. So far we discovered two mixing angles, θsun = θ12 and θatm = θ23 and we only have an upper bound on the third angle θ13 , that tells the e component of the most splitted neutrino mass eigenstate ν3 . As a consequence the sign of Δm223 = Δm2atm is not known and two different neutrino mass spectra are allowed: the first possibility in fig. 3 corresponds to Δm223 > 0 and is called “normal”, the second spectrum corresponds to Δm223 < 0 and is called “normal”. The sign of Δm212 = +Δm2sun is known because we observed matter oscillations of solar neutrinos. If θ13 = 0, oscillations in matter can discriminate the two cases, similarly to what already happened in the solar case. The experimental program that hopes to achieve this goal and later to measure the CP violating phase φ will involve reactor experiments (2CHOOZ), long base-line experiments, initially using a conventional neutrino beam and an off-axis detector (T2K, NOνA), and later maybe a neutrino factory beam or a β-beam.

44

A. Strumia

Oscillation experiments are insensitive to the absolute neutrino mass scale (parameterized by the mass of the lightest neutrino) and to the 2 Majorana phases α and β. Other types of experiments can study some of these quantities and the nature of neutrino masses. They are: – β-decay experiments, that to good approximation probe m2νe ≡ (m · m† )ee =  2 2 i |Vei |mi ; – neutrino-less double-beta decay (0ν2β) experiments, that probe the absolute value  of the ee entry of the neutrino mass matrix m, |mee | = | i Vei2 mi | if it is of Majorana type; – cosmological observations (Large-Scale Structures and anisotropies in the Cosmic Microwave Background), that to good approximation probe the sum of neutrino masses, mcosmo ≡ m1 + m2 + m3 . 16. – β-decay Neutrino masses distort the electron spectrum in the β-decay of a nucleus. The most sensitive choice is tritium decay 3

H → 3 He e ν¯e

(Q = m3 H − m3 He = 18.6 keV).

Energy conservation tells that Ee Q−Eν . The maximal electron energy is Q − mν (assuming that all neutrinos have a common mass mν ). Around its end-point, the electron energy spectrum is essentially determined by the neutrino phase space factor ∝ Eν pν . So (32)

 dNe = F (Ee )(Q − Ee ) (Q − Ee )2 − m2νe , dEe

where F (Ee ) can be considered as a constant. The fraction of events in the end-point tail is ∝ (mν /Q)3 , so nuclear decays with a low Q (and a reasonable life-time) offer the best sensitivity. Most recent experiments Troitsk [14] and Mainz [15] found m2νe ≈ 0±3 eV2 . Katrin should improve the sensitivity to mνe down to about 0.3 eV, thanks to an energy resolution of 1 eV. New ideas are needed to plan a β-decay experiment able of reaching the neutrino mass scale suggested by oscillation data. In line of principle, a β-decay experiment is sensitive to neutrino masses mi and mixings |Vei |: 

(33)

 dNe = |Vei |2 F (Ee )(Q − Ee ) dEe i

(Q − Ee )2 − m2i .

This is illustrated in fig. 11a, where we show the combined effect of a H eavier neutrino with little e component and of a Lighter neutrino with sizable e component. Following Kurie we plotted the square root of dNe /dEe , that in absence of neutrino masses is

45

Phenomenology of neutrino masses

(b) counts

(dN/dEe )1/2

(a)

Q − mνH

Q − mνL

Ee

Q

2ν2β

0ν2β

0

Q Total energy in electrons

Fig. 11. – a) β-decay spectrum close to end-point for a massless (dotted) and massive (continuous line) neutrino. b) 2ν2β and 0ν2β spectra.

a linear function close to the end-point. In fig. 12 we show the predicted reduction of the β-decay rate around its end-point. The various curves are for different values of the lightest neutrino mass. In practice the energy resolution is limited, and only broad features can be seen. If it is not possible to resolve the difference between neutrino masses, it is useful to approximate eq. (33) with (32) and present the experimental bound in terms of the single effective parameter (34) m2νe ≡ (m · m† )ee =



|Vei2 |m2i = cos2 θ13 (m21 cos2 θ12 + m22 sin2 θ12 ) + m23 sin2 θ13 .

i

The expected ranges of mνe at 99% CL are plotted in fig. 14b [16].

Rate/(Rate without neutrino masses)

0 0.8 0.6 0.4 0.2

-0.08 -0.06 -0.04 -0.02

Ee – Q in eV

0.01

0.02

0.03

0.04

0.05

0.06

0.07

0 -0.1

0.08

0.09

Rate/(Rate without neutrino masses)

Normal hierarchy 1

0

1

Inverted hierarchy

0.8 0.6 0.4 0.2 0 -0.1

-0.08 -0.06 -0.04 -0.02

0

Ee – Q in eV

Fig. 12. – β-decay spectrum close to end-point predicted for best-fit values of oscillation parameters (we assumed θ13 = 0.1; the difference with respect to θ13 = 0 is hardly visible) and for different values of the lightest neutrino mass, indicated on each curve in the left plot. The vertical lines indicate the positions of (Δm2sun,atm )1/2 . Even without neutrino masses the phase space strongly suppresses the rate around the end-point.

46

A. Strumia p

p

n

n

e

p

e ν

ν ν

n e

ν

e

ν

ΔL = 2 mass e

n

n p

p

Fig. 13. – Feynman diagrams for β decay, double-β decay, and neutrino-less double-β decay.

17. – Neutrino-less double-β decay A few nuclei can only decay through double-β decay, that at the nucleon level corresponds to two simultaneous n → pe¯ νe decays, see fig 13. This is e.g. the case of 76 32 Ge, 76 that cannot β-decay to 33 As because it is heavier. It can only jump to the lighter 76 34 Se: 76

Ge → 76 Se ee ν¯e ν¯e

(Q = 2038.6 keV).

21 Since it is a second-order weak process, 76 32 Ge has a very long life-time, τ ∼ 10 yr. If neutrinos have Majorana masses, the alternative neutrino-less double β-decay (0ν2β) decay 76 Ge → 76 Se ee is also possible. 0ν2β can be distinguished from ordinary 2ν2β decay relying on kinematics: as illustrated in fig. 11b: 0ν2β gives two electrons with total energy equal to Q, while 2ν2β decay gives two electrons with a continuous spectrum that extends up to Q. In real life one has to fight with limited energy resolution and other backgrounds.

(a)

1

(b)

disfavoured by cosmology

3

(c)

Bound from MAINZ and TROITSK

Δm 223

2 Δm 23 < 0

0.01

Δm 223 > 0 99% CL (1 dof)

1

0.003 10-3

| m ee | in eV

m νe in eV

> 0

0.01 0.1 lightest neutrino mass in eV

0.1 0.03

99% CL (1 dof)

0.03 10-3

0.3

0.01 0.1 lightest neutrino mass in eV

Δm 223 < 0 -2

10

Δm 223 > 0

10-3 99% CL (1 dof)

1

10-4 10-4

disfavoured by cosmology

0.1 Δm 223 < 0

disfavoured by 0ν2β

10-1

Sensitivity of KATRIN

0.3

disfavoured by cosmology

m cosmo in eV

1

1

10-3 10-2 10-1 lightest neutrino mass in eV

1

Fig. 14. – 99% CL expected ranges as function of the lightest neutrino mass for the parameters: 1/2 mcosmo = m1 + m2 + m3 probed by cosmology (fig. 14a), mνe ≡ (m · m† )ee probed by β2 decay (fig. 14b), |mee | probed by 0ν2β (fig. 14c). Δm23 > 0 corresponds to normal hierarchy (mlightest = m1 ) and Δm223 < 0 corresponds to inverted hierarchy (mlightest = m3 ), see fig. 3. The darker regions show how the ranges would shrink if the present best-fit values of oscillation parameters were confirmed with negligible error.

Phenomenology of neutrino masses

47

Experiments can measure the Γ0ν2β decay rate. Assuming that neutrino masses are much smaller than Q, the 0ν2β decay amplitude is proportional to mee , the νeL νeL element of the neutrino mass matrix. Assuming three Majorana neutrinos, mee can be written in terms of the neutrino masses mi , mixing angles θij and Majorana CP -violating phases α, β as (35)

mee =



Vei2 mi = cos2 θ13 (m1 e2iβ cos2 θ12 + m2 e2iα sin2 θ12 ) + m3 sin2 θ13 .

i

Γ0ν2β can be computed in terms of ν masses as (36)

  2 Γ0ν2β = G · M2  · |mee | ,

where G is a known phase space factor, M is the nuclear 0ν2β matrix element, plagued by a sizable theoretical uncertainty. The expected ranges of mee at 99% CL are plotted in fig. 14c [16]. 18. – Cosmology Neutrino masses lie somewhere between the present temperature of the universe and the temperature of matter/radiation equality. This is the temperature range during which small primordial inhomogeneities could grow (gravity makes denser regions more dense), eventually forming structures like galaxies. The lessons by S. Pastor show how we can compute and measure the small role played by massive neutrinos, such that today cosmological observations put the strongest upper bound on the neutrino mass scale. REFERENCES [1] For a review see Strumia A. and Vissani F., arXiv:hep-ph/0606054. [2] Llewellyn-Smith C. H., Phys. Rept., 3 (1972) 261; Vogel P. and Beacom J. F., Phys. Rev. D, 60 (1999) 053003 (arXiv:hep-ph/9903554); Strumia A. and Vissani F., Phys. Lett. B, 564 (2003) 42 (arXiv:astro-ph/0302055). [3] Gandhi R., Quigg C., Reno M. and Sarcevic I., Phys. Rev. D, 58 (1998) 093009 (arXiv:hep-ph/9807264); Cooper-Sarkar A. and Sarkar S., arXiv:0710.5303. [4] Kusenko A. and Weiler T., Phys. Rev. Lett., 88 (2002) 161101 (arXiv:hep-ph/0106071). [5] Minkowski P., Phys. Lett. B, 67 (1977) 421; Weinberg S., Phys. Rev. Lett., 43 (1979) ´ G., Phys. Rev. Lett., 44 (1980) 912. 1566; Mohapatra R. N. and Senjanovic [6] Exchange of a fermion SU (2)L triplet instead of a fermion singlet was discussed in Foot R., Lew H., He X.-G. and Joshi G. C., Z. Phys. C, 44 (1989) 441; Exhange of a scalar triplet was discussed in Gelmini G. B. and Roncadelli M., Phys. Lett. B, 99 (1981) 411. [7] ν ↔ ν¯ transitions were discussed in Pontecorvo B., J. Exp. Theor. Phys., 33 (1957) 549; A derivation of the flavour vacuum oscillation formula was given (with a wrong factor 2 in the oscillation phase) in Gribov V. and Pontecorvo B., Phys. Lett. B, 28 (1969) 493. [8] Super-Kamiokande Collaboration, Phys. Rev. D, 74 (2006) 032002 (arXiv:hepex/0604011).

48

A. Strumia

K2K Collaboration, Phys. Rev. D, 74 (2006) 072003 (arXiv:hep-ex/0606032). MINOS Collaboration, arXiv:0711.0769. SNO Collaboration, Phys. Rev. Lett., 92 (2004) 181301 (arXiv:nucl-ex/0309004). KamLAND Collaboration, Phys. Rev. Lett., 94 (2005) 081801 (arXiv:hep-ex/0406035). Wolfenstein L., Phys. Rev. D, 17 (1978) 2369; Mikheyev S. P. and Yu Smirnov A., Sov. J. Nucl. Phys., 42 (1986) 913; First analytical formulae for adiabaticity violation were obtained in Parke S., Phys. Rev. Lett., 57 (1986) 1275; Pizzochero P., Phys. Rev. D, 36 (1987) 2293; Petcov S. T., Phys. Lett. B, 200 (1988) 373; For a review see Kuo T. K. and Pantaleone J., Rev. Mod. Phys., 61 (1989) 937. [14] Troitsk Collaboration, Nucl. Phys. Proc. Suppl., 91 (2001) 280. [15] Mainz Collaboration, Eur. Phys. J. C, 40 (2005) 447 (arXiv:hep-ex/0412056). [16] We here update the results of Feruglio F., Strumia A. and Vissani F., Nucl. Phys. B, 637 (2002) 345 (arXiv:hep-ph/0201291). [9] [10] [11] [12] [13]

DOI 10.3254/978-1-60750-038-4-49

Nuclear physics aspects of double-beta decay P. Vogel Kellogg Radiation Laboratory 106-38, California Institute of Technology Pasadena, CA 91125, USA

Summary. — Comprehensive description of the phenomenology of the ββ decay is given, with emphasis on the nuclear physics aspects. After a brief review of the neutrino oscillation results and of motivation to test the lepton number conservation, the mechanism of the 0νββ is discussed. Its relation to the lepton flavor violation involving charged leptons and its use as a diagnostic tool of the 0νββ mechanism is described. Next the basic nuclear physics of both ββ decay modes is presented, and the decay rate formulae derived. The nuclear physics methods used, the nuclear shell model and the quasiparticle random phase approximation, are described next, and the choice of input parameters is discussed in the following section. Finally, the numerical values of the nuclear matrix elements, and their uncertainty, are presented. In Appendix A the relation of the search for the neutrino magnetic moment to the Dirac versus Majorana nature of neutrinos is described.

1. – Introduction to ββ decay In the last decade neutrino oscillation experiments have convincingly and triumphantly shown that neutrinos have a finite mass and that the lepton flavor is not a conserved quantity. These results opened the door to what is often called the “Physics Beyond the Standard Model”. In other words, accommodating these findings into a consistent scenario requires generalization of the Standard Model of electroweak interactions c Societ`  a Italiana di Fisica

49

50

P. Vogel

that postulates that neutrinos are massless and that consequently lepton flavor, and naturally, also the total lepton number, are conserved quantities. In oscillation experiments only the differences in squares of the neutrino masses, Δm2 ≡ |m22 − m21 |, is measured, and the results do not depend on the charge conjugation properties of neutrinos, i.e. whether they are Dirac or Majorana fermions. Nevertheless, from oscillation experiments one  can establish a lower limit on the absolute value of the neutrino mass scale, m = |Δm2 |. Thus, one or more neutrinos scale   have a mass of at 2 least |Δmatm | ∼ 50 meV, and another one has mass of at least |Δm2sol | ∼ 10 meV. In addition, an upper limit on the masses of all active neutrinos ∼ 2–3 eV can be derived from the combination of analysis of the tritium beta decay experiments and the neutrino oscillation experiments. Combining these constraints, masses of at least two (out of the total of three active) neutrinos are bracketted by 10 meV ≤ mν ≤ 2–3 eV. Thus, neutrino masses are six or more orders of magnitude smaller than the masses of the other fermions. Moreover, the pattern of masses, i.e. the mass ratios of neutrinos, is rather different (even though it remains largely unknown) than the pattern of masses of the up- or down-type quarks or charged leptons. All of these facts suggest that, perhaps, the origin of the neutrino mass is different from the origin (which is still not well understood) of the masses of the other fermions. The discoveries of neutrino oscillations, in turn, are causing a renaissance of enthusiasm in the double-beta decay community and a slew of new experiments that are expected to reach, within a near future, the sensitivity corresponding to the neutrino mass scale. Below I review the current status of the double-beta decay and the effort devoted to reach the required sensitivity, as well as various issues in theory (or phenomenology) related to the relation of the 0νββ decay rate to the absolute neutrino mass scale and to the general problem of the Lepton Number Violation (LNV). And, naturally, substantial emphasis is devoted to the nuclear structure issues. But before doing that, I very briefly summarize the achievements of the neutrino oscillation searches and the role that the search for the neutrinoless double-beta decay plays in the elucidation of the pattern of neutrino masses and mixing. There is a consensus that the measurement of atmospheric neutrinos by the SuperKamiokande collaboration [1] can be only interpreted as a consequence of the nearly maximum mixing between νμ and ντ neutrinos, with the corresponding mass squared difference |Δm2atm | ∼ 2.4×10−3 eV2 . This finding was confirmed by the K2K experiment [2] that uses accelerator νμ beam pointing towards the SuperKamiokande detector 250 km away, as well as by the very recent result of the MINOS experiment located at the Sudan mine in Minnesota 735 km away from Fermilab [3]. Several large long-baseline experiments are being built to further elucidate this discovery, and determine the corresponding parameters even more accurately. At the same time the “solar neutrino puzzle”, which has been with us for over thirty years since the pioneering chlorine experiment of Davis [4], also reached the stage where the interpretation of the measurements in terms of oscillations between the νe and some combination of active, i.e. νμ and ντ neutrinos, is inescapable. In particular, the juxtaposition of the results of the SNO experiment [5] and SuperKamiokande [6], together

Nuclear physics aspects of double-beta decay

51

Fig. 1. – Schematic illustration of the decomposition of the neutrino mass eigenstates νi in terms of the flavor eigenstates. The two hierarchies cannot be, at this time, distinguished. The small admixture of νe into ν3 is an upper limit, and the mass square of the neutrino ν1 , the quantity m21 , remains unknown.

with the earlier solar neutrino flux determination in the gallium experiments [7, 8] and, of course chlorine [4], leads to that conclusion. The value of the corresponding oscillation parameters, however, remained uncertain, with several “solutions” possible, although the so-called Large Mixing Angle (LMA) solution, with sin2 2θsol ∼ 0.8 and Δm2sol ∼ 10−4 eV2 , was preferred. A decisive confirmation of the “solar” oscillations was provided by the nuclear reactor experiment KamLAND [9-11] that demonstrated that the flux of the reactor ν¯e is reduced and its spectrum distorted at the distance L0 ∼ 180 km from nuclear reactors. The most recent KamLAND results [11], combined with the existing solar neutrino data launched the era of precision neutrino measurements, with the −5 corresponding parameters Δm221 = 7.59+0.21 eV2 and tan2 θ12 = 0.47+0.06 −0.21 × 10 −0.05 determined with an unprecedented accuracy. Analysis of that experiment, moreover, clearly shows the oscillatory behavior of the detection probability as a function of L0 /Eν . That behavior can be traced in ref. [11] over two full periods. The pattern of neutrino mixing is further simplified by the constraint due to the Chooz and Palo Verde reactor neutrino experiments [12, 13] which lead to the conclusion that the third mixing angle, θ13 , is small, sin2 2θ13 ≤ 0.1. The two remaining possible neutrino mass patterns are illustrated in fig. 1.

52

P. Vogel

As already stated, oscillation experiments cannot determine the absolute magnitude of the masses and, in particular, cannot at this stage separate two √ rather different scenarios, 2 the hierarchical pattern √ of neutrino masses in which m ∼ Δm and the degenerate 2 pattern in which m  Δm . It is hoped that the search for the neutrinoless double-beta decay, reviewed here, will help in foreseeable future in determining or at least narrowing down the absolute neutrino mass scale, and in deciding which of these two possibilities is applicable. Moreover, even more important is the fact that the oscillation results do not tell us anything about the properties of neutrinos under charge conjugation. While the charged leptons are Dirac particles, distinct from their antiparticles, neutrinos may be the ultimate neutral particles, as envisioned by Majorana, that are identical to their antiparticles. That fundamental distinction becomes important only for massive particles. Neutrinoless double-beta decay proceeds only when neutrinos are massive Majorana particles, hence its observation would resolve the question. The argument for the “Majorana nature” of the neutrinos can be traced to the observation by Weinberg [14] who pointed out almost thirty year ago that there exists only one lowest-order (dimension 5, suppressed by only one inverse power of the corresponding high-energy scale Λ) gauge-invariant operator given the content of the standard model (1)

¯ c H)(H T L), L(5) = C (5) /Λ(L

¯ c = LT C, with C the charge conjugation operator, where L is the lepton doublet, L  = −iτ2 , and H represents the Higgs boson. After the spontaneous symmetry breaking the Higgs acquires vacuum expectation value and the above operator represents the neutrino Majorana mass that violates the total lepton number conservation law by two units (2)

L(M ) =

C (5) v 2 c (¯ ν ν) + h.c., Λ 2

where v ∼ 250 GeV and the neutrinos are naturally light because their mass is suppressed by the large value of the new physics scale Λ in the denominator. The most popular explanation of the smallness of neutrino mass is the see-saw mechanism, which is also roughly thirty years old [15]. In it, the existence of heavy right-handed neutrinos NR is postulated, and by diagonalizing the corresponding mass matrix, one arrives at the formula (3)

mν =

m2D , MN

where the Dirac mass mD is expected to be a typical charged fermion mass and MN is the Majorana mass of the heavy neutrinos NR . Again, the small mass of the standard neutrino is related to the large mass of the heavy right-handed partner. Requiring that mν is of the order of 0.1 eV means that MN (or Λ) is ∼ 1014–15 GeV, i.e. near the GUT scale. That makes this template scenario particularly attractive.

Nuclear physics aspects of double-beta decay

53

Fig. 2. – Atomic masses of the isotopes with A = 136. Nuclei 136 Xe, 136 Ba and 136 Ce are stable against the ordinary β decay; hence they exist in nature. However, energy conservation alone allows the transition 136 Xe → 136 Ba + 2e− (+ possibly other neutral light particles) and the analogous decay of 136 Ce with the positron emission.

Clearly, one cannot reach such high-energy scale experimentally. But, these scenarios imply that neutrinos are Majorana particles, and consequently that the total lepton number should not be conserved. Hence the tests of the lepton number conservation acquires a fundamental importance. Double-beta decay (ββ) is a nuclear transition (Z, A) → (Z + 2, A) in which two neutrons bound in a nucleus are simultaneously transformed into two protons plus two electrons (and possibly other light neutral particles). This transition is possible and potentially observable because nuclei with even Z and N are more bound than the oddodd nuclei with the same A = N + Z. Analogous transition of two protons into two neutrons are also, in principle, possible in several nuclei, but phase space considerations give preference to the former mode. An example is shown in fig. 2. The situation shown there is not really exceptional. There are eleven analogous cases (candidate nuclei) with the Q-value (i.e. the kinetic energy available to leptons) in excess of 2 MeV. There are two basic modes of the ββ decay. In the two-neutrino mode (2νββ) there are 2 ν¯e emitted together with the 2 e− . It is just an ordinary beta decay of two bound neutrons occurring simultaneously since the sequential decays are forbidden by the energy conservation law. For this mode, clearly, the lepton number is conserved and this mode of decay is allowed in the standard model of electroweak interaction. It has been repeatedly observed in a number of cases and proceeds with a typical half-life of ∼ 1019–20 years for the nuclei with Q-values above 2 MeV. In contrast, in the neutrinoless mode (0νββ) only the 2e− are emitted and nothing else. That mode clearly violates the law of lepton

54

P. Vogel

number conservation and is forbidded in the standard model. Hence, its observation would be a signal of a “new physics”. The two modes of the ββ decay have some common and some distinct features. The common features are: – The leptons carry essentially all available energy. The nuclear recoil is negligible, Q/Amp 1. – The transition involves the 0+ ground state of the initial nucleus and (in almost all cases) the 0+ ground state of the final nucleus. In few cases the transition to an excited 0+ or 2+ state in the final nucleus is energetically possible, but suppressed by the smaller phase space available. (But the 2νββ decay to the excited 0+ state has been observed in few cases.) – Both processes are of second order of weak interactions, ∼ G4F , hence inherently slow. The phase space considerations alone (for the 2νββ mode ∼ Q11 and for the 0νββ mode ∼ Q5 ) give preference to the 0νββ which is, however, forbidden by the lepton number conservation. The distinct features are: – In the 2νββ mode the two neutrons undergoing the transition are uncorrelated (but decay simultaneously) while in the 0νββ the two neutrons are correlated. – In the 2νββ mode the sum of the electron kinetic energies T1 + T2 spectrum is continuous and peaked below Q/2. This is due to the electron masses and the Coulomb attraction. As T1 + T2 → Q the spectrum approaches zero approximately like (ΔE/Q)6 . – On the other hand, in the 0νββ mode the sum of the electron kinetic energies is fixed, T1 + T2 = Q, smeared only by the detector resolution. These last distinct features allow one to separate the two modes experimentally by measuring the sum energy of the emitted electrons with a good energy resolution, even if the decay rate for the 0νββ mode is much smaller than for the 2νββ mode. This is illustrated in fig. 3 where the insert shows the situation for the rate ratio of 1 : 106 corresponding to the most sensitive current experiments. Various aspects, both theoretical and experimental, of the ββ decay have been reviewed many times. Here I quote just some of the review articles [16-21], earlier references can be found there. In this introductory section let me make only few general remarks. The existence of the 0νββ decay would mean that on the elementary particle level a six fermion lepton number violating amplitude transforming two d quarks into two u quarks and two electrons is non-vanishing. As was first pointed out by Schechter and Valle [22] more than twenty years ago, this fact alone would guarantee that neutrinos are massive Majorana

Nuclear physics aspects of double-beta decay

55

Fig. 3. – Separating the 0νββ mode from the 2νββ by the shape of the spectrum of the sum of the electron kinetic energies, including the effect of the 2% resolution smearing. The figure is for the rate ratio 1/100 and the insert for 1/106 .

fermions (see fig. 4). This qualitative statement (or theorem), however, does not in general allow us to deduce the magnitude of the neutrino mass once the rate of the 0νββ decay has been determined. It is important to stress, however, that quite generally an observation of any total lepton number violating process, not only of the 0νββ decay, would necessarily imply that neutrinos are massive Majorana fermions. There is no indication at the present time that neutrinos have non-standard interactions, i.e. they seem to have only interactions carried by the W and Z bosons that are contained in the Standard Electroweak Model. All observed oscillation phenomena can be understood if one assumes that neutrinos interact exactly the way the Standard Model prescribes, but are massive fermions forcing a generalization of the model. If we accept this, but in addition assume that neutrinos are Majorana particles, we can in fact relate the 0νββ decay rate to a quantity containing information about the absolute

Fig. 4. – By adding loops involving only standard weak-interaction processes, the ββ decay amplitude (the black box) implies the existence of the Majorana neutrino mass.

56

P. Vogel

neutrino mass. With these caveats that relation can be expressed as (4)

1 0ν 0ν 2 2 0ν = G (Q, Z)|M | mββ  , T1/2

where G0ν (Q, Z) is a phase space factor that depends on the transition Q value and through the Coulomb effect on the emitted electrons on the nuclear charge and that can be easily and accurately calculated (a complete list of the phase space factors G0ν (Q, Z) and G2ν (Q, Z) can be found, e.g. in ref. [23]), M 0ν is the nuclear matrix element that can be evaluated in principle, although with a considerable uncertainty and is discussed in detail later, and finally the quantity mββ  is the effective neutrino Majorana mass, representing the important particle physics ingredient of the process. In turn, the effective mass mββ  is related to the mixing angles θij (or to the matrix elements |Ue,i | of the neutrino mixing matrix) that are determined or constrained by the oscillation experiments, to the absolute neutrino masses mi of the mass eigenstates νi and to the totally unknown additional parameters, as fundamental as the mixing angles θij , the so-called Majorana phases α(i), (5)

mββ  = |Σi |Uei |2 eiα(i) mi |.

Here Uei are the matrix elements of the first row of the neutrino mixing matrix. It is straightforward to use eq. (5) and the known neutrino oscillation results in order to compare mββ  with other neutrino mass related quantities. This is illustrated in fig. 5. Traditionally such plot is made as in the left panel. However, the lightest neutrino mass mmin is not an observable quantity. For that reason the other two panels show the relation of mββ  to the sum of the neutrino masses M that is constrained and perhaps one day will be determined by the “observational cosmology”, and also to mβ  that represent the parameter that can be determined or constrained in ordinary β decay, (6)

mβ 2 = Σi |Uei |2 m2i .

Several remarks are in order. First, the observation of the 0νββ decay and determination of mββ , even when combined with the knowledge of M and/or mβ  does not allow, in general, to distinguish between the normal and inverted mass orderings. This is a consequence of the fact that the Majorana phases are unknown. In regions in fig. 5 where the two hatched bands overlap it is clear that two solutions with the same mββ  and the same M (or the same mβ ) always exist and cannot be distinguished. On the other hand, obviously, if one can determine that mββ  ≥ 0.1 eV we would conclude that the mass pattern is degenerate. And in the so far hypothetical case that one could show that mββ  ≤ 0.01 eV, but non-vanishing nevertheless, the normal hierarchy would be established(1 ). (1 ) In that case also the mβ  in the right panel would not represent the quatity directly related to the ordinary β decay. There are no ideas, however, how to reach the corresponding sensitivity in ordinary β decay at the present time.

Nuclear physics aspects of double-beta decay

57

Fig. 5. – The left panel shows the dependence of mββ  on the absolute mass of the lightest neutrino mmin , the middle one shows the relation between mββ  and the sum of neutrino masses M = Σmi determined or constrained by the “observational cosmology”, and the right one depicts the relation between mββ  and the effective mass mβ  determined or constrained by the ordinary β decay. In all panels the width of the hatched area is due to the unknown Majorana phases and therefore irreducible. The solid lines indicate the allowed regions by taking into account the current uncertainties in the oscillation parameters; they will shrink as the accuracy improves. The two sets of curves correspond to the normal and inverted hierarchies, they merge above about mββ  ∼ 0.1 eV, where the degenerate mass pattern begins.

It is worthwhile noting that if the inverted mass ordering is realized in nature (and neutrinos are Majorana particles), the quantity mββ  is constrained from below by ∼ 0.01 eV. This is within the reach of the next generation of experiments. Also, at least in principle, in the case of the normal hierarchy while all neutrinos could be massive Majorana particles it would still be possible that mββ  = 0. Such a situation, however, requires “fine tuning” or reflects a symmetry of some kind. For example, if θ13 = 0 the relation m1 /m2 = tan2 θ12 must be realized in order that mββ  = 0. This implies, therefore, a definite relation between the neutrino masses and the mixing angles. There is only one value of m1 = 4.6 meV for which this condition is valid. Let us finally remark that the 0νββ decay is not the only LNV process for which important experimental constraints exist. Examples of the other LNV processes with important limits are (7)

μ− + (Z, A) → e+ + (Z − 2, A); experimental branching ratio ≤ 10−12 , K + → μ+ μ+ π − ; experimental branching ratio ≤ 3 × 10−9 , ν¯e emission from the Sun; experimental branching ratio ≤ 10−4 .

58

P. Vogel

Fig. 6. – All these symbolic Feynman graphs potentially contribute to the 0νββ decay amplitude.

However, detailed analysis suggests that the study of the 0νββ decay is by far the most sensitive test of LNV. In simple terms, this is caused by the amount of tries one can make. A 100 kg 0νββ decay source contains ∼ 1027 nuclei that can be observed for a long time (several years). This can be contrasted with the possibilities of first producing muons or kaons, and then searching for the unusual decay channels. The Fermilab accelerators, for example, produce ∼ 1020 protons on target per year in their beams and thus correspondingly smaller numbers of muons or kaons. 2. – Mechanism of the 0νββ decay It has been recognized long time ago that the relation between the 0νββ decay rate and the effective Majorana mass mββ  is to some extent problematic. The rather conservative assumption leading to eq. (4) is that the only possible way the 0νββ decay can occur is through the exchange of a virtual light, but massive, Majorana neutrino between the two nucleons undergoing the transition, and that these neutrinos interact by the standard left-handed weak currents. But that is not the only possible mechanism. LNV interactions involving so far unobserved much heavier (∼ TeV) particles can lead to a comparable 0νββ decay rate. Some of the possible mechanisms of the elementary dd → uu + e− e− transition (the “black box” in fig. 4) are indicated in fig. 6. Only the graph in the upper left corner would lead to eq. (4). Thus, in the absence of additional information about the mechanism responsible for the 0νββ decay, one could not unambiguously infer the magnitude of mββ  from the 0νββ decay rate.

59

Nuclear physics aspects of double-beta decay

In general the 0νββ decay can be generated by i) light massive Majorana neutrino exchange or ii) heavy-particle exchange (see, e.g. refs. [24, 25]), resulting from LNV dynamics at some scale Λ above the electroweak one. The relative size of heavy (AH ) versus light particle (AL ) exchange contributions to the decay amplitude can be crudely estimated as follows [26]: (8)

AL ∼ G2F

mββ  , k 2 

AH ∼ G2F

4 MW , 5 Λ

AH M 4 k 2  , ∼ 5W AL Λ mββ 

where mββ  is the effective neutrino Majorana mass, k 2  ∼ (100 MeV)2 is the typical light neutrino virtuality, and Λ is the heavy scale relevant to the LNV dynamics. Therefore, AH /AL ∼ O(1) for mββ  ∼ 0.1–0.5 eV and Λ ∼ 1 TeV, and thus the LNV dynamics at the TeV scale leads to a similar 0νββ decay rate as the exchange of light Majorana neutrinos with the effective mass mββ  ∼ 0.1–0.5 eV. Obviously, the lifetime measurement by itself does not provide the means for determining the underlying mechanism. The spin-flip and non-flip exchange can be, in principle, distinguished by the measurement of the single-electron spectra or polarization (see, e.g., [27]). However, in most cases the mechanism of light Majorana neutrino exchange, and of heavy-particle exchange, cannot be separated by the observation of the emitted electrons. Thus one must look for other phenomenological consequences of the different mechanisms. Here I discuss the suggestion [28] that under natural assumptions the presence of low-scale LNV interactions, and therefore the absence of proportionality between mββ 2 and the 0νββ decay rate also affects muon lepton flavor violating (LFV) processes, and in particular enhances the μ → e conversion compared to the μ → eγ decay. The discussion is concerned mainly with the branching ratios Bμ→eγ = Γ(μ → (0) eγ)/Γμ and Bμ→e = Γconv /Γcapt , where μ → eγ is normalized to the standard muon (0) decay rate Γμ = (G2F m5μ )/(192π 3 ), while the μ → e conversion is normalized to the capture rate Γcapt . The main diagnostic tool in our analysis is the ratio (9)

R = Bμ→e /Bμ→eγ ,

and the relevance of our observation relies on the potential for LFV discovery in the forthcoming experiments MEG [29] (μ → eγ) and MECO [30] (μ → e conversion)(2 ). At present, the most stringent limit on the branching ratio Bμ→eγ is [31] 1.2 × 10−11 and the MEG experiment aims at the sensitivity about two orders of magnitude better. For the muon conversion the best experimental limit [32] used gold nuclei and reached Bμ→e < 8 × 10−13 . The various proposals aim at reaching sensitivity of about 10−17 . (2 ) Even though the MECO experiment, that aimed at substantial incerase in sensitivity of the μ → e conversion, was recently cancelled, proposals for experiments with similar sensitivity exist elsewhere.

60

P. Vogel

It is useful to formulate the problem in terms of effective low-energy interactions obtained after integrating out the heavy degrees of freedom that induce LNV and LFV dynamics. Thus, we will be dealing only with the Standard Model particles and all symmetry relations will be obeyed. However, operators of dimension > 4 will be suppressed by 1/Λd−4 , where Λ is the scale of new physics. If the scales for both LNV and LFV are well above the weak scale, then one would not expect to observe any signal in the forthcoming LFV experiments, nor would the effects of heavy-particle exchange enter 0νββ at an appreciable level. In this case, the only origin of a signal in 0νββ at the level of prospective experimental sensitivity would be the exchange of a light Majorana neutrino, leading to eq. (4), and allowing one to extract mββ  from the decay rate. In general, however, the two scales may be distinct, as in SUSY-GUT [33] or SUSY seesaw [34] models. In these scenarios, both the Majorana neutrino mass and LFV effects are generated at the GUT scale. The effects of heavy Majorana neutrino exchange in 0νββ are, thus, highly suppressed. In contrast, the effects of GUT scale LFV are transmitted to the TeV scale by a soft SUSY-breaking sector without mass suppression via renormalization group running of the high-scale LFV couplings. Consequently, such scenarios could lead to observable effects in the upcoming LFV experiments but with an O(α) suppression of the branching ratio Bμ→e relative to Bμ→eγ due to the exchange of a virtual photon in the conversion process rather than the emission of a real one. As a specific example, let us quote the SUSY SU(5) scenario where [35] 2  4 |Vts | |Vtd | 100 GeV , 0.04 0.01 mμ¯ 2  4  100 GeV |Vts | |Vtd | −12 = 5.8 × 10 α , 0.04 0.01 mμ¯

(10)

Bμ→eγ = 2.4 × 10−12

(11)

Bμ→e



where the gaugino masses were neglected. Another example is the evaluation of the ratio R = Bμ→e /Bμ→eγ in the constrained see-saw minimal supersymmetric model [36] with very high scale LNV and R ∼ 1/200 for a variety of input parameters. There are, however, exceptions, like the recent evaluation of R in a variety of SUSY SO(10) models [37] with high-scale LNV but with R as large as 0.3 in one case. The case where the scales of LNV and LFV are both relatively low (∼ TeV) is more subtle and requires more detailed analysis. This is the scenario which might lead to observable signals in LFV searches and at the same time generate ambiguities in interpreting a positive signal in 0νββ. This is the case where one needs to develop some discriminating criteria. Denoting the new physics scale by Λ, one has a LNV effective Lagrangian (dimension d = 9 operators) of the form (12)

L0νββ =

 c˜i ˜i , O Λ5 i

˜ i = q¯Γ1 q q¯Γ2 q e¯Γ3 ec , O

Nuclear physics aspects of double-beta decay

61

where we have suppressed the flavor and Dirac structures (a complete list of the ˜ i can be found in ref. [25]). dimension-nine operators O For the LFV interactions (dimension d = 6 operators), one has LLFV =

(13)

 ci Oi , Λ2 i

and a complete operator basis can be found in refs. [38, 39]. The LFV operators relevant to our analysis are of the following type (along with their analogues with L ↔ R): OσL =

(14)

e iL σμν i/ D jL F μν + h.c., (4π)2

OL = iL cjL ckL mL , Oq = i Γ j qΓq q. Operators of the type Oσ are typically generated at one-loop level, hence our choice to explicitly display the loop factor 1/(4π)2 . On the other hand, in a large class of models, operators of the type O or Oq are generated by tree level exchange of heavy degrees of freedom. With the above choices, all non-zero ci are nominally of the same size, typically the product of two Yukawa-like couplings or gauge couplings (times flavor mixing matrices). With the notation established above, the ratio R of the branching ratios μ → e to μ → e+γ can be written schematically as follows (neglecting flavor indices in the effective couplings and the term with L ↔ R) [28]: (15)

Φ  Λ2 λ1 e2 cσL + e2 (λ2 cL + λ3 cq ) log 2 2 48π mμ 2     +λ4 (4π)2 cq + . . .  / e2 |cσL |2 + |cσR |2 .

R=

In the above formula λ1,2,3,4 are numerical factors of O(1), while the overall factor arises from phase space and overlap integrals of electron and muon wave functions in 2 the nuclear field. For light nuclei Φ = (ZFp2 )/(gV2 + 3gA ) ∼ O(1) (gV,A are the vector and axial nucleon form factors at zero momentum transfer, while Fp is the nuclear form factor at q 2 = −m2μ [39]). The dots indicate subleading terms, not relevant for our discussion, such as loop-induced contributions to c and cq that are analytic in external masses and momenta. In contrast the logarithmically enhanced loop contribution given by the second term in the numerator of R plays an essential role. This term arises whenever the operators OL,R and/or Oq appear at tree level in the effective theory and generate one-loop renormalization of Oq [38] (see fig. 7). The ingredients in eq. (15) lead to several observations: i) In the absence of tree level cL and cq , one obtains R ∼ (Φ λ21 α)/(12π) ∼ 10−3 –10−2 , due to gauge coupling and phase space suppression. ii) When present, the logarithmically enhanced contributions, Φ 48π 2

62

P. Vogel

Fig. 7. – Loop contributions to μ → e conversion through the insertion of operators O or Oq , generating the large logarithm.

i.e. when either cL or cq or both are non-vanishing, compensate for the gauge coupling and phase space suppression, leading to R ∼ O(1). iii) If present, the tree-level coupling cq dominates the μ → e rate leading to R  1. Thus, we can formulate our main conclusions regarding the discriminating power of the ratio R: 1) Observation of both the LFV muon processes μ → e and μ → eγ with relative ratio R ∼ 10−2 implies, under generic conditions, that Γ0νββ ∼ mββ 2 . Hence the relation of the 0νββ lifetime to the absolute neutrino mass scale is straightforward. 2) On the other hand, observation of LFV muon processes with relative ratio R  10−2 could signal non-trivial LNV dynamics at the TeV scale, whose effect on 0νββ has to be analyzed on a case by case basis. Therefore, in this scenario no definite conclusion can be drawn based on LFV rates. 3) Non-observation of LFV in muon processes in forthcoming experiments would imply either that the scale of non-trivial LFV and LNV is above a few TeV, and thus Γ0νββ ∼ mββ 2 , or that any TeV scale LNV is approximately flavor diagonal (this is an important caveat). The above statements are illustrated using two explicit cases [28]: the minimal supersymmetric standard model (MSSM) with R-parity violation (RPV-SUSY) and the Left-Right Symmetric Model (LRSM). Limits on the rate of the 0νββ decay were used in the past to constrain parameters of these two models [24]. RPV SUSY . – If one does not impose R-parity conservation [R = (−1)3(B−L)+2s ], the MSSM superpotential includes, in addition to the standard Yukawa terms, lepton and baryon number violating interactions, compactly written as (see, e.g., [40]) (16)

WRPV = λijk Li Lj Ekc + λijk Li Qj Dkc + λijk Uic Djc Dkc + μi Li Hu ,

where L and Q represent lepton and quark doublet superfields, while E c , U c , Dc are lepton and quark singlet superfields. The simultaneous presence of λ and λ couplings

63

Nuclear physics aspects of double-beta decay

d u g

d u u

u d

u d

e

e

Fig. 8. – Gluino exchange contribution to 0νββ (a), and typical tree level contribution to Oq (b) in RPV SUSY.

would lead to an unacceptably large proton decay rate (for SUSY mass scale ΛSUSY ∼ TeV), so we focus on the case of λ = 0 and set μ = 0 without loss of generality. In such case, lepton number is violated by the remaining terms in WRPV , leading to short-distance contributions to 0νββ (see fig. 8(a)), with typical coefficients (cf. eq. (12)) (17)

παs λ2 c˜i 111 ∼ , Λ5 mg˜ m4f˜

πα2 λ2 111 , mχ m4f˜

where αs , α2 represent the strong and weak gauge coupling constants, respectively. The RPV interactions also lead to lepton number conserving but lepton flavor violating operators (see fig. 8(b)), with coefficients (cf. eq. (13)) (18)

c λi11 λ∗i21 ∼ , 2 Λ m2ν˜i

λ∗i11 λi12 , m2ν˜i

 λ∗ cq 11i λ21i ∼ , Λ2 m2d˜

 λ∗ 1i1 λ2i1 , m2u˜i

i

∗

λλ cσ ∼ 2, Λ2 m˜

λ λ∗ , m2q˜

where the flavor combinations contributing to cσ can be found in ref. [41]. Hence, for the generic flavor structure of the couplings λ and λ the underlying LNV dynamics generate both short-distance contributions to 0νββ and LFV contributions that lead to R  10−2 . Existing limits on rare processes strongly constrain combinations of RPV couplings, assuming ΛSUSY is between a few hundred GeV and ∼ 1 TeV. Non-observation of LFV at future experiments MEG and MECO could be attributed either to a larger ΛSUSY

64

P. Vogel

Fig. 9. – Typical doubly charged Higgs contribution to 0νββ (a) and to O (b) in the LRSM.

(> few TeV) or to suppression of couplings that involve mixing among first and second generations. In the former scenario, the short-distance contribution to 0νββ does not compete with the long-distance one (see eq. (8)), so that Γ0νββ ∼ mββ 2 . On the other hand, there is an exception to this “diagnostic tool”. If the λ and λ matrices are nearly flavor diagonal, the exchange of superpartners may still make non-negligible contributions to 0νββ without enhancing the ratio R. LRSM . – The LRSM provides a natural scenario for introducing non-sterile, righthanded neutrinos and Majorana masses [42]. The corresponding electroweak gauge group SU (2)L ×SU (2)R ×U (1)B−L , breaks down to SU (2)L ×U (1)Y at the scale Λ ≥ O (TeV). The symmetry breaking is implemented through an extended Higgs sector, containing a bi-doublet Φ and two triplets ΔL,R , whose leptonic couplings generate both Majorana neutrino masses and LFV involving charged leptons: (19)

  ij ij ˜ ij ˜ ij ˜ Llept = −LL i yD Φ + y˜D Φ LjR − (LL )c i yM ΔL LjL − (LR )c i yM ΔR LjR . Y

˜ L,R = iσ2 ΔL,R , and leptons belong to two isospin doublets Li = ˜ = σ2 Φ∗ σ2 , Δ Here Φ L,R i i (νL,R , L,R ). The gauge symmetry is broken through the VEVs Δ0R  = vR , Δ0L  = 0, Φ = diag(κ1 , κ2 ). After diagonalization of the lepton mass matrices, LFV arises from both non-diagonal gauge interactions and the Higgs Yukawa couplings. In particular, the ΔL,R -lepton interactions are not suppressed by lepton masses and have the structure c L ∼ Δ++ L,R i hij (1±γ5 )j +h.c. The couplings hij are in general non-diagonal and related to the heavy-neutrino mixing matrix [43]. Short-distance contributions to 0νββ arise from the exchange of both heavy ν’s and ΔL,R (see fig. 9(a)), with (20)

g24 1 c˜i ∼ , 4 Λ5 MW M νR R

g23 hee 3 2 , MW MΔ R

where g2 is the weak gauge coupling. LFV operators are also generated through non-

65

Nuclear physics aspects of double-beta decay

diagonal gauge and Higgs vertices, with [43] (see fig. 9(b)) (21)

hμi h∗ie c ∼ , 2 Λ m2Δ

cσ (h† h)eμ ∼ , 2 2 Λ MW R

i = e, μ, τ.

Note that the Yukawa interactions needed for the Majorana neutrino mass necessarily imply the presence of LNV and LFV couplings hij and the corresponding LFV operator coefficients c , leading to R ∼ O(1). Again, non-observation of LFV in the next generation of experiments would typically push Λ into the multi-TeV range, thus implying a negligible short-distance contribution to 0νββ. As with RPV-SUSY, this conclusion can be evaded by assuming a specific flavor structure, namely yM approximately diagonal or a nearly degenerate heavy neutrino spectrum. In both of these phenomenologically viable models that incorporate LNV and LFV at low scale (∼ TeV), one finds R  10−2 [38,41,43]. It is likely that the basic mechanism at work in these illustrative cases is generic: low-scale LNV interactions (ΔL = ±1 and/or ΔL = ±2), which in general contribute to 0νββ, also generate sizable contributions to μ → e conversion, thus enhancing this process over μ → eγ. In conclusion of this section, the above considerations suggest that the ratio R = Bμ→e /Bμ→eγ of muon LFV processes will provide important insight about the mechanism of neutrinoless double-beta decay and the use of this process to determine the absolute scale of neutrino mass. Assuming observation of LFV processes in forthcoming experiments, if R ∼ 10−2 the mechanism of 0νββ is light Majorana neutrino exchange and, therefore, 1/T1/2 ∼ mββ 2 ; on the other hand, if R  10−2 , there might be TeV scale LNV dynamics, and no definite conclusion on the mechanism of 0νββ decay can be drawn based only on LFV processes. 3. – Overview of the experimental status of the search for ββ decay Before embarking on the discussion of the nuclear structure aspects of the ββ decay let us briefly describe the experimental status of the field (more detailed information on this topics are in the lectures by A. Giuliani). The topic has a venerable history. The rate of the 2νββ decay was first estimated by Maria Goeppert-Meyer already in 1937 in her thesis work suggested by E. Wigner, basically correctly. Yet, a first experimental observation in a laboratory experiment was achieved only in 1987, fifty years later [44]. (Note that this is not really exceptional in neutrino physics. It took more than twenty years since the original suggestion of Pauli to show that neutrinos are real particles in the pioneering experiment by Raines and Cowan. And it took another almost fifty years since that time to show that neutrinos are massive fermions.) Why it took so long in the case of the ββ decay? As pointed out above, the typical half-life of the 2νββ decay is ∼ 1020 years. Yet, its “signature” is very similar to natural radioactivity, present to some extent everywhere, and governed by the half-life of ∼ 1010 years or much less for most of the man-made or cosmogenic radioactivities. So, background suppression is the main problem to overcome when one wants to study either of the ββ decay modes.

66

P. Vogel

Fig. 10. – Nuclear matrix elements for the 2νββ decay extracted from the measured half-lives.

During the last two decades the 2νββ decay has been observed in “live” laboratory experiments in many nuclei, often by different groups and using different methods. That shows not only the ingenuity of the experimentalists who were able to overcome the background nemesis, but makes it possible at the same time to extract the corresponding 2ν nuclear matrix element from the measured decay rate. In the 2ν mode the half-life is given by (22)

1/T1/2 = G2ν (Q, Z)|M 2ν |2 ,

where G2ν (Q, Z) is an easily and accurately calculable phase space factor. The resulting nuclear matrix elements M 2ν , which have the dimension energy−1 , are plotted in fig. 10. Note the pronounced shell dependence; the matrix element for 100 Mo is almost ten times larger than the one for 130 Te. Evaluation of these matrix elements, to be discussed below, is an important test for the nuclear theory models that aim at the determination of the analogous but different quantities for the 0ν neutrinoless mode. The challenge of detecting the 0νββ decay is, at first blush, easier. Unlike the continuous 2νββ decay spectrum with a broad maximum at rather low energy where the background suppression is harder, the 0νββ decay spectrum is sharply peaked at the known Q value (see fig. 3), at energies that are not immune to the background, but a bit less difficult to manage. However, as also indicated in fig. 3, to obtain interesting results at the present time means to reach sensitivity to the 0ν half-lives that are ∼ 106 times longer than the 2ν decay half-life of the same nucleus. The historical lessons are illustrated in fig. 11 where the past limits on the 0νββ decay half-lives of various candidate nuclei are translated using eq. (4) into the limits on the effective mass mββ . When plotted in the semi-log plot this figure represents “Moore’s law” of double-beta decay, and indicates that, provided that the past trend will continue,

Nuclear physics aspects of double-beta decay

67

Fig. 11. – The limit of the effective mass mββ  extracted from the experimental lower limits on the p 0νββ decay half-life versus the corresponding year. The gray band near bottom indicates the Δm2atm value. Figure originally made by S. Elliott.

the mass scale corresponding to Δm2atm will be reached in about 7 years. This is also the time scale of significant experiments these days. Note that the figure was made using some assumed values of the corresponding nuclear matrix elements, without including their uncertainty. For such illustrative purposes they are, naturally, irrelevant. The past search for the neutrinoless double-beta decay, illustrated in fig. 11, was driven by the then current technology and the resources of the individual experiments. The goal has been simply to reach sensitivity to longer and longer half-lives. The situation is different, however, now. The experimentalists at the present time can, and do, use the knowledge summarized in fig. 5 to gauge the aim of their proposals. Based on that figure, the range of the mass parameter mββ  can be divided into three regions of interest.  – The degenerate mass region where all mi  Δm2atm . In that region mββ  ≥ 0.1 eV, corresponding crudely to the 0ν half-lives of 1026–27 years. To explore it (in a realistic time frame), ∼ 100 kg of the decaying nucleus is needed. Several experiments aiming at such sensitivity are being built and should run very soon and give results within the next ∼ 3 years. Moreover, this mass region (or a substantial part of it) will be explored, in a similar time frame, by the study of ordinary β decay (in particular of tritium, see the lectures by C. Weinheimer) and by the observational cosmology (see the lectures by S. Pastor). These techniques are independent of the Majorana nature of neutrinos. It is easy, but perhaps premature, to envision various possible scenarios depending on the possible outcome of these measurements.

68

P. Vogel

– The so-called inverted-hierarchy mass region where 20 < mββ  < 100 meV and the 0νββ half-lives are about 1027–28 years. (The name is to some extent a misnomer. In that interval one could encounter not only the inverted hierarchy but also a quasidegenerate but normal neutrino mass ordering. Successful observation of the 0νββ decay will not be able to distinguish these possibilities, as I argued above. This is so not only due to the anticipated experimental accuracy, but more fundamentally due to the unknown Majorana phases.) To explore this mass region, about ton size, sources would be required. Proposals for the corresponding experiments exist, but none has been funded as yet, and presumably the real work will begin depending on the experience with the various ∼ 100 kg size sources. Timeline for exploring this mass region is ∼ 10 years.

– Normal mass hierarchy region where mββ  ≤ 10–20 meV. To explore this mass region, ∼ 100 ton sources would be required. There are no realistic proposals for experiments of this size at present.

Over the last two decades, the methodology for double-beta decay experiments has improved considerably. Larger amounts of high-purity enriched parent isotopes, combined with careful selection of all surrounding materials and using deep-underground sites have lowered backgrounds and increased sensitivity. The most sensitive experiments to date use 76 Ge, 100 Mo, 116 Cd, 130 Te, and 136 Xe. For 76 Ge the lifetime limit reached impressive values exceeding 1025 years [45, 46]. The experimental lifetime limits have been interpreted to yield effective neutrino mass limits typically a few eV and in 76 Ge as low as 0.3–1.0 eV (the spread reflects an estimate of the uncertainty in the nuclear matrix elements). Similar sensitivity to the neutrino mass was reached recently also in the CUORICINO experiment with 130 Te [47]. While all these experiments reported lower limits on the 0νββ decay half-lives, a subset of members of the Heidelberg-Moscow collaboration [48] reanalyzed the data (and used additional information, e.g. the pulse-shape analysis and a different algorithm in the peak search) and claimed to observe a positive signal corresponding, in the latest 25 publication, to the half-life T1/2 = 2.23+0.44 years. That report has been followed −0.31 × 10 by a lively discussion. Clearly, such an extraordinary claim with its profound implications, requires extraordinary evidence. It is fair to say that a confirmation, both for the same 76 Ge parent nucleus, and better yet also in another nucleus with a different Q value, would be required for a consensus. In any case, if that claim is eventually confirmed (and the mechanism of the 0νββ decay determined, i.e. the validity of eq. (4) assured), the degenerate mass scenario will be implicated, and an eventual positive signal in the analysis of the tritium β decay and/or observational cosmology should be forthcoming. For the neutrinoless ββ decay the next generation of experiments, which will use ∼ 100 kg of decaying isotopes will, among other things, test this recent claim.

Nuclear physics aspects of double-beta decay

69

4. – Basic nuclear physics of ββ decay Whether a nucleus is stable or undergoes weak decay is determined by the dependence of the atomic mass MA of the isotope (Z, A) on the nuclear charge Z. This functional dependence near its minimum can be approximated by a parabola, (23)

MA (Z, A) = const + 2bsym

(A/2 − Z)2 Z2 + bCoul 1/3 + me Z + δ, 2 A A

where the symmetry energy coefficient is bsym ∼ 50 MeV and the Coulomb energy coefficient is bCoul ∼ 0.7 MeV. The me Z term represents the mass of the bound electrons; their binding energy, for our purposes, is small enough to be neglected. The last term δ, decisive for the application to the ββ decay, describes nuclear pairing, the increase in binding as pairs of like nucleons couple to angular momentum zero. It is a small correction term and is given in a crude approximation by δ ∼ ±12/A1/2 MeV for odd N and odd Z, or even N and even Z, respectively, while δ = 0 for odd A. Thus, for odd A nuclei, typically only one isotope is stable; nuclei with charge Z smaller than the stable nucleus decay by electron emission, while those with larger Z decay by electron capture or positron emission or by both these modes simultaneously. For even A nuclei the situation is different. Due to the pairing term δ, the even-even nuclei form one parabola while the odd-odd nuclei form another one, at larger mass, as shown in fig. 2, using A = 136 as an example. Consequently, in a typical case there exist two (or three as in fig. 2) even-even nuclei for a given A which are stable against both electron and positron (or EC) decays. As these nuclei usually do not have the same mass, the heavier may decay into the lighter through a second-order weak process in which the nuclear charge changes by two units. This process is double-beta decay. In fig. 12 all nuclei that are practical candidates for the search for the 0νββ decay are listed. All of them exist in nature since their lifetime is longer than the age of the Solar System. However, with a single exception (130 Te), all of them are relatively rare so that large-scale experiments also require a large scale and costly (and sometimes technically difficult) isotope enrichment. Double-beta decay, therefore, proceeds between two even-even nuclei. All ground states of even-even nuclei have spin and parity 0+ and thus transitions 0+ → 0+ are expected in all cases. Occasionally, the population of the low-lying excited states of the daughter nucleus is energetically possible, giving rise to 0+ → 2+ transitions or to transitions to the excited 0+ states. Double-beta decay with the electron emission (both the 2ν and 0ν modes) in which the nuclear charge increases by two units is subject to the obvious condition (24)

MA (Z, A) > MA (Z + 2, A), while MA (Z, A) < MA (Z + 1, A),

where MA is the atomic mass, with the supplementary practical requirement that single-beta decay is absent, or that it is so much hindered (e.g., by the angular momentum selection rules) that it does not compete with double-beta decay.

70

P. Vogel

Fig. 12. – Candidate nuclei for ββ decay with 2e− emission and with the Q value > 2 MeV. The corresponding abundances are also shown.

Double-beta decay with the positron emission and/or electron capture (both the 2ν and 0ν modes) in which the nuclear charge decreases by two units can proceed in three different ways: – Two-positron emission when MA (Z, A) > MA (Z − 2, A) + 4me , – One positron emission and one electron capture when MA (Z, A) > MA (Z − 2, A) + 2me + Be , and – Two electron captures (only the two-neutrino mode, see below for the comment on the 0ν mode) when MA (Z, A) > MA (Z − 2, A) + Be (1) + Be (2), where Be is the positive binding energy of the captured electron. As mentioned above, a complete list of all candidate nuclei (except the double-electron capture) with the corresponding phase space factors for both ββ decay modes is given in ref. [23]. Since the relevant masses are atomic masses, the processes with emission of positrons have reduced phase space (terms with me above). While from the point of view of experimental observation the positron emission seems advantageous (possibility to observe the annihilation radiation), the reduction of phase space means that the corresponding lifetimes are quite long. In fact, not a single such decay has been observed so far. The two-electron capture decay without neutrino emission requires a special comment. Clearly, when the initial and final states have different energies, the process cannot proceed since energy is not conserved. The radiative process, with bremsstrahlung photon emission, however, can proceed and its rate, unlike all the other neutrinoless processes, increases with decreasing Q value [49]. (However, the estimated decay rates are quite

Nuclear physics aspects of double-beta decay

71

small and lifetimes long.) In the extreme case of essentially perfect degeneracy, a resonance enhancement can occur [50]. The case of resonance, though probably unrealistic, perhaps deserves some explanations. The initial state is the atom (Z, A), stable against ordinary β decay. The final state is the ion (Z − 2, A) with electron vacancies H, H  and, in general, with the nucleus in some excited state of energy E ∗ . The resonance occurs if the final energy E = E ∗ + EH + EH 

(25)

is close to the decay Q value, i.e. the difference of the initial and final atomic masses, and a perfect resonance occurs when Q − E is less than the width of the final state which is dominated by the electron hole widths ΓH , ΓH  . The decay rate near resonance is given by the Breit-Wigner–type formula (ΔM )2 1 = Γ, τ (Q − E)2 + Γ2 /4

(26)

where ΔM is the matrix element of the weak interaction between the two degenerate atomic states. The states of definite energy, the eigenstates of the total Hamiltonian, are superpositions of the initial and final states, mixed by ΔM . But in reality, the initial state is pure, and not a state of definite energy, since the final state decays essentially immediately. The mixing matrix element is [50] (27)

ΔM ∼

G2F cos2 θC 2 mββ |ψ(0)|2 gA M 0ν , 4π

where ψ(0) is the amplitude at the origin of the wave function of the captured electrons and M 0ν is the nuclear matrix element discussed later. Clearly, if the resonance can be approached, the decay rate would be enhanced by the factor 4/Γ compared to Γ/(E−Q)2 , where the width Γ is typically tens of eV. Estimates suggest that in such a case the decay lifetime for mββ  ∼ 1 eV could be of the order of 1024–25 years, competitive to the rate with 2e− emission. However, chances of finding a case of a perfect (eV size) resonance when E is of order of MeV are very unlikely. 5. – Decay rate formulae . 5 1. 2ν decay. – Even though the 2νββ decay mode is unrelated to the fundamental particle physics issues, it is worthwhile to discuss it in some detail. This is so because it is the mode that is actually seen experimentally; it is also the inevitable background for the 0νββ decay mode. In nuclear structure theory the corresponding rate is used as a test of the adequacy of the corresponding nuclear models. And various auxiliary experiments can be performed to facilitate the evaluation of the M 2ν nuclear matrix elements.

72

P. Vogel

The derivation of the 2νββ decay rate formula is analogous to the treatment of ordinary beta decay. It begins with the Fermi golden rule for second-order weak decay 2  1 f |Hβ |mm|H β |i = 2πδ(E0 − Σf Ef ) Σm,β , τ Ei − E m − p ν − E e

(28)

where the sum over m includes all relevant virtual states in the intermediate odd-odd nucleus and β labels the different Dirac structures of the weak interaction Hamiltonian. Next we take into account that the weak Hamiltonian is the product of the nuclear and lepton currents; the corresponding formula will include the summation over the indeces of the emitted leptons. Then the summation over the lepton polarizations is performed, taking into account the indistinguishability of the final lepton pairs. Because we are interested in the rate formula, we neglect terms linear in pe and pν that disappear after integration over angles. (The angular distribution of the electrons is of the form 1 · β 2 ) for the 0+ → 0+ transitions, where β i is the velocity of the electron i.) (1 − β The energy denominators are of the following form: Km (Mm ) =

(29)

1 1 ± , Em − Ei + pν1 + Ee1 Em − Ei + pν2 + Ee2

where the + sign belongs to Km and the − sign to Mm and (30)

Lm (Nm ) =

1 1 ± . Em − Ei + pν2 + Ee1 Em − Ei + pν1 + Ee2

The energy denominators in the factors K, M , L, N contain contributions of the nuclear energies Em − Ei , as well as the lepton energies Ee + pν . When calculating the 0+ → 0+ transitions, it is generally a very good approximation to replace these lepton energies with the corresponding average value, i.e. Ee + pν ∼ E0 /2, where the E0 = Mi − Mf is the total decay energy including electron masses. In that case Mm = Nn = 0 and Km = Lm ∼

(31)

1 1 = . Em − Ei + E0 /2 Em − (Mi + Mf )/2

The lepton momenta, for both electrons and neutrinos, are all q < Q and thus qR 1, where R is the nuclear radius. Hence the so-called long-wavelength approximation is valid and the rate formula (with eq. (31)) separates into a product of the nuclear and lepton parts, where the lepton part contains just the phase space integral 



E0 −me

(32)

E0 −E1

F (Z, Ee1 )pe1 Ee1 dEe1 me

F (Z, Ee2 )pe2 Ee2 dEe2 (E0 −Ee1 −Ee2 )5 /30,

me

where the integration over the neutrino momentum was already performed. The single-electron spectrum is obtained by performing integration over dEe2 , while the spectrum of summed electron energies is obtained by changing the variables to Ee1 + Ee2 and

73

Nuclear physics aspects of double-beta decay

Ee1 − Ee2 and performing the integration over the second variable. If an accurate result is required, the relativistic form of the function F (Z, E) must be used and numerical evaluation is necessary. For a qualitative and intuitive picture, one can use the simplified non-relativistic Coulomb expression, so-called Primakoff-Rosen approximation [52] (33)

F (Z, E) =

E 2πZα . p 1 − e−2πZα

This approximation allows us to perform the required integrals analytically. For example, the sum electron spectrum, which is of primary interest from the experimental point of view is then independent of Z, (34)

  dN K3 K4 4K 2 5 ∼ K(T0 − K) 1 + 2K + + + , dK 3 3 30

where K is the sum of the kinetic energies of both electrons, in units of electron mass. The Coulomb effects result in shifting the maximum of dN/dK towards lower energy and in making the approach of dN/dK to zero when K → T0 steeper. The nuclear structure information is contained in the nuclear matrix element; only the Gamow-Teller στ part contributes in the long-wavelength approximation (35)

M 2ν = Σm

0+ σi τi+ |mm|σk τk+ |0+ i  f | Em − (Mi + Mf )/2

.

The individual terms in eq. (35) have a well-defined meaning, in particular for the most relevant ground state to ground state transitions. The terms m|σk τk+ |0+ i  represent the − β strength in the initial nucleus and can be explored in the nucleon exchange reactions such as (p, n) and (3 He, t). On the other hand, the terms 0+ σi τi+ |m represent the f | + β strength in the final nucleus and can be explored in the nucleon charge exchange reactions such as (n, p) and (d, 2 He). In this way one can (up to the sign) explore the contribution of several low-lying states to the M 2ν matrix element. It turns out that in several nuclei the lowest (or few lowest) 1+ states give a dominant contribution to M 2ν . (This is so-called “single-state dominance”.) In those cases the above-mentioned experiments allow one to determine the M 2ν indirectly, independently of the actual 2νββ decay. Such data are, naturally, a valuable testing ground of nuclear theory. On the other hand, it is not a priori clear and easy to decide in which nuclei the sum over the 1+ states in eq. (35) converges very fast and in which nuclei many states contribute. We will return to this issue later. Since, as stated in sect. 3, the half-lives of many 2νββ decays were experimentally determined. We can then extract the values of the nuclear matrix elements M 2ν using eq. (35). They are depicted in fig. 10. For completeness, table I shows the most recent half-life measurements of the 2νββ decay.

74

P. Vogel

Table I. – Summary of experimentally measured 2νββ half-lives and matrix elements, mostly from the NEMO experiment [51] (136 Xe is an important exception where a limit is quoted).

Isotope

2ν T1/2 (y)

2ν MGT (MeV−1 )

48

(3.9 ± 0.7 ± 0.6) × 1019 (1.7 ± 0.2) × 1021 (9.6 ± 0.3 ± 1.0) × 1019 (2.0 ± 0.3 ± 0.2) × 1019 (7.11 ± 0.02 ± 0.54) × 1018 (2.8 ± 0.1 ± 0.3) × 1019 (2.0 ± 0.1) × 1024 (7.6 ± 1.5 ± 0.8) × 1020 > 1.0 × 1022 (90% CL) (9.2 ± 0.25 ± 0.73) × 1018 (2.0 ± 0.6) × 1021

0.05 ± 0.01 0.13 ± 0.01 0.10 ± 0.01 0.12 ± 0.02 0.23 ± 0.01 0.13 ± 0.01 0.05 ± 0.005 0.032 ± 0.003 < 0.01 0.06 ± 0.003 0.05 ± 0.01

Ca Ge 82 Se 96 Zr 100 Mo 116 Cd 128 Te(a) 130 Te 136 Xe 150 Nd 238 (b) U 76

(a ) Deduced from the geochemically determined half-life ratio (b ) Radiochemical result for all decay modes.

128

Te/130 Te.

. 5 2. 0ν rate. – We shall now indicate the derivation of the electron spectra and decay rates associated with the non-vanishing value of mν . The decay rate is of the general form ω0ν = 2πΣspin |R0ν |2 δ(Ee1 + Ee2 + Ef − Mi )d3 pe1 d3 pe2 ,

(36)

where Ef is the energy of the final nucleus and R0ν is the transition amplitude including both the lepton and nuclear parts. The lepton part of the amplitude is written as a product of two left-handed currents 1 1 e¯(x)γρ (1 − γ5 )νj (x)¯ e(y)γσ (1 − γ5 )νk (y), 2 2

(37)

where, νj , νk represent neutrino mass eigenstates j and k, and there is a contraction over the two neutrino operators. The contraction above is allowed only if the neutrinos are Majorana particles. After substitution for the neutrino propagator and integration over the virtual neutrino momentum, the lepton amplitude acquires the form  (38)

−iδjk

1 1 d4 q e−iq(x−y) e¯(x)γρ (1 − γ5 )(q μ γμ + mj ) (1 − γ5 )γσ eC (y). (2π)4 q 2 − m2j 2 2

From the commutation properties of the gamma matrices, it follows that (39)

1 1 1 (1 − γ5 )(q μ γμ + mj ) (1 − γ5 ) = mj (1 − γ5 ). 2 2 2

Nuclear physics aspects of double-beta decay

75

Thus the decay amplitude for purely left-handed lepton currents is proportional to the neutrino Majorana mass mj . Integration over the virtual neutrino energy leads to the replacement of the propagator (q 2 − m2j )−1 by the residue π/ωj with ωj = (q 2 + m2j )1/2 . For the remaining integration over the space part dq we have to consider, besides this denominator ωj , the energy denominators of the second-order perturbation expression. Denoting (40)

An = En − Ei + Ee ,

we find that integration over dq leads to an expression representing the effect of the neutrino propagation between the two nucleons. This expression has the form of a “neutrino potential” and appears in the corresponding nuclear matrix elements, introducing the dependence of the transition operator on the coordinates of the two nucleons, as well as a weak dependence on the excitation energy En − Ei of the virtual state in the odd-odd intermediate nucleus. There are several neutrino potentials as explained in the next subsection. The main one is of the form   ∞ R 2R q sin(qr) dq 1 i q · r (41) H(r, Em ) = . e = dq 2 2 2π 2 gA ω ω + Am πrgA ω(ω + Am ) 0 Here we added the nuclear radius R = 1.2A1/3 fm as an auxiliary factor so that H becomes dimensionless. A corresponding 1/R2 compensates for this auxiliary quantity in the phase space formula. (Note that a consistency between the definitions of the nuclear radius R is required.) The first factor ω in the denominator of eq. (41) is the residue, while the factor ω + Am is the energy denominator of perturbation theory. To obtain the final result, one has to treat properly the antisymmetry between the identical outgoing electrons (see [53]). The momentum of the virtual neutrino is determined by the uncertainty relation q ∼ 1/r, where r ≤ R is a typical spacing between two nucleons. We will show later that in fact the relevant values of r are only r ≤ 2–3 fm, so that the momentum transfer q ∼ 100–200 MeV. For the light neutrinos the neutrino mass mj can then be safely neglected in the potential H(r). (Obviously, for heavy neutrinos, with masses Mj  1 GeV a different procedure is necessary.) Also, given the large value of q the dependence on the difference of nuclear energies Em − Ei is expected to be rather weak and the summation of the intermediate states can be performed in closure for convenience. (We will discuss the validity of that approximation later.) Altogether, we can rewrite the expression for the neutrino potential as (42)

H(r) =

R Φ(ωr), r

where Φ(ωr) ≤ 1 is a relatively slowly varying function of r. From that it follows that a typical value of H(r) is larger than unity, but less than 5–10. In the next subsection

76

P. Vogel

we present the exact expressions for the neutrino potentials and the 0νββ transition operator for the most interesting case of small but finite neutrino Majorana masses mj . For now we use relation (4) and evaluate the phase space function G0ν  (43)

G (Q, Z) ∼ 0ν

F (Z, Ee1 )F (Z, Ee2 )pe1 pe2 Ee1 Ee2 δ(E0 − Ee1 − Ee2 )dEe1 dEe2 .

The constant factor in front of this expression is  (44)

4

(GF cos θC gA )

¯c h R

2

1 1 , ¯ ln(2)32π 5 h

and the values of 1/G0ν listed in ref. [23] are in years, provided that the neutrino masses are in eV. Again, in the Primakoff-Rosen approximation, eq. (33), G0ν is independent of Z and (only the E0 dependence is shown)  (45)

G0ν PR

∼

2E02 E05 2 − + E0 − 30 3 5

 ,

where E0 is expressed in units of the electron mass. Each of the two electrons observed separately will have an energy spectrum determined by the phase space integral. In the Primakoff-Rosen approximation its shape is (46)

dN ∼ (Te + 1)2 (T0 − Te + 1)2 , dTe

where again the kinetic energies are in units of electron mass. It is of interest to contrast the 0ν and 2ν decay modes from the point of view of the phase space integrals. The 0ν mode has the advantage of the two-lepton final state, with the characteristic E05 dependence compared to the four-lepton final state with E011 dependence for the 2ν mode. In addition, the large average momentum of the virtual neutrino, compared with the typical nuclear excitation energy also makes the 0ν decay faster. Thus, if mββ  were to be of the order of me , the 0ν decay would be ∼ 105 times faster than the 2ν decay. It is this phase space advantage which makes the 0νββ decay a sensitive probe for Majorana neutrino mass. Finally, let us remark that it is possible that, in addition to the two electrons, a light boson, the so-called majoron, is emitted. This transition would have a three-body phase space, giving rise to a continuous spectrum peaked at approximately three quarters of the decay energy T0 . We shall not discuss this topic here, but refer to Doi et al. [53] for a discussion of this issue. Also, since we concentrate on the mechanism involving the exchange of light Majorana neutrinos, we will not discuss in any detail the case of hypothetical right-handed currents.

77

Nuclear physics aspects of double-beta decay

. 5 3. Exact expressions for the transition operator . – After the qualitative discussion in the preceding subsection, here we derive the exact expressions for the transition operator. The hadronic current, expressed in terms of nucleon fields Ψ, is   σ ρν (47) J ρ† = Ψτ + gV (q 2 )γ ρ + igM (q 2 ) qν − gA (q 2 )γ ρ γ5 − gP (q 2 )q ρ γ5 Ψ, 2mp where mp is the nucleon mass and q μ is the momentum transfer, i.e. the momentum of the virtual neutrino. Since in the 0νββ decay q 2  q02 , we take q 2 −q 2 . For the vector and axial vector form factors we adopt the usual dipole approximation (48)

gV (q 2 ) = gV /(1 + q 2 /MV2 )2 ,

gA (q 2 ) = gA /(1 + q 2 /MA2 )2 ,

with gV = 1, gA = 1.254, MV = 850 MeV, and MA = 1086 MeV. These form factors are a consequence of the composite nature of nucleons. With high momentum transfer the “elastic” transitions, in which a nucleon remains nucleon and no other hadrons are produced, is reduced. We use the usual form for the weak magnetism, and the Goldberger-Treiman relation for the induced pseudoscalar term: (49)

gM (q 2 ) = (μp − μn )gV (q 2 ),

gP (q 2 ) = 2mp gA (q 2 )/(q 2 + m2π ).

Reducing the nucleon current to the non-relativistic form yields (see ref. [54]) (50)

ρ†

J (x) =

A 

τn+ [g ρ0 J 0 (q 2 ) +

n=1



g ρk Jnk (q 2 )]δ(x − rn ),

k

where J 0 (q 2 ) = gV (q 2 ) and (51)

σn × q q σn · q Jn (q 2 ) = gM (q 2 )i + gA (q 2 )σ − gP (q 2 ) , 2mp 2mp

rn is the coordinate of the n-th nucleon, k = 1, 2, 3, and g ρ,α is the metric tensor. This allows us to derive the effective two-body transition operator in the momentum representation (52) Ω = τ + τ +

(−hF + hGT σ12 − hT S12 ) , q(q + Em − (Mi + Mf )/2)

σ12 = σ1 ·σ2 ,

S12 = 3σ1 ·ˆ qσ2 ·ˆ q −σ12 .

Here hF = gV2 and 2 2  q 2 , hGT = gA q 2 + m2π   2 q 2 2 1 q 2 2 hT = gA . − 3 q 2 + m2π 3 q 2 + m2π 

(53)

1 2 q 2 + 1− 3 q 2 + m2π 3



78

P. Vogel

For simplicity the q 2 dependence of the form factors gV and gA is not indicated and the terms containing 1/m2p are omitted. The parts containing q 2 + m2π come from the induced pseudoscalar form factor gP for which the partially conserved axial-vector hypothesis (PCAC) is used. In order to calculate the nuclear matrix element in the coordinate space, one has to evaluate first the “neutrino potentials” that, at least in principle, depend explicitly on the energy Em of the virtual intermediate state,  ∞ 2 hK (q 2 )qdq , (54) HK (r12 ) = fK (qr12 ) R 2 πgA q + Em − (Mi + M − f )/2 0 where K = F, GT, T , fF,GT = j0 (qr12 ), fT = −j2 (qr12 ), and r12 is the internucleon distance. With these “neutrino potentials” and the spin dependence given in eq. (52) where, naturally, in the tensor operator the unit vector qˆ is replaced with rˆ12 , the nuclear matrix element is now written (see [55])    g 2 M 0ν A 0ν 0ν 0ν f | 2 + MGT + MT |i , = (55) M 1.25 gA where |f  and |i are the ground state wave functions of the final and, respectively, initial nuclei. The somewhat awkward definition of M 0ν is used so that, if needed, one can use an “effective” value of the axial coupling constant gA but still use the tabulated values of the phase space integral G0ν that were evaluated with gA = 1.25. 6. – Nuclear structure issues We will discuss now the procedures to evaluate the ground-state wave functions of the initial and final nuclei |f  and |i and the nuclear matrix element, eq. (55). There are two complementary methods to accomplish this task, the nuclear shell model (NSM) and the quasiparticle random phase approximation (QRPA). Since my own work deals with the QRPA method and the NSM will be covered by Prof. Poves in his seminar, the NSM will be described only superficially and reference to its results will be made mainly in comparison with the QRPA. . 6 1. Nuclear shell model. – The basic idea is schematically indicated in fig. 13. The procedure should describe, at the same time, the energies and transition probabilities involving the low-lying nuclear states as well as the β and ββ decay nuclear matrix elements. The Hamiltonian matrix is diagonalized in one of two possible bases, either     d dπ + + (56) m-scheme |Φα  = Πnljmτ a+ · ν , |0 = a · · · a |0, D ∼ i i1 iA p n which is simple, based on the Slater determinants, and the corresponding Hamiltonian matrix is sparse, but it has a huge dimension (dπ , dν are the dimensions of the proton and

Nuclear physics aspects of double-beta decay

79

Fig. 13. – Schematic illustration of the basic procedures in the nuclear shell model.

neutron included subshells and p, n are the numbers of valence protons and neutrons). The other possible basis uses states coupled to a given total angular momentum J and isospin T . The dimensions are smaller in that case but the evaluation of the Hamiltonian matrix element is more complicated and the corresponding Hamiltonian matrix has fewer zero entries. Due to the high dimensionality of the problem, one cannot include in the valence space too many single-particle orbits. Even the most advanced evaluations include just one oscillator shell, in most ββ decay candidate nuclei the valence space usually omits important spin-orbit partners. (For 76 Ge, for example, the valence space consists of p1/2 , p3/2 , f5/2 and g9/2 orbits for protons and neutrons, while omitting the essentially occupied f7/2 and empty g7/2 spin-orbit partners.) In order to evaluate M 0ν , the closure approximation is used and thus one evaluates (57)

f ||OK ||i,

0 λ,K  + + λ (ai aj ) (˜ with OK = Σijkl Wijkl ak a ˜l )λ ,

where the creation operators create two protons and the annihilation operators annihilate two neutrons. In this way the problem is reduced to a standard nuclear structure problem where the many-body problem is reduced to that of evaluation of two-body transition λ,K densities. The matrix elements Wijkl involve only the mean-field (usually harmonic oscillator) one-body wave functions, and the transition operator defined above. The Hamiltonian Heff is an effective operator. It is not entirely based on first-principle reduction of the free nucleon-nucleon potential. Instead it relies on empirical data, in particular on the energies of states in semi-magic nuclei. At the same time effective operators should be used, in principle. Again, there is no well-defined and well-tested procedure to obtain their form. Instead, one uses empirical data and effective couplings (effective charges for the electromagnetic transitions, effective gA values for the weak transitions). How this procedure works is illustrated in fig. 14 where the experimental β decay halflives for a number of nuclei are compared with calculation and a quenching factor, i.e. the 2 reduction factor of gA of ∼ 0.57 is obtained. And in fig. 15 we show the same comparison for the evaluation of the 2νββ half-lives. (Note that this table is a bit obsolete as far as the experimental data are concerned. In the meantime, the T1/2 for 130 Te was directly determined as 7.6 × 1020 years, and the limit for T1/2 in 136 Xe is longer than indicated, T1/2 > 1.0 × 1022 years, see table I.)

80

P. Vogel

Fig. 14. – Experimental and calculated β-decay half-lives for several nuclei with A = 128–136 (adopted from ref. [56]).

Various aspects of the application of the NSM to the ββ decay were reported in a number of publications [57-63]. We will return to these results later when we compare the NSM and QRPA methods. Here we wish to stress one general result of NSM evaluation of M 0ν . In the NSM one can classify states by their “seniority”, i.e. by the number of valence nucleons that do not form Cooper-like pair and are therefore not coupled to I π = 0+ . The dimensionality of the problem increases fast with seniority and thus it is of interest to see whether a truncation in seniority is possible and in general how the magnitude of M 0ν behaves as a function of the included seniority. This is illustrated in fig. 16 from ref. [63] for the case of the 76 Ge decay. Note that the result does not saturate until sm = 12 which is nearly the maximum seniority possible. That behavior is observed in other cases as well (the saturation in sm is faster in cases when one of the involved nuclei is semi-magic), and is relevant when the comparison to QRPA is made. NSM can also successfully describe nuclear deformation, unlike the usual application of QRPA. Many of the considered ββ decay candidate nuclei are spherical or nearly so. However, one seemingly attractive candidate nucleus, 150 Nd, is strongly deformed. Moreover, the final nucleus, 150 Sm, is considerably less deformed than 150 Nd. Unfortunately, the NSM is unable to describe this system, the dimension is just too large. However, to see qualitatively what the effect of deformation is, or the difference in deformation, might be, in ref. [63] the transition 82 Se → 82 Kr was considered and the initial nucleus

Fig. 15. – Experimental and calculated 2νββ decay half-lives for several nuclei (adopted from ref. [56]).

Nuclear physics aspects of double-beta decay

81

Fig. 16. – The full matrix element M 0ν for the 76 Ge → 76 Se transition evaluated with the indicated maximum seniority sm included (adopted from ref. [63]).

82

Se was artificially deformed by including in the Hamiltonian an additional (unrealistic) quadrupole-quadrupole interaction of varying strength. The results of that exercise are shown in fig. 17. One can see that as the difference in deformation increases the magnitude of M 0ν decreases considerably.

Fig. 17. – The matrix element M 0ν for the 82 Se → 82 Kr transition for a large number of added quadrupole-quadrupole interaction strengths that induces an increased deformation in 82 Se. The magnitude of M 0ν is plotted against the difference in the squared quadrupole moments of the invloved nuclei (adopted from ref. [63]).

82

P. Vogel

What are, then, the outstanding issues for NSM vis a vis the evaluation of the M 0ν matrix elements? The most important one, in my opinion, is the limited size of the valence space. It is not clear how large (or small) the effect of the additional orbits might be. They cannot be, at present, included directly. Perhaps a perturbative method of including them can be developed, either in the shell model codes or in the definition of the effective operator. The other issue, that perhaps could be overcome, is the fact that Heff has not been determined for nuclei with A = 90–110 and thus the M 0ν are not available. Among them nuclei 100 Mo and 96 Zr are important ββ candidate (definitive calculations for 116 Cd were not reported as yet either). . 6 2. QRPA basics. – The QRPA method was first applied to the charge changing modes by Halbleib and Sorensen [64] long time ago and generalized to include the particleparticle interaction by Cha [65]. The use of quasiparticles in QRPA makes it possible to include the pairing correlations in the nuclear ground states in a simple fashion. With pairing included, the Fermi levels for protons and neutrons not only become diffuse, but the number of nucleons in each subshell will not have a sharp value, instead only a mean occupancy of each subshell will have a well-determined value. To include the pairing, we perform first the Bogoliubov transformation relating the particle creation and annihilation operators a†jm , a ˜jm with the quasiparticle creation and † annihilation operators cjm , c˜jm ,

(58)

   uj c†jm a†jm = a ˜jm −vj c†jm

+ vj c˜jm + uj c˜jm

 ,

where a ˜jm = (−1)j−m aj−m and u2j + vj2 = 1. The amplitudes uj , vj are determined in the standard way by solving the BCS gap equations, separately for protons and neutrons, (59)

Δa = (2ja + 1)−1/2 Σc (2jc + 1)1/2 uc vc ja2 ; 0+ ||V ||jc2 ; 0+ ,

N = Σc (2jc + 1)vc2 .

Here N is the number of neutrons or protons and the gaps Δ are empirical quantities deduced from the usual mass differences of the corresponding even-even and odd-A nuclei. We renormalize the strength of the pairing interaction (the coupling constant in ja2 ; 0+ ||V ||jc2 ; 0+ ) slightly such that the empirical gaps Δ are correctly reproduced. Our goal is to evaluate the transition amplitudes associated with charge changing one-body operator T JM connecting the 0+ BCS vacuum |O of the quasiparticles c and c† in the even-even nucleus with any of the J π excited states in the neighboring odd-odd nuclei. In the spirit of RPA we describe such states as harmonic oscillations above the BCS vacuum. Thus (60)

 m m ˜ |J π M ; m = Σpn Xpn,Jπ A† (pn; J π M ) + Ypn,Jπ A(pn; J π M ) |0+ QRPA ,

Nuclear physics aspects of double-beta decay

83

where (61)

A† (pn; J π M ) = Σmp ,mn jp mp , jn mn |JM c†jp ,mp c†jn mn , ˜ A(pn; J π M ) = (−1)J−M A(pn; J π − M ),

and |0+ QRPA  is the “phonon vacuum”, a correlated state that has the zero-point motion corresponding to the given J π built into it. It contains, in addition to the BCS vacuum, components with 4, 8, etc. quasiparticles. The so-called forward- and backward-going amplitudes X and Y as well as the corresponding energy eigenvalues ωm are determined by solving the QRPA eigenvalue equations for each J π  (62)

A −B

    X X B =ω Y Y −A

It is easy to see that eq. (62) is, in fact, an eigenvalue equation for ω 2 of the type (A −B 2 )X = ω 2 X. Hence the physical solutions are such that ω 2 is positive, and we can choose ω to be positive as well. On the other hand, there could be unphysical solutions with ω 2 < 0 and hence imaginary energies. By varying the coupling constants in the matrices A and B, we might trace the development of the solutions from the physical ones with ω > 0 to the situation where ω = 0. That point signals the onset of the region where the original RPA (or QRPA) is no longer applicable, because the ground state must be rearranged. Examples are the transition from a spherical to deform shape, or transition from pairing of neutrons with neutrons (and protons with protons) to a pairing involving neutron-proton pairs. We will see that real nuclei are rather close to that latter situation, and we need to worry about the applicability of the method in such situations. To obtain the matrices A and B, one needs first to rewrite the Hamiltonian in the quasiparticle representation. Then 2

(63)

† ˆ †  c†  )(JM ) |O AJpn,p n = O|(c†p c†n )(JM ) H(c p n

= δpn,p n (Ep + En ) +(up vn up vn + vp un vp un )gph pn−1 , J|V |p n−1 , J +(up un up un + vp vn vp vn )gpp pn, J|V |p n , J, and (64)

J ˆ † † (J−M ) (−1)M (c†  c†  )(JM ) |O Bpn,p  n = O|H(cp cn ) p n

+(−1)J (up vn vp un + vp un up vn )gph pn−1 , J|V |p n−1 , J −(−1)J (up un vp vn + vp vn up un )gpp pn, J|V |p n , J.

84

P. Vogel

Here Ep , En are the quasiparticle energies. The particle-hole and particle-particle interaction matrix elements are related to each other by the Pandya trasformation (65)

−1

pn

 −1

, J|V |p n

!

p , J = −Σ (2J + 1)  p 

J

n n

" J pn , J|V |p n, J. J

Above, in eqs. (63), (64) we have introduced adjustable renormalization constants gph and gpp that multiply the whole block of interaction matrix elements for particle-hole and particle-particle configurations. Typically, one uses a realistic interaction for V (Gmatrix) and thus the nominal values are gph = gpp = 1. The vectors X and Y obey the normalization and orthogonality conditions (for each Jπ) 



m m m m Σpn Xpn Xpn − Ypn Ypn = δm,m ,

(66)

m m m Σm Xpn Xpm n − Ypn Yp n = δpn,p n , 



m m m m Ypn − Ypn Xpn = 0, Σpn Xpn m m m m Σm Xpn Yp n − Ypn Xp n = 0.

For a one-body charge-changing operator T JM the transition amplitude connecting the ground state of an even-even (N, Z) nucleus to the m-th excited state in the odd-odd (N − 1, Z + 1) nucleus is (67)

− m  + m m; JM |T JM |0+ QRPA  = Σpn tpn Xpn,Jπ + tpn Ypn,Jπ ,

where (68)

t− pn = 

u p vn (2J + 1)

p||T J ||n,

J t+ pn = (−1) 

vp u n (2J + 1)

p||T J ||n.

The transition in the opposite direction, to the (N +1, Z −1), is governed by an analogous formula but with X and Y interchanged. Given these formulae, we are able to calculate, within QRPA, the ββ decay nuclear matrix elements, for both 2ν and 0ν modes. However, one needs to make another approx+ imation, since the initial state |0+ QRPA ; i and the final state |0QRPA ; f  are not identical. This is a “two vacua” problem. The standard way of accounting for the difference in the initial and final states is to add the overlap factor (69)

π k ˜m k ˜m Jkπ |Jm  = Σpn Xpn Xpn − Ypn Ypn ,

˜ Y˜ are the solutions of the QRPA equations of motion for the final nucleus. where X,

85

Nuclear physics aspects of double-beta decay

We can now write down the formula for the 2νββ decay matrix element as

M 2ν = Σk,m

(70)

+ + + f ||σ τ + ||1+ σ τ + ||i k 1k |1m 1m || , ωm − (Mi + Mf )/2

m m σ τ + ||i = Σpn p||σ ||n(up vn Xpn + vp un Ypn ), 1+ m || k ˜k + u σ ||n(˜ vp u ˜n X ˜p v˜n Y˜pn ). f ||σ τ + ||1+ pn k  = Σpn p||

For the 0ν decay the corresponding formula is (71)

MK =

 J π ,k

√

i ,kf ,J



(−1)jn +jp +J+J

pnp n

× 2J + 1



jp

jn

J

jn

jp

J

#

×p(1), p (2); J  f¯(r12 )τ1+ τ2+ OK f¯(r12 )  n(1), n (2); J  $ + ×0+ ˜n ]J ||J π kf J π kf |J π ki J π kf i ||[c+ ˜n ]J ||0+ pc i . f ||[cp c The operators OK , K = Fermi (F), Gamow-Teller (GT), and Tensor (T) contain neutrino k ,k potentials, see eq. (54), and spin and isospin operators, and RPA energies EJ iπ f . The + reduced matrix elements of the one-body operators [cp c˜n ]J in eq. (71) depend on the BCS coefficients ui , vj and on the QRPA vectors X, Y ; they are just the reduced matrix elements of the one-body operators like in eqs. (67), (68). The function f¯(r12 ) above represents the effect of short-range correlations. These will be discussed in detail in the next section. Note that the radial matrix elements in eq. (71) are evaluated with unsymmetrized two-particle wave functions. This is a generic requirement of RPA-like procedures as explained in ref. [66] . 6 3. Generalization - RQRPA. – The crucial simplifying point of QRPA (or RPAlike procedures in general) is the quasiboson approximation, the assumption that the commutation relations of a pair of fermion operators can be replaced with the boson commutation relation. That is a good approximation for harmonic, small-amplitude excitations. However, when the strength of the attractive particle-particle interaction increases, the number of quasiparticles in the correlated ground state |0+ QRPA  increases and thus the method violates the Pauli principle. This, in turn, leads to an overestimate of the ground-state correlations, and too early onset of the QRPA collapse. To cure this problem, to some extent, a simple procedure, so-called renormalized QRPA (RQRPA) has been proposed and is widely used [67]. In RQRPA the exact

86

P. Vogel

expectation value of a commutator of two-bifermion operators is replaced with (72)

  + +     0+ QRPA A(pn, JM ), A (p n , JM ) 0QRPA  = δpp δnn " ! 1 + 1 + + + + + ˜p ]00 |0QRPA  − 0QRPA |[an a ˜n ]00 |0QRPA  , × 1 − 0QRPA |[ap a jˆl jˆk &' ( % Dpn,J π

 with jˆp = 2jp + 1. To take this generalization into account, i.e. the non-vanishing values of Dpn,J π − 1, one simply needs to use the amplitudes (73)

m

1/2

m X (pn,J π ) = Dpn,J π X(pn,J π ),

m

1/2

m Y (pn,J π ) = Dpn,J π Y(pn,J π ),

which are orthonormalized in the usual way instead of the standard X and Y everywhere also in the QRPA equation of motion (62). In addition, the matrix elements of the one1/2 body operators, eqs. (67), (68), must be multiplied by Dpn,J π evaluated for the initial and final nuclei. 1/2 In order to calculate the factors Dpn,J π , one has to use an iterative procedure and evaluate in each iteration (74)

  1 J,k Σn Dpn ΣJ,k (2J + 1)|Y pn |2 2jp + 1   1 J,k Σp Dp n ΣJ,k (2J + 1)|Y p n |2 . − 2jn + 1

Dpn = 1 −

Note the summation over the multipolarity J. Even if for the 2ν decay only J π = 1+ are seemingly needed, in RQRPA the equations need to be solved for all multipoles.

7. – Numerical calculations in QRPA and RQRPA In the previous section all relevant expressions were given. But that is not all one needs in order to evaluate the nuclear matrix elements numerically. One has to decide, first of all, what are the relevant input parameters, and how to choose them. The first one to choose, as in all nuclear structure calculations, is the mean-field potential, and which orbits are going to be included in the corresponding expressions. A typical choice is the calculation based on the Coulomb-corrected Woods-Saxon potential. However, sometimes it is advisable to modify the single-particle energy levels in order to better describe certain experimental data (energies in the odd-A nuclei or occupation numbers). Next one needs to choose the nucleon-nucleon potential. For that one typically uses a G-matrix based on a realistic force. For example, in [66] the G-matrix used was derived

Nuclear physics aspects of double-beta decay

87

Fig. 18. – The matrix elements M 2ν for 76 Ge evaluated in QRPA (a) and RQRPA (b). The calculation was performed with the indicated number of included single-particle states (adopted from [16]).

from the Bonn-CD nucleon-nucleon force. It turns out that the results only weakly depend on which parametrization of the nucleon-nucleon interaction is used. Next, the effective coupling constants gph and gpp in the matrices A and B in equation of motion (62) must be determined. The parameter gph is not controversial. It is usually adjusted by requiring that the energy of some chosen collective states, often GamowTeller (GT) giant resonances, is correctly reproduced. It turns out that the calculated energy of the giant GT state is almost independent of the size of the single-particle basis and is well reproduced with gph ≈ 1. Hence, the nominal and unrenormalized value gph = 1 is used in most calculations; that reduces the number of adjustable parameters as well. The choice of the particle-particle parameter gpp is, however, not only important, but also to some extent controversial. One of the issues involved is illustrated in fig. 18. There, one can see that the curves of M 2ν versus gpp are rather different for a different number of included single-paricle states. Thus, the calculated magnitude of M 2ν will change dramatically if gpp is fixed and a different number of levels is included. The other feature, illustrated in fig. 18 is the crossing of M 2ν of zero value for certain gpp that is relatively close to unity. This was first recognized long time ago in ref. [68]. Obviously, if M 2ν = 0, then the 2νββ decay lifetime is infinite; this is a absolute suppression of that mode. Past that zero crossing the curves become very steep and the collapse of QRPA is reached when the slope becomes vertical. Obviously, the zero crossing is moved to larger values of gpp in RQRPA.

88

P. Vogel

Fig. 19. – The calculated 2ν matrix elements for 76 Ge and 82 Se as a function of gpp (solid lines). The experimental values are indicated by the horizontal dashed lines. The dotted line indicates the contribution of the first 1+ state (adopted from [69]).

One can use all of this to an advantage by abandoning the goal of predicting the M 2ν values, but instead using the experimental M 2ν and determine the gpp (for a given set of s.p. states) in such a way that the correct M 2ν is obtained. That is illustrated in fig. 19. The resulting gpp then depends on the number of included single-particle states, and is typically in the range 0.8 ≤ gpp ≤ 1.2 when a realistic G-matrix-based Hamiltonian is used. Adjusting the value of gpp such that the M 2ν is correctly reproduced has been criticized, e.g. in ref. [69]. There is an alternative method, based on the experimentally known β-decay f t values connecting the ground state of the intermediate nucleus (if that happens to be 1+ , which is so only in 100 Tc, 116 In and 128 I among the ββ decay candidates). In QRPA the transition amplitudes for the EC process (decreasing nuclear charge) and β − (increasing nuclear charge) move in opposite way when gpp is increased; the first one goes up while the second one goes down. It is difficult, and essentially impossible to describe all three experimental quantities with the same value of gpp (in the case of 100 Mo this was noted already in [70]). While the differences between these two approaches are not very large (see [55]), there are other arguments why choosing the agreement with M 2ν is preferable. First, it is not really true that the first 1+ state is the only one responsible for the 2νββ decay. This is illustrated for the cases of 76 Ge and 100 Mo in fig. 20. Even though for 100 Mo the first state contributes substantially, higher lying states give non-negligible contribution. And in 76 Ge many 1+ states give comparable contribution. Thus, to give preference to the lowest state is not well justified, the sum is actually what matters. At the same time, the dilemma that the β − and β + /EC matrix elements move with gpp in opposite directions makes it difficult to choose one of them. It seems better to use the sum of the products of the amplitudes, i.e. the 2νββ decay. At the same time, the contribution of the 1+ multipole to the 0νββ matrix element and the corresponding 2νββ matrix element are correlated, even though they are not identical, as also shown in fig. 20. Making sure that the 2νββ matrix element agrees

Nuclear physics aspects of double-beta decay

89

Fig. 20. – Running sum of the 2νββ decay and 0νββ decay (only 1+ component) matrix elements for 76 Ge and 100 Mo (normalized to unity) as a function of the excitation energy Eex = En − (Ei + Ef )/2.

with its experimental value constrains the 1+ part of the 0νββ matrix element as well. Since we are really interested in the M 0ν matrix element, it is relevant to ask why do we fit the important parameter gpp to the 2ν decay lifetime. To understand this, it is relevant to point out that two separate multipole decompositions are built into eq. (71). One is in terms of the J π of the virtual states in the intermediate nucleus, the good quantum numbers of the QRPA and RQRPA. The other decomposition is based on the angular momenta and parities J π of the pairs of neutrons that are transformed into protons with the same J π . In fig. 21 we show that it is essentially only the 1+ multipole that is responsible for the variation of M 0ν with gpp . (Note that in the three variants shown the parameter gpp changes only by 5%.) Fixing its contribution to a related observable (2ν decay) involving the same initial and final nuclear states appears to be an optimal procedure for determining gpp . Moreover, as was shown in [71, 55], this choice, in addition, essentially removes the dependence of M 0ν on the number of the single-particle states (or oscillator shells) in the calculations.

90

P. Vogel

Fig. 21. – The contributions of different intermediate-state angular momenta J π to M 0ν in 100 Mo (positive parities in the upper panel and negative parities in the lower one). We show the results for several values of gpp . The contribution of the 1+ multipole changes rapidly with gpp , while those of the other multipoles change slowly.

. 7 1. Competition between “pairing” and “broken pairs”. – The decomposition based on the angular momenta and parities J π of the pairs of neutrons that are transformed into protons with the same J π is particularly revealing. In fig. 22 we illustrate it both in the NSM and QRPA, with the same single-single particle spaces in each. These two rather different approaches agree in a semiquantitative way, but the NSM entries for J > 0 are systematically smaller in absolute value. There are two opposing tendencies in fig. 22. The large positive contribution (essentialy the same in QRPA and NSM) is associated with the so-called pairing interaction of neutrons with neutrons and protons with protons. As the result of that interaction, the nuclear ground state is mainly composed of Cooperlike pairs of neutrons and protons coupled to J = 0. The transformation of one neutron Cooper pair into one Cooper proton pair is responsible for the J = 0 piece in fig. 22. However, the nuclear Hamiltonian contains, in addition, an important neutron-proton interaction. That interaction, primarily, causes the presence in the nuclear ground state of “broken pairs”, i.e. pairs of neutrons or protons coupled to J =  0. Their effect, as seen in fig. 22, is to reduce drastically the magnitude of M 0ν . In treating these terms, the agreement between QRPA and NSM is only semi-quantitative. Since the pieces related to the “pairing” and “broken pairs” contribution are almost of the same magnitude but of opposite signs, an error in one of these two competing tendencies is enhanced in the

Nuclear physics aspects of double-beta decay

91

Fig. 22. – Contributions of different angular momenta J associated with the two decaying neutrons to the Gamow-Teller part of M 0ν in 82 Se (upper panel) and 130 Te (lower panel). The results of NSM (dark histogram) and QRPA treatments (lighter histogram) are compared. Both calculations use the same single-particle spaces: (f5/2 , p3/2 , p1/2 , g9/2 ) for 82 Se and (g7/2 , d5/2 , d3/2 , s1/2 , h11/2 ) for 130 Te. In the QRPA calculation the particle-particle interaction was adjusted to reproduce the experimental 2νββ decay rate.

final M 0ν . The competition, illustrated in fig. 22, is the main reason behind the spread of the published M 0ν calculations. Many authors use different, and sometimes inconsistent, treatment of the neutron-proton interaction. There are many evaluations of the matrix elements M 0ν in the literature (for the latest review see [21]). However, the resulting matrix elements often do not agree with each other as mentioned above and it is difficult, based on the published material, to decide who is right and who is wrong, and what is the theoretical uncertainty in M 0ν . That was stressed in a powerful way in the paper by Bahcall et al. few years ago [72] where a histogram of 20 calculated values of (M 0ν )2 for 76 Ge was plotted, with the implication that the width of that histogram is a measure of uncertainty. That is clearly not a valid conclusion, as one could see in fig. 23 where the failure of the outliers to reproduce the known 2νββ decay lifetime is indicated. To see some additional reasons why different authors obtain in their calculations different nuclear matrix elements, we need to analyze the dependence of the M 0ν on the distance r between the pair of initial neutrons (and, naturally, the pair of final protons) that are transformed in the decay process. That analysis reveals, at the same time, the

92

P. Vogel

Fig. 23. – Histogram of older published calculated values of (M 0ν )2 for 76 Ge. The failure of some of the calculations to reproduce the known 2νββ decay lifetime is indicated.

various physics ingredients that must be included in the calculations so that realistic values of the M 0ν can be obtained. . 7 2. Dependence on the radial distance. – The simplest and most important neutrino potential has the form (already defined in eq. (41)) (75)

H(r) ∼

R Φ(ωr), r

where R is the nuclear radius introduced here as usual to make the potential, and the resulting M 0ν , dimensionless (the 1/R2 in the phase space factor compensates for this), r is the distance between the transformed neutrons (or protons) and Φ(ωr) is a rather slowly varying function of its argument. From the form of the potential H(r) one would, naively, expect that the characteristic value of r is the typical distance between the nucleons in a nucleus, namely that r¯ ∼ R. However, that is not true, as was demonstrated first in ref. [66] and illustrated in fig. 24. One can see there that the competition between the “pairing” and “broken pairs” pieces essentially removes all effects of r ≥ 2–3 fm. Only the relatively short distances contribute significantly; essentially only the nearest-neighbor neutrons undergo the 0νββ transition. The same result was obtained in the NSM [63]. (We have also shown in [66] that an

Nuclear physics aspects of double-beta decay

93

Fig. 24. – The dependence on r of M 0ν for 76 Ge, 100 Mo and 130 Te. The upper panel shows the full matrix element, and the lower panel shows separately “pairing” (J = 0 of the two participating neutrons) and “broken pair” (J =

0) contributions.

analogous result is obtained in an exactly solvable, semirealistic model. There we also showed that this behaviour is restricted to an interval of the parameter gpp that contains the realistic value near unity.) Once the r dependence displayed in fig. 24 is accepted, several new physics effects clearly need to be considered. These are not nuclear structure issues per se, since they are related more to the structure of the nucleon. One of them is the short-range nucleon-nucleon repulsion known from scattering experiments. Two nucleons strongly repel each other at distances r ≤ 0.5–1.0 fm, i.e. the distances very relevant to evaluation of the M 0ν . The nuclear wave functions used in QRPA and NSM, products of the mean-field single-nucleon wave function, do not take into account the influence of this repulsion that is irrelevant in most standard nuclear structure theory applications. The usual and simplest way to include the effect is to modify the radial dependence of the 0νββ operator so that the effect of short distances (small values of r) is reduced. This is achieved by introducing a phenomenological function f¯(r12 ) in eq. (71). Examples of such Jastrow-like function were first derived in [73] and in a more modern form in [74]. That phenomenological procedure reduces the magnitude of M 0ν by 20–25% as illustrated in fig. 25. Recently, another procedure, based

94

P. Vogel

Fig. 25. – The r dependence of M 0ν in 76 Ge. The four curves show the effects of different treatments of short-range correlations. The resulting M 0ν values are 5.32 when the effect is ignored, 5.01 when the UCOM transformation is applied and 4.14 when the treatment based on the Fermi hypernetted chain and 3.98 when the phenomenological Jastrow function is used (see the text for details).

on the Unitary Correlation Operator Method (UCOM) has been proposed [75]. That procedure, still applied not fully consistently, reduces the M 0ν much less, only by about 5% [76]. It is prudent to include these two possibilities as extremes and the corresponding range as systematic error. Once a consistent procedure is developed, consisting of deriving an effective 0νββ decay operator that includes (probably perturbatively) the effect of the high momentum (or short range), that component of the systematic error could be substantially reduced. Another effect that needs to be taken into account is the nucleon composite nature. At weak interaction reactions with higher momentum transfer the nucleon is less likely to remain nucleon; new particles, for example pions, are often produced. That reduction is included, usually, by introducing the dipole form of the nucleon form factor, already introduced,  (76)

fV,A =

1 2 1 + q 2 /MV,A

2 ,

where the cut-off parameters MV,A have values (deduced in the reactions of free neutrinos with free or quasifree nucleons) ∼ 1 GeV. This corresponds to the nuclon size of ∼ 0.5–1.0 fm. Note that in our case we are dealing with neutrinos far off mass shell, and bound nucleons, hence it is not obvious that the above form factors are applicable. It turns out, however, that once the short-range correlations are properly included (by either of the procedures discussed above) the M 0ν becomes essentially independent of

Nuclear physics aspects of double-beta decay

95

the adopted values when MV,A ≥ 1 GeV. In the past various authors neglected the effect of short-range correlations, and in that case a proper inclusion of nucleon form factor (or their neglect) again causes variations in the calculated M 0ν values. Yet another correction that various authors neglected must be included in a correct treatment. Since r ≤ 2–3 fm is the relevant distance, the corresponding momentum transfer 1/r is of the order of ∼ 200 MeV, much larger than in the ordinary β decay. Hence the induced nucleon currents, in particular the pseudoscalar (since the neutrinos are far off mass shell) give noticeable contributions [66, 77]. Finally, the issue of the axial current “quenching” should be considered. As shown in a rather typical example in fig. 14, calculated values of the GT β-decay matrix elements usually overestimate the corresponding experimental values. The reasons for that are at least qualitatively understood, but the explanation is beyond the scope of these lectures. It suffices to say that one can account for that effect phenomenologically and conveniently, by reducing the value of the axial-vector coupling constant gA to ∼ 1 instead of its true value 1.25. The phenomenon of quenching has been observed only in the GT β decays, so it is not clear whether the same reduction of gA should be used also in the 0νββ decay. Nevertheless, it is prudent to include that possibility as a source of uncertainty. In anticipation, we already used the modified definition M 0ν , see eq. (55). We have, therefore, identified the various physics effects that ought to be included in a realistic evaluation of M 0ν values. The spread of the calculated values, noted by Bahcall et al. [72] can be often attributed to the fact that various authors either neglect some of them, or include them inconsistently. 8. – Calculated M 0ν values Even though we were able to explain, or eliminate, a substantial part of the spread of the calculated values of the nuclear matrix elements, sizeable systematic uncertainty remains. That uncertainty, within QRPA and RQRPA, as discussed in refs. [71, 55], is primarily related to the difference between these two procedures, to the size of the singleparticle space included, whether the so-called quenching of the axial current coupling constant gA is included or not, and to the systematic error in the treatment of short-range correlations [66]. In fig. 26 the full ranges of the resulting matrix elements M 0ν is indicated. The indicated error bars are highly correlated; e.g., if true values are near the lower end in one nucleus, they would be near the lower ends in all indicated nuclei. The figure also shows the most recent NSM results [63]. Those results, obtained with Jastrow-type short-range correlation corrections, are noticeably lower than the QRPA values. That difference is particularly acute in the lighter nuclei 76 Ge and 82 Se. While the QRPA and NSM agree on many aspects of the problem, in particular on the role of the competition between “pairing” and “broken pairs” contributions and on the r dependence of the matrix elements, the disagreement in the actual values remains to be explained. When one compares the 2ν and 0ν matrix elements (figs. 10 and 26), the feature to notice is the fast variation in M 2ν when going from one nucleus to another while M 0ν change only rather smoothly in both QRPA and NSM. This is presumably related to the

96

P. Vogel

Fig. 26. – The full ranges of M 0ν with the two alternative treatments of the short-range correlations. For comparison, the results of a recent Large Scale Shell Model evaluation of M 0ν that used the Jastrow-type treatment of short-range correlations are also shown (triangles).

high momentum transfer (or short range) involved in 0νββ. That property of the M 0ν matrix elements makes the comparison of results obtained in different nuclei easier and more reliable. Table II. – The calculated ranges of the nuclear matrix element M 0ν evaluated within both the QRPA and RQRPA and with both standard (gA = 1.254) and quenched (gA = 1.0) axial-vector couplings. In each case we adjusted gpp so that the rate of the 2νββ decay is reproduced. Column 2 contains the ranges of M 0ν with the phenomenological Jastrow-type treatment of short-range correlations (see I and II), while column 3 shows the UCOM-based results (see ref. [75]). Columns 3 and 5 give the 0νββ decay half-life ranges corresponding to the matrix-element ranges in columns 2 and 4, for mββ  = 50 meV. Adopted from [66].

Nuclear transition Ge → 76 Se Se → 82 Kr 96 Zr → 96 Mo 100 Mo → 100 Ru 116 Cd → 116 Sn 128 Te → 128 Xe 130 Te → 130 Xe 136 Xe → 136 Ba 76

82

(R)QRPA (Jastrow s.r.c.)

(R)QRPA (UCOM s.r.c.)

M 0ν

0ν T1/2 (mββ  = 50 meV)

M 0ν

0ν T1/2 (mββ  = 50 meV)

(3.33, 4.68) (2.82, 4.17) (1.01, 1.34) (2.22, 3.53) (1.83, 2.93) (2.46, 3.77) (2.27, 3.38) (1.17, 2.22)

(6.01, 11.9) × 1026 (1.71, 3.73) × 1026 (7.90, 13.9) × 1026 (1.46, 3.70) × 1026 (1.95, 5.01) × 1026 (3.33, 7.81) × 1027 (1.65, 3.66) × 1026 (3.59, 12.9) × 1026

(3.92, 5.73) (3.35, 5.09) (1.31, 1.79) (2.77, 4.58) (2.18, 3.54) (3.06, 4.76) (2.84, 4.26) (1.49, 2.76)

(4.01, 8.57) × 1026 (1.14, 2.64) × 1026 (4.43, 8.27) × 1026 (8.69, 23.8) × 1025 (1.34, 3.53) × 1026 (2.09, 5.05) × 1027 (1.04, 2.34) × 1026 (2.32, 7.96) × 1026

97

Nuclear physics aspects of double-beta decay

Given the interest in the subject, we show the range of predicted half-lives corresponding to our full range of M 0ν in table II (for mββ  = 50 meV). As we argued above, this is a rather conservative range within the QRPA and its related frameworks. One should keep in mind, however, the discrepancy between the QRPA and NSM results as well as systematic effects that might elude either or both calculations. Thus, as we have seen, while a substantial progress has been achieved, we are still somewhat far from being able to evaluate the 0νββ nuclear matrix elements confidently and accurately. ∗ ∗ ∗ The original results reported here were obtained in collaboration with N. Bell, V. Cirigliano, J. Engel, A. Faessler, M. Gorchtein, A. Kurylov, G. Prezeau, ˇ M. Ramsey-Musolf, V. Rodin, F. Simkovic, P. Wang and M. Wise. The fruitful collaboration with them is gratefully acknowledged.

Appendix A. Neutrino magnetic moment and the distinction between Dirac and Majorana neutrinos The topic of neutrino magnetic moment μν is seemingly unrelated to the 0νββ decay. Yet, as will be shown below, the experimental observation of μν allows one to make important conclusions about the Dirac versus Majorana nature of neutrinos. Hence, it is worthwhile to discuss it here. Neutrino mass and magnetic moments are intimately related. In the orthodox Standard Model neutrinos have a vanishing mass and magnetic moments vanish as well. However, in the minimally extended SM containing gauge-singlet right-handed neutrinos the magnetic moment μν is non-vanishing, but unobservably small [78], (A.1)

3eGF mν . mν = 3 × 10−19 μB μν = √ 2 1 eV 28π

An experimental observation of a magnetic moment larger than that given in eq. (A.1) would be an uneqivocal indication of physics beyond the minimally extended Standard Model. Laboratory searches for neutrino magnetic moments are typically based on the obsevation of the ν-e scattering. Non-vanishing μν will be recognizable only if the corresponding electromagnetic scattering cross-section is at least comparable to the well-understood weak-interaction cross-section. The magnitude of μν (diagonal in flavor or transitional) which can be probed in this way is then given by (A.2)

G F me  |μν | ≡ √ me T ∼ 10−10 μB 2πα



T me

 ,

98

P. Vogel

where T is the electron recoil kinetic energy. Considering realistic values of T , it would be difficult to reach sensitivities below ∼ 10−11 μB using the ν-e scattering. Present limits are about an order of magnitude larger than that. Limits on μν can also be obtained from bounds on the unobserved energy loss in astrophysical objects. For sufficiently large μν the rate of plasmon decay into the ν ν¯ pairs would conflict with such bounds. Since plasmons can also decay weakly into the ν ν¯ pairs, the sensitivity of this probe is again limited by the size of the weak rate, leading to |μν | G F me hωP , ¯ ≡ √ μB 2πα

(A.3)

hωP )2 me T , that limit is stronger than where ωP is the plasmon frequency. Since (¯ that given in eq. (A.2). Current limits on μν based on such considerations are ∼ 10−12 μB . The interest in μν and its relation to neutrino mass dates from ∼ 1990 when it was suggested that the chlorine data [4] on solar neutrinos show an anticorrelation between the neutrino flux and the solar activity characterized by the number of sunspots. A possible explanation was suggested in ref. [79] where it was proposed that a magnetic moment μν ∼ 10−(10–11) μB would cause a precession in solar magnetic field of the neutrinos emitted initially as left-handed νe into unobservable right-handed ones. Even though later analyses showed that the effect does not exist, the possibility of a relatively large μν accompanied by a small mass mν was widely discussed and various models accomplishing that were suggested. If a magnetic moment is generated by physics beyond the Standard Model (SM) at an energy scale Λ, we can generically express its value as μν ∼

(A.4)

eG , Λ

where e is the electric charge and G contains a combination of coupling constants and loop factors. Removing the photon from the diagram gives a contribution to the neutrino mass of order mν ∼ GΛ.

(A.5) We thus have the relationship (A.6)

mν ∼

Λ2 μν μν ∼ −18 [Λ(TeV)]2 eV, 2me μB 10 μB

which implies that it is difficult to simultaneously reconcile a small neutrino mass and a large magnetic moment. These considerations are schematically illustrated in fig. 27. This naive restriction given in eq. (A.6) can be overcome via a careful choice for the new physics, e.g., by requiring certain additional symmetries [80-83]. Note, however, that these symmetries are typically broken by Standard Model interactions. For Dirac neutrinos such symmetry (under which the left-handed neutrino and antineutrino ν and ν c transform as a doublet) is violated by SM gauge interactions. For Majorana neutrinos analogous symmetries are not broken by SM gauge interactions, but are instead violated by SM Yukawa interactions, provided that the charged lepton masses are generated via the standard mechanism through Yukawa couplings to the SM Higgs boson. This suggests

Nuclear physics aspects of double-beta decay

99

Fig. 27. – a) Generic contribution to the neutrino magnetic moment induced by physics beyond the standard model. b) Corresponding contribution to the neutrino mass. The solid and wavy lines correspond to neutrinos and photons respectively, while the shaded circle denotes physics beyond the SM.

that the relation between μν and mν is different for Dirac and Majorana neutrinos. This distinction can be, at least in principle, exploited experimentally, as shown below. Earlier, I have quoted ref. [22] (see fig. 4) to stress that the observation of the 0νββ decay would necessarily imply the existence of a non-vanishing neutrino Majorana mass. Analogous considerations can be applied in this case. By calculating neutrino magnetic moment contributions to mν generated by SM radiative corrections, one may obtain in this way general, “naturalness” upper limits on the size of neutrino magnetic moments by exploiting the experimental upper limits on the neutrino mass. In the case of Dirac neutrinos, a magnetic-moment term will generically induce a radiative correction to the neutrino mass of order [84] (A.7)

mν ∼

μν α Λ2 μν ∼ [Λ(TeV)]2 eV. 16π me μB 3 × 10−15 μB

Taking Λ 1 TeV and mν ≤ 0.3 eV, we obtain the limit μν ≤ 10−15 μB (and a more stringent one for larger Λ), which is several orders of magnitude more constraining than current experimental upper limits on μν . The case of Majorana neutrinos is more subtle, due to the relative flavor symmetries of mν and μν , respectively. For Majorana neutrinos the transition magnetic moments [μν ]αβ are antisymmetric in the flavor indices {α, β}, while the mass terms [mν ]αβ are symmetric. These different flavor symmetries play an important role in the limits, and are the origin of the difference between the magnetic moment constraints for Dirac and Majorana neutrinos.

Fig. 28. – One-loop diagram contributions to the Majorana neutrino mass associated with the magnetic moment that sums to zero (see [85]). The cross indicates the magnetic moment [μ]αβ and the  is the lepton doublet.

100

P. Vogel

Fig. 29. – The one- and two-loop contributions to the Majorana neutrino mass associated with the magnetic moment. Here X is the charged lepton mass insertion (see [85]).

It has been shown in ref. [85] that the constraints on Majorana neutrinos are significantly weaker than those for Dirac neutrinos [84], as the different flavor symmetries of mν and μν lead to a mass term which is suppressed only by charged lepton masses. This conclusion was reached by considering one-loop mixing of the magnetic moment and mass operators generated by Standard Model interactions. The authors of ref. [85] found that if a magnetic moment arises through a coupling of the neutrinos to the neutral component of the SU (2)L gauge boson, the constraints for μτ e and μτ μ are comparable to present experiment limits, while the constraint on μeμ is significantly weaker. Thus, the analysis of ref. [85] leads to a model-independent bound for the transition magnetic moment of Majorana neutrinos that is less stringent than present experimental limits. Those considerations are illustrated in figs. 28 and 29. Even more generally it was shown in ref. [86] that two-loop matching of mass and magnetic moment operators implies stronger constraints than those obtained in [85] if the scale of the new physics Λ ≥ 10 TeV. Moreover, these constraints apply to a magnetic moment generated by either the hypercharge or SU (2)L gauge boson. In arriving at these conclusions, the most general set of operators that contribute at lowest order to the mass and magnetic moments of Majorana neutrinos was constructed, and modelindependent constraints which link the two were obtained. Thus, the results of ref. [86] imply a completely model-independent naturalness bound that —for Λ ≥ 100 TeV— is stronger than the present experimental limits (even for the weakest constrained element μeμ ). On the other hand, for sufficiently low values of the scale Λ the known small values of the neutrino masses do not constrain the magnitude of the magnetic moment μν more than the present experimental limit. Thus, if these conditions are fulfilled, the discovery of μν might be forthcoming any day. The above result means that an experimental discovery of a magnetic moment near the present limits would signify that i) neutrinos are Majorana fermions and ii) new lepton-number–violating physics responsible for the generation of μν arises at a scale Λ which is well below the see-saw scale. This would have, among other things, implications for the mechanism of the neutrinoless double-beta decay and lepton flavor violation as discussed above and in ref. [28].

Nuclear physics aspects of double-beta decay

101

REFERENCES [1] Kajita T. and Totsuka Y., Rev. Mod. Phys., 73 (2001) 85; Ashie Y. et al., Phys. Rev. D, 71 (2005) 112005. [2] Ahn M. H. et al., Phys. Lett. B, 511 (2001) 178; Ahn M. H. et al., hep-ex/0606032. [3] MINOS Collaboration, hep-ex/0607088; arXiv:0708.1495. [4] Cleveland B. T. et al., Astrophys. J., 496 (1998) 505. [5] Ahmad Q. R. et al., Phys. Rev. Lett., 87 (2001) 071301. [6] Fukuda S. et al., Phys. Rev. Lett., 86 (2001) 5651; 5656. [7] Hampel W. et al., Phys. Lett. B, 447 (1999) 127. [8] Abdurashitov J. N. et al., Phys. Rev. C, 60 (1999) 055801. [9] Eguchi K. et al., Phys. Rev. Lett., 90 (2003) 021802. [10] Araki T. et al., Phys. Rev. Lett., 94 (2005) 081801. [11] Abe S. et al., arXiv:0801.4589. [12] Apollonio M. et al., Phys. Lett. B, 466 (1999) 415. [13] Boehm F. et al., Phys. Rev. D, 64 (2001) 112001. [14] Weinberg S., Phys. Rev. Lett., 43 (1979) 1566. [15] Gell-Mann M., Ramond P. and Slansky R., in Supergravity, edited by Freeman D. and Niuwenhuizen P. (North Holland) 1979; Yanagida T., in Proceedings of Workshop on Unified Theory and Baryon Number of Universe, edited by Sawada O. and Sugamoto A. (KEK, Tsukuba) 1979; Mohapatra R. and Senjanovic G., Phys. Rev. Lett, 44 (1980) 912; Minkowski P., Phys. Lett. B, 67 (1977) 421. ˇ [16] Faessler A. and Simkovic F., J. Phys. G, 24 (1998) 2139. [17] Suhonen J. and Civitarese O., Phys. Rep., 300 (1998) 123. [18] Vergados J. D., Phys. Rep., 361 (2002) 1. [19] Elliott S. R. and Vogel P., Annu. Rev. Nucl. Part. Sci., 52 (2002) 115. [20] Elliott S. R. and Engel J., J. Phys. G, 30 (2004) R183. [21] Avignone F. T., Elliott S. R. and Engel J., Rev. Mod. Phys., 80 (2008) 481; arXiv:0708.1033. [22] Schechter J. and Valle J., Phys. Rev. D, 25 (1982) 2951. [23] Boehm F. and Vogel P., Physics of Massive Neutrinos, 2nd edition (Cambridge University Press, Cambridge) 1992. [24] Mohapatra R. N., Phys. Rev. D, 34 (1986) 3457; Vergados J. D., Phys. Lett. B, 184 (1987) 55; Hirsch M., Klapdor-Kleingrothaus H. V. and Kovalenko S. G., Phys. Rev. D, 53 (1996) 1329; Hirsch M., Klapdor-Kleingrothaus H. V. and Panella O., ˇ ¨ssler A., Kovalenko S., Simkovic Phys. Lett. B, 374 (1996) 7; Fa F. and Schwieger ¨s H., Hirsch M., Klapdor-Kleingrothaus J., Phys. Rev. Lett., 78 (1997) 183; Pa ˇ ¨ ssler H. V. and Kovalenko S. G., Phys. Lett. B, 498 (2001) 35; Simkovic F. and Fa A., Progr. Part. Nucl. Phys., 48 (2002) 201. [25] Prezeau G., Ramsey-Musolf M. J. and Vogel P., Phys. Rev. D, 68 (2003) 034016. [26] Mohapatra R. N., Nucl. Phys. Proc. Suppl., 77 (1999) 376. [27] Doi M., Kotani T. and Takasugi E., Prog. Theor. Phys. Suppl., 83 (1985) 1. [28] Cirigliano V., Kurylov A., Ramsey-Musolf M. J. and Vogel P., Phys. Rev. Lett., 93 (2004) 231802. [29] Signorelli G., J. Phys. G, 29 (2003) 2027; see also http://meg.web.psi.ch/docs/ index.html. [30] Popp J. L., Nucl. Instrum. Methods Phys. Res. A, 472 (2000) 354; hep-ex/0101017. [31] Brooks M. L. et al., Phys. Rev. Lett., 83 (1999) 1521. [32] Bertl W. et al., PSI report, unpublished; (2002). [33] Barbieri R., Hall L. J. and Strumia A., Nucl. Phys. B, 445 (1995) 219.

102

P. Vogel

[34] [35] [36] [37] [38] [39] [40]

Borzumati F. and Masiero A., Phys. Rev. Lett., 57 (1986) 961. Barbieri R. and Hall L. J., Phys. Lett. B, 338 (1994) 212. Arganda E., Herrero M. J. and Teixeira A. M., arXiv:0707.2955. Albright C. H. and Chen M.-C., arXiv:0802. 4228 [hep-ph]. Raidal M. and Santamaria A., Phys. Lett. B, 421 (1998) 250. Kitano R., Koike M. and Okada Y., Phys. Rev. D, 66 (2002) 096002. Dreiner H., in Perspectives on Supersymmetry, edited by Kane G. L. (World Scientific) 1998, pp. 462-479. de Gouvea A., Lola S. and Tobe K., Phys. Rev. D, 63 (2001) 035004. Mohapatra R. N. and Senjanovic G., Phys. Rev. Lett., 44 (1980) 912. Cirigliano V., Kurylov A., Ramsey-Musolf M. J. and Vogel P., Phys. Rev. D, 70 (2004) 075007. Elliott S. R., Hahn A. A. and Moe M. K., Phys. Rev. Lett., 59 (1987) 2020. Klapdor-Kleingrothaus H. V. et al., Eur. Phys. J. A, 12 (2001) 147. Aalseth C. E. et al., Phys. Rev. D, 65 (2002) 092007. Arnaboldi C. et al., arXiv:0802.3439. Klapdor-Kleingrothaus H. V., Dietz A., Krivosheina I. V. and Chvorets O., Phys. Lett. B, 586 (2004) 198; Nucl. Instrum. Methods Phys. Res. A, 522 (2004) 371; Klapdor-Kleingrothaus H. V. and Krivosheina I. V., Mod. Phys. Lett. A, 21 (2006) 1547. Wycech S. and Sujkowski Z., Phys. Rev. C, 70 (2004) 052501. Bernabeu J., DeRujula A. and Jarlskog C., Nucl. Phys. B, 223 (1983) 15. Flack R. L., in Neutrino98 (www2.phys.cantebury.ac.nz/∼jaa53/presentations/ flack.pdf). Primakoff H. and Rosen S. P., Rep. Prog. Phys., 22 (1959) 121. Doi M. et al., Progr. Theor. Phys. Suppl., 83 (1985). Ericson T. and Weise W., Pions and Nuclei (Clarendon, Oxford) 1988, pp. 423-426. ˇ Rodin V. A., Faessler A., Simkovic F. and Vogel P., Nucl. Phys. A, 766 (2006) 107 and erratum; Nucl. Phys. A, 793 (2007) 213; arXiv:0706.4304. Nowacki F., talk at the IDEA meeting, Heidelberg, Oct. 2004. Retamosa J., Caurier E. and Nowacki F., Phys. Rev. C, 51 (1995) 371. Caurier E., Nowacki F., Poves A. and Retamosa J., Phys. Rev. Lett., 77 (1996) 1954. Caurier E., Nowacki F., Poves A. and Retamosa J., Nucl. Phys. A, 654 (1999) 973c. Caurier E., Martinez-Pinedo G., Nowacki F., Poves A. and Zuker A., Rev. Mod. Phys., 77 (2005) 427. Caurier E., Menendez J., Nowacki F. and Poves A., Phys. Rev. Lett., 100 (2008) 052503; arXiv:0708.2137. Caurier E., Nowacki F. and Poves A., arXiv:0708.0277. Menendez J., Poves A., Caurier E. and Nowacki F., arXiv:0801.3760. Halbleib J. A. and Sorensen R. A., Nucl. Phys. A, 98 (1967) 542. Cha D., Phys. Rev. C, 27 (1983) 2269. ˇ Simkovic F., Faessler A., Rodin V. A. and Vogel P., Phys. Rev. C, 77 (2008) 045503. Toivanen J. and Suhonen J., Phys. Rev. Lett., 75 (1995) 410. Vogel P. and Zirnbauer M. R., Phys. Rev. Lett., 57 (1986) 3148. Suhonen J., Phys. Lett. B, 607 (2005) 87. Griffiths A. and Vogel P., Phys. Rev. C, 46 (1992) 181. ˇ Rodin V. A., Faessler A., Simkovic F. and Vogel P., Phys. Rev. C, 68 (2003) 044302. Bahcall J. N., Murayama H. and Pena-Garay C., Phys. Rev. D, 70 (2004) 033012. Miller G. A. and Spencer J. E., Ann. Phys., 100 (1976) 562.

[41] [42] [43] [44] [45] [46] [47] [48]

[49] [50] [51] [52] [53] [54] [55] [56] [57] [58] [59] [60] [61] [62] [63] [64] [65] [66] [67] [68] [69] [70] [71] [72] [73]

Nuclear physics aspects of double-beta decay

103

[74] Fabrocini A., de Saavedra F. A. and Co’ G., Phys. Rev. C, 61 (2000) 044302; Co’ G., private communication. [75] Feldmeier H., Neff T., Roth R. and Schnack J., Nucl. Phys. A, 632 (1998) 61. [76] Kortelainen M. and Suhonen J., Phys. Rev. C, 75 (2007) 051303; Phys. Rev. C, 76 (2007) 024315; Kortelainen M., Civitarese O., Suhonen J. and Toivanen J., Phys. Lett. B, 647 (2007) 128. ˇ ¨ ssler A., Phys. Rev. C, 60 (1999) [77] Simkovic F., Pantis G., Vergados J. D. and Fa 055502. [78] Marciano W. J. and Sanda A. I., Phys. Lett. B, 67 (1977) 303; Lee B. W. and Shrock R. E., Phys. Rev. D, 16 (1977) 1444; Fujikawa K. and Shrock R. E., Phys. Rev. Lett., 45 (1980) 963. [79] Voloshin M. B., Vysotskij M. I. and Okun L. B., Sov. J. Nucl. Phys., 44 (1986) 440. [80] Voloshin M. B., Sov. J. Nucl. Phys., 48 (1988) 512. For a specific implementation see Barbieri R. and Mohapatra R. N., Phys. Lett. B, 218 (1989) 225. [81] Georgi H. and Randall L., Phys. Lett. B, 244 (1990) 196. [82] Grimus W. and Neufeld H., Nucl. Phys. B, 351 (1991) 115. [83] Babu K. S. and Mohapatra R. N., Phys. Rev. Lett., 64 (1990) 1705. [84] Bell N. F. et al., Phys. Rev. Lett., 95 (2005) 151802. [85] Davidson S., Gorbahn and Santamaria A., Phys. Lett. B, 626 (2005) 151. [86] Bell N. F. et al., Phys. Lett. B, 642 (2006) 377; hep-ph/0606248.

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-105

The mass of the particles A. Bettini(∗ ) Dipartimento di Fisica “G. Galilei”, Universit` a di Padova and INFN Via Marzolo 8 - 35131 Padova, Italy Laboratorio Subterr´ aneo de Canfranc, Canfranc (Huesca), Spain

Summary. — This lecture is meant to be complementary to those dedicated to the main subject of the Course, namely neutrinos, their masses and the corresponding measurements. We shall discuss the concept of mass at an elementary, but not trivial, level. From an operational point of view, mass, as any observable, is defined by the set of operations employed to measure it or, when not observable as in the case of quarks, to calculate it. Consequently, there are several “masses”, which are not necessarily equal. We shall discuss the relationships amongst them. We start by recalling the basic concept of mass and the strictly related ones of energy and momentum. We shall give then a historical perspective and draw the attention on a number of wrong concepts that are still present. Without considering neutrino masses, covered by other lectures, we shall discuss the masses of the neutrally charged flavoured mesons, the masses of the hadrons, the quark masses and their running.

1. – Basic concepts: energy, momentum, mass The energy E and the momentum p of a free system are conserved, i.e. commute with the Hamiltonian. This is true not only for elementary bodies, such as electrons (∗ ) E-mail: [email protected] c Societ`  a Italiana di Fisica

105

106

A. Bettini

and neutrinos, but also for composite systems, such as atoms, nuclei or hadrons. The energy and the three components of the momentum form together a four-vector. Its norm, as for any four-vectors, is Lorentz invariant. Indeed it is a very important one, namely the square of the mass of the system multiplied by the invariant of the Lorentz transformations c2 (1)

m2 c4 = E 2 − p2 c2 .

This is a fundamental expression: it is the definition of the mass. The expression is completely general, valid both for point-like and for composite bodies, even in the presence of internal forces. However, as already said, the concept of mass applies rigorously only to the stationary states, i.e. to the eigenstates of the free Hamiltonian, just as only monochromatic waves have a well-defined frequency. Even the barely more complicated wave, the dichromatic wave, does not have a well-defined frequency. There are particles, which are two-state quantum systems, such as K 0 and B 0 , or three-state systems as neutrinos, which are naturally produced in states different from stationary states. For the former states it is not proper to speak of mass and of lifetime, as we shall discuss. The second fundamental relationship between energy and momentum is (2)

p=

E v, c2

which is valid both for massless and massive bodies. If m = 0, the energy can be written as (3)

E = mγc2 ,

where γ is the Lorentz factor, and the expression of the momentum takes the equivalent form (4)

p = mγv.

The experimental determination of the mass of an elementary particle can be done on the basis of eq. (1) or of eq. (4). In the first case one measures its momentum, by measuring the curvature of its trajectory in a magnetic field or its multiple scattering in a detector, and its energy, for example with a calorimeter. In the second case we must measure momentum and velocity, the latter, e.g., by measuring the time of flight on a given basis. In any case, these measurements require that the lifetime of the particle be long enough to let it travel over macroscopic distances. This is the case of weakly decaying particles, not of the strongly decaying ones. For particles moving at speeds much smaller than c under the action of the force F, the law of motion, the Newton law, is (5)

F=

dp , dt

107

The mass of the particles

which, can be written in the equivalent form (6)

F = ma. Notice that:

a) from the historical point of view, Newton always used the law of motion in the form (5); b) the two expressions are equivalent only if υ c: at speed close to that of light only eq. (5) is valid; c) since we have assumed υ = c, we have assumed m = 0 implicitly. Let us now find the explicit expression of the “relativistic” law of motion. We have to take the time derivative of eq. (4). As it contains two factors varying with time, the velocity and the Lorentz factor, the result is the sum of two terms (7)

F = mγa + mγ 3 (a · β)β.

We see that the two terms are one parallel to the acceleration and one parallel to the velocity. Therefore, we cannot define any “mass” as the ratio between acceleration and force. At high speeds, the mass is not the inertia to motion. The limit for υ c of eq. (7) is eq. (6) with exactly the same value for m. There is no “relativistic” mass, there is only one mass, the mass of Galileo and Newton. Observe, but it is not much more than a curiosity, that force and acceleration are parallel (only) in two cases: if the force is perpendicular to the velocity, say (8)

FT = mγa

and if it is parallel to the velocity (9)

FL = mγa + mγ 3 β 2 a = mγ 3 a.

Notice that the two proportionality constants are different. None of them has any deep physical meaning, however at the beginning of the past century, as we will see in the next section, they even received names: transverse and longitudinal mass, respectively. In Newtonian mechanics mass is not only the inertia to motion (inertial mass), but also the source and the receptor of the gravitational force (gravitational mass). However, not only the first property but also the second one is not true at speeds comparable with c or in a gravitational potential comparable with c2 . One might naively think the source and receptor of the gravitational field to be mγ or, equivalently, E/c2 , but this is not true. The source and receptor of gravity in general relativity is the energy-momentum tensor.

108

A. Bettini

Consider a body of small, or zero, mass m and energy E, near a celestial body of large mass M , for example a proton or a photon near the Sun. A simple expression of the force acting on it was given by L. B. Okun [1] (10)

Fg = −

  GM cE2   r 1 + β 2 − β(β · r) , r3

where r is the radius vector from the centre of the Sun. For υ c (hence m = 0) the expression becomes (11)

Fg = −

GM m r, r3

which is the Newton expression. Notice that the gravitational force has two terms, one in the direction of the Sun and one parallel to the velocity. In two particular cases the force is parallel to the radius: when the particle moves in the radial direction (12)

  GM cE2 Fg = − r r3

and when its moves tangentially (velocity perpendicular to the radius) (13)

  GM 2 cE2 r. Fg = − r3

One sees that the quantity that takes the place of m in the Newton force is different, E/c2 in the first case, 2E/c2 in the second. Consequently, it is not possible to define a relativistic “gravitational” mass. Differently from the common belief, the deflection of light rays grazing the Sun is already a prediction of Newtonian mechanics. In fact Newton was thinking that light particles had a mass. Consequently they feel the gravitational force. However, the general relativity foresees a deflection angle twice as big as the Newtonian one, as a consequence of the force in eq. (13) being twice that of eq. (12). 2. – Wrong and confused concepts of energy, momentum and mass The basic relativistic concepts recalled in the previous section are very simple indeed. Historically, the development of relativity theory was a long process lasting more than a quarter of a century between the end of the 19th century and the beginning of the 20th, with contributions of several physicists, both theorists and experimentalists. We just recall Michelson, Lorentz, Poincar´e, Einstein and Planck. In the initial phases of the process, preliminary ideas were set forward and provisional concepts were developed. Part of them —specifically on energy, momentum and mass— were unfocussed or simply wrong. The appearance of confused elements in the early

The mass of the particles

109

stages of a theory is rather common, but usually they soon disappear. However, in the case of relativity wrong and confused concepts still remain after more than a century, used even by physicists, especially in textbooks, and, even more, when communicating to the general public. The most conspicuous example is the “Famous Einstein Equation” E = mc2 , which is obviously wrong (for bodies not at rest). We owe it to L. B. Okun to having attracted the attention of the community on this situation. Almost twenty years ago he wrote [1]: Every year millions of boys and girls are taught special relativity in such a way that they miss the essence of the subject. Archaic and confusing notions are hammered into their heads. It is our duty —the duty of professional physicists— to stop this process. More recently Okun [2] published a comprehensive study of the argument titled The Einstein formula E0 = mc2 . Isn’t the Lord laughing? We shall recall here and in the next section only the most relevant historical elements. The most important contributions to the final phases of the development of relativity were given by Lorentz, Poincar´e, Einstein and Planck between 1904 and 1906, reaching the apex in 1905. Let us see in detail. On the 5th of June, H. Poincar´e presents the memoir Sur la dynamique de l’´ electron at the Acad´emie de Science in Paris, which is immediately printed [3] and distributed to the community. An extended version of the work, which however contained already all the basic elements, is sent by Poincar´e to the “Circolo Matematico di Palermo” on the 23rd of July. The publication process is long and the paper circulates only in 1906 [4]. This work not only contains the complete relativistic kinematics, but also the correct formulation of the relativistic dynamics. Poincar´ e, as everybody else at those times, considers the electron as a charged sphere, small but finite. Assuming its mass being of electromagnetic origin, he finds that the “relativistic” equation of motion is the Newton equation, namely the time derivative of momentum is equal to the force, eq. (5), and then writes eq. (7). To be precise, in retrospect, Poincar´e obtains this result using, as we shall see in the next section, a non-covariant definition of the field momentum. However, Poincar´e immediately demonstrates a very important theorem: the only relationship between force and acceleration compatible with the relativity principle (Poincar´e himself had christened the law in such a way in 1904 [5]) is eq. (7). Twenty five days after the Poincar´e memoir and twenty three before the completion of its extended version, Einstein completes Zur Elektrodynamik bewegter K¨ orper [6]. It is his famous first work on relativity containing the complete formulation of the relativistic kinematics, as in Poincar´e, but free of a couple of archaic concepts which were still present in Poincar´e. The ether is declared “superfluous” and the Lorentz contraction is shown to be purely kinematic. Our main interest here is on the relationship between force and acceleration. Unfortunately, Einstein starts from the equation of motion in the form (6), instead of the Newton expression (5), and tries to generalize it. Moreover, his arguments are logically inconsistent, leading to a wrong, non-covariant, equation. As everybody else at that time, Einstein still employs the wrong concepts, introduced by Abraham, of “transverse

110

A. Bettini

mass” and “longitudinal mass”. Moreover, his expression of transverse mass is wrong, mγ 2 instead of mγ. The most important issue here is that Einstein considers the mass as the inertia to motion. His second work on relativity of 1905 is titled Does the inertia to motion of a body depend on its energy content? [7], where “inertia to motion” is the mass. He will never abandon this idea. The final demonstration of the relativistic equation of motion was given in 1906 by Planck [8]. As noticed by Okun [2], the fundamental eq. (1), surprisingly enough, was formulated only, in print, in 1941, in the famous Landau and Lifschitz Teroia polia (Theory of fields) [9], and only ten years later these beautiful lectures appeared in English [10]. Let us conclude this section with the following summary: – Mass is a Lorentz-scalar quantity. It is an invariant, it does not depend on velocity. – Energy is conserved, mass not always. – The mass of a system is not the sum of the masses of its constituents (even if they do not interact). – The still used concept of “relativistic mass”, namely mγ, which increases with velocity, is wrong. It is the energy divided by c2 , namely the fourth component of a four-vector. The concept of “rest mass” is wrong too, it is simply the mass. Other wrong concepts, which fortunately are not used any more, are the transverse and longitudinal masses. – Mass and energy are not equivalent: it is true that any system with mass has energy even at rest (the rest energy), but the opposite is not true: there are systems, such as a photon, which have energy and no mass. – The equation E = mc2 is wrong, the correct equation is E0 = mc2 , where E0 is the rest energy. As already mentioned, some of these elementary statements are often forgotten even by professional physicists, especially when teaching at high school or undergraduate levels or, even more often, when writing and talking to the general public. Even two of the greatest physicists of the 19th century, Feynman and Landau, the authors of the most magnificent textbooks in physics, did not escape this fate, respectively in the Lectures on Physics (Chapters 15 and 16) [11] and in What is relativity? [12]. 3. – Energy, momentum and mass of the electromagnetic field The concepts of energy and momentum of the electromagnetic field developed in parallel with “relativity” between the end of the 19th and the beginning of 20th centuries. However, they are still object of debate. A further issue is the “electromagnetic mass”,

111

The mass of the particles

namely the contribution to mass of the field energy. We shall use the symbol U for energy in this section, to avoid confusion with the electric field. As it is well known now, the energy density and the momentum density of the electromagnetic field form a four-momentum (14)

w=

 ε0  2 E + c2 B 2 , 2

g = ε0 E × B.

In 1900 Poincar´e [13] proposed the following expressions for the field total energymomentum. We are using here a modern language. The Lorentz group and the fourvectors were introduced by Poincar´e only five years later [3, 4]. (15)

A UEM =

ε0 2





 E 2 + c2 B 2 dV,

V

 PA EM = ε0

E × BdV. V

The proposal was universally accepted, in particular by Abraham [14] (and eqs. (15) are often called after him, hence the apex “A”) and by Lorentz [15]. This is a bad definition, because energy-momentum should be a four-vector and eq. (14) is not, because its components are obtained by multiplying the components of a four-vector by dV that is not a four-scalar. This consideration seems obvious, but historically it was not. The non-covariant expressions have been widely used till the present times causing several problems of understanding. This interesting history is narrated, in particular, by Rohrlich [16]. We shall limit ourselves to a few important examples here. To the knowledge of the author, the first historical hint on a possible correlation between mass and energy is due to J. J. Thomson and is dated 1881. We shall not follow literarily his calculations, performed when the use of the Maxwell theory, published in 1865, was still under development and that were not completely correct. Rather, we shall discuss the issue in modern language [17]. Consider a rigid sphere of radius a, with a uniform surface charge qe at rest in the origin of the axes of the reference frame Σ0 . In this frame the magnetic field is zero and, outside the sphere, the electric field is the field of a point charge in the origin. The corresponding (electric) energy is (16)

Uel0

qe2 = 32π 2 ε0

 a

∞

1 qe2 1 1 2 , 4πr dr = r4 2 4π 2 ε0 a

where the apex “0” is to remind that it is rest energy. In his work, Thomson starts directly considering the charged sphere moving with uniform velocity v (much smaller than c), say, in the frame Σ. The electric field, and consequently the electric energy, are substantially the same as in Σ0 . However there is now also a magnetic field, given by the Biot-Savart law, namely (17)

B(r) =

1 v × B, c2

B(r) =

qe υ sin θ , 4πε0 c2 r2

r > a,

112

A. Bettini

where θ is the angle between the radius vector r and the velocity v. Integrating on the volume, an exercise for the reader, we obtain the contribution to energy of the magnetic field (18)

Umag

1 = 2



2 qe2 1 3 4πε0 c2 a

 υ2 .

We see that the additional field energy, when the electron is in motion, is proportional to the square of its speed and the proportionality constant, the quantity in parenthesis, depends only on electron properties, its charge and its radius. We can conclude that eq. (18) gives the additional “kinetic energy due to electrification”. The effect of electrification, concludes Thomson, “is the same as if the mass of the sphere were increased by” (19)

mTh EM =

2 qe2 1 , 3 4πε0 c2 a

where we introduced the apex “Th” for Thomson. Thomson did not take the last step, which is however a logical consequence of his argument. Indeed, by comparing eq. (19) with eq. (16), we see that the following relation holds between “electromagnetic” mass and rest energy: 2 mTh EM c =

(20)

4 0 U . 3 EM

But why does the surprising factor 4/3 appear? The same factor appears also if one tries to obtain an expression of the electromagnetic mass from the electromagnetic momentum defined by eq. (15), as done for example by Feynman in his Lectures on Physics (Volume II, Chapter 28). With reference to fig. 1, the momentum density of the field of a spherical positive charge in the origin is (21)

g = ε0 E × B,

g=

ε0 υ 2 E sin θ c2

and, using for the magnetic field eq. (17),  (22)

pA EM = ε0

E × BdV = V

2 qe2 1 v. 3 4πε0 c2 a

We see that the electromagnetic momentum is proportional to the velocity and that the proportionality constant depends only on the charge and radius of the sphere. If we identify this constant with the mass, we have (23)

2 mA EM c =

4 0 2 qe2 1 = UEM , 3 4πε0 a 3

113

The mass of the particles

y E

B + + + + + + +

r

g v

x

Fig. 1. – Scheme of the fields of a spherical charge in motion.

where the apex “A” reminds that this expression of mass has been obtained from the “Abraham” momentum. Again the factor 4/3 appears! One might think that the origin of the problem is that we have not used the correct relativistic expressions of the fields, namely those valid also at high speeds. However a complete calculation gives (24)

pA EM =

2 qe2 1 γv, 3 4πε0 c2 a

leading once more to eq. (23). The reason of the problem is the use of the non-covariant expressions (15). Surprisingly enough, this simple consideration escaped to Feynman himself! It did not escape, however, to the young Fermi, who published in 1922 an article entitled On a conflict between elctrodynamic and relativistic theories of the electromagnetic mass [18]. Fermi starts with the statements: As it is known, simple electrodynamic arguments lead to the value (4/3)U/c2 for the electromagnetic mass of a spherical system containing the energy U. . . (Fermi quotes Abraham). On the other hand it is well known that simple relativistic considerations lead to the value U/c2 for the mass of a system containing the energy U. Consequently, we are confronted by a conflict between two different conceptions. It looks to me not to be without interest to clarify such a conflict, especially if one takes into account the enormous importance for physics of the concept of electromagnetic mass. In this beautiful work Fermi shows that the problem is due to the fact, as we have said, that eq. (15) are not Lorentz-invariant. The problem is solved considering the total energy momentum, which is the sum of the electromagnetic and mechanical ones. It has nothing to do with the problem of the stability of the electron. However, the paper went largely unnoticed, and the problem remained in the community. It was solved again with the same solution and again not being noticed by B. Kwal [19] in 1949. Finally it was brought to the general attention by Rohrlich [16]. Following Rohrlich [16], the correct covariant definition is given in terms of the energymomentum tensor Tij of the electromagnetic field (25)

Pi ≡ −

i c

 S3

Tji d3 Sj ,

114

A. Bettini

where S 3 is a space-type hyperplane. The expression is covariant at sight. We remind the reader that electromagnetic energy-momentum tensor (in vacuum) is given by

(26)

T = ε0

 −Eα Eβ −c2 Bα Bβ + 12 δαβ (E 2 +c2 B 2 ) icE × B

icE × B − 12 (E 2 +c2 B 2 )

 ,

α, β = 1, 2, 3.

It can be shown that the covariant definition leads to eq. (15) only if ∂j Tji = 0,

(27)

namely if the electromagnetic energy and momentum are conserved, i.e. if the electromagnetic field does not exchange energy with matter. A system of charges for which a reference frame exists in which the magnetic field is zero everywhere is called electrostatic. Such is our spherical charge of radius a. For such systems eq. (25) becomes [16]  

(28)

  1 2 E + c2 B 2 − v · E × B dV, 2    2  γ β 2 cE × B + (β · E)E + c2 (β · B)B − ε0 E + c2 B 2 dV. = c 2

UEM = γ 2 ε0 PEM

According to eq. (1) the mass of the system is ) (29)

mEM =

2 2 PEM UEM − . c4 c2

Considering that it is an invariant quantity, we can express it in the rest frame, in which both velocity and magnetic field are zero, obtaining mEM =

(30)

0 UEM ε0 = 2 c2 2c

 E 2 dV. V

The mass is the rest energy divided by c2 . At small, but non-zero speeds, υ c eqs. (28) become (31)

UEM

ε0 = 2

PEM = ε0





 E 2 + c2 B 2 dV,

 

 1 E2 E × B + 2 (v · E)E − 2 v dV. c 2c

Notice that the expression of energy is the same as in eq. (15), but that of momentum is not, it contains two more terms! The correct field momentum is given by the sum of

115

The mass of the particles

the three following integrals (the first of which is the only one considered by Feynman):  E × BdV = 2π

ε0 V



∞



π

E 2 r2 dr

0

0

4 sin3 θdθ = mEM υ , 3

  π ε0 υ ∞ 2 2 2 (v · E)EdV = 2π 2 E r dr cos θ sin θdθ = mEM υ , c 3 0 0 V  π    ∞ ε0 υ 1 ε0 E 2 vdV 2π 2 E 2 r2 dr − sin θdθ = mEM υ(−1), − 2 2c V c 2 0 0 ε0 c2



ε0 υ c2

and summing up  (32)

PEM =

 4 2 + − 1 mEM υ = mEM υ. 3 3

In conclusion, if we use he correct, covariant, expressions of the electromagnetic energy-momentum vector, the problem of the 4/3 factor disappears. In history, this problem became linked to the problems of the stability of the electron, of the self-energy of a point charge and the infinities in electrodynamics, from Poincar´ e up to Feynman in his lectures. But, as we have shown, it is just a matter of bad definitions. 4. – Waves, dispersion relation In quantum mechanics systems with well-defined momentum and energy are represented by plane monochromatic waves, with, say, wave vector k and angular frequency ω. Using the natural units, c = h ¯ = 1, the following fundamental relationships hold: (33)

p = k,

E = ω.

We remind the reader that ω is the variation of the phase of the wave function per unit time and k is its variation per unit length perpendicularly to the wave fronts. The vector k is perpendicular to the wave fronts. In general, the behaviour of the waves is governed by the dispersion relation, which is the functional dependence of k on ω. The dispersion relation for a free particle is a consequence of eqs. (1) and (33), (34)

k 2 = ω 2 − m2 .

Let us consider now a light wave, a beam of photons, in a dielectric transparent non-magnetic medium, such as glass or water. If the medium is also homogeneous and isotropic, as we assume, the sum of the incident wave and the waves scattered by the molecules of the medium has an appreciable amplitude only in the forward direction. The net effect is a wave propagating in the original direction with a phase velocity υφ = c/n, where n is the refraction index. Both are in general functions of the frequency, but, to make things a little simpler, we assume dispersion to be small and ignore it. The

116

A. Bettini

frequency of the wave in the medium is the same as in vacuum, but its wave number is different, k = nω. What is the momentum of the light wave in such a simple medium? What is the momentum of the photons? To answer to the first question we can use the macroscopic description of the Maxwell equation; to answer to the second we need to consider the quantum effects too. The macroscopic fields, are E, D, the electrical displacement, and B. H does not play a role in the present discussion because we have assumed the medium to be non-magnetic. Historically, one century ago, two different answers were given to this apparently simple question. In 1908 Hermann Minkowski [20] proposed the electromagnetic field momentum density gM = D × B and the filed momentum  (35a)

PM =

 gM dV =

D × BdV.

The momentum of an electromagnetic wave entering the dielectric decreases by a factor 1/n (in the usual case in which n > 1). One year later, Max Abraham [21] proposed the field momentum density gA = ε0 D × B and the field momentum   (36a) PA = gA dV = ε0 E × BdV, which implies that the momentum of the electromagnetic wave increases by n. Since then, the question of the “correct” form of an electromagnetic wave in a dielectric medium, the “Minkowski-Abraham controversy”, has been debated both theoretically and experimentally. A recent review article, published in 2007, by R. N. C. Pfeifer et al. [22] has contributed substantially to clarify the situation. Indeed, we immediately see that neither one equation nor the other defines three spatial components of a four-vector. Moreover, they correspond to two different definitions of the field energy-momentum tensor (see ref. [22] for their expressions). Both are perfectly legitimate only if one takes properly into account that the conserved quantity is the total energy-momentum tensor of the system. The latter is the sum of the electromagnetic energy-momentum and of the mechanical energy-momentum of the medium. The two definitions correspond to different, arbitrary, divisions of the two contributions, which are not separately conserved. Equation (27) is valid for the total energy-momentum tensor and not for the electromagnetic one and consequently eqs. (35a) and (35b) are not covariant definitions. The energy and momentum of the wave (of the photons) are determined by measuring the energy and momentum transferred to the apparatus. This measurement includes contributions both from the electromagnetic energy-momentum and the matter energy-momentum. This fact should be taken into account explicitly in the analysis of the experimental results. Historically, as recalled by Pfeifer et al. [22], neither the Minkowski nor the Abraham momentum were proposed by their “fathers” in association

117

The mass of the particles

with the corresponding matter momenta. The Abraham momentum acquired its matter counterpart only in 1954 [23] and the Minkowski one even later, in the 1970s [24]. Both the Abraham and the Minkowski momentum give a correct description, provided that the matter counterparts are properly considered, which is not always the case in the literature. As noticed by Pfeifer et al. [22] “awareness of the resolution of the original controversy remains patchy.” It is important to notice that it is not possible to write down an expression of the matter energy-momentum tensor valid in every circumstance. The reason is that such an expression should summarise macroscopically the behaviour of the material, namely of an extremely complicated situation, including effects such as the mechanical fluid flows, the mechanical stress, the electrostriction and the magnetostriction. This can be done only within a certain approximation, which can be different in different physical circumstances. We try now to answer to the second question, namely whether we can define an effective photon momentum in the medium. The question has been addressed by Garrison and Chiao [25]. Their discussion properly includes dispersion and the difference between phase and group velocities, but we stick here for simplicity to the non-dispersive example. In this case, the Minkowski macroscopic momentum corresponds to an effective photon momentum equal to the wave vector (¯ h = 1). Then we have (remember that also c = 1) (35b)

pM = nω.

The Abraham choice leads to pA = ω/n.

(36b)

Let us now consider, as an example, the important and (apparently) conceptually simple experiment done in 1978 by R. V. Jones and B. Leslie [26]. They measured with 0.05% accuracy the radiation pressure of a HeNe LASER with a power PL = 15 mW on a highly reflective (multilayer) mirror immersed in several dielectric liquids and compared with the pressure in air. We call dNinc /dt the incident photon flux and ωL the frequency of the LASER. Taking (naively) the Minkowski eqs. (35), the radiation pressure should be PL dNinc 2p = 2nωL = 2PL n dt ωL

Frad (liquid) =

and the ratio of the pressure on the mirror in the liquid and in air R≡

Frad (liquid) = n. Frad (air)

Similarly, taking the Abraham eqs. (36), we have R≡

Frad (liquid) = 1/n. Frad (air)

118

A. Bettini

One of the measured liquids is benzene, for which with the known value of the refraction index, one predicts (taking into account a small (≈ 3%) effect due to dispersion [25]) Rth = 1.4974. The measured ratio is Rexp = 1.4970 ± 0.0021. If the correct expression were that of Abraham, the expected value should have been RA = 0.6475. For methanol the expected values are 1.3275 for Minkowski and 0.7435 for Abraham against the measured value 1.3281 ± 0.0018 and similarly for several other liquids. The conclusions seems to be that the correct expression is the Minkowski momentum and that Abraham is wrong. However, as it should be clear from the previous discussion, this conclusion is not correct. Indeed, a proper analysis must include the contribution of the matter part of the energy-momentum tensor in both cases. As shown for example by Pfeifer et al. [22], the counterpart of the Minkowski momentum gives only a rather small contribution, namely the above-mentioned small effect due to dispersion. On the contrary, the contribution of the matter energy-momentum in the case of Abraham is important. In the simplified case of no dispersion this mechanical component turns out to be nω(1 − 1/n2 ), which added to eq. (36b) gives back eq. (35b). Let us now consider another question: is it possible or useful to define a photon “effective” mass in a transparent dielectric medium? We restrict to a low-pressure gas to minimize the problems we have just discussed. To be rigorous, mass is a property of free particles. Photons in a medium, when travelling between molecules, are free particles in a vacuum, with zero mass. Naively, one might think also to assign them an effective mass squared using eq. (34), i.e. m2 = ω 2 − k 2 = (1 − n2 )ω 2 , which in the usual case of n > 1 would be negative! This absurd conclusion is wrong for the obvious reason that in general the dispersion relation for light in a medium is not eq. (34). An expression which is good enough for our discussion is the following: (37)

n2 ≡

 1 k2 fj = 2 = 1 + ωp2 2 2 − ω 2 + iγ ω , βph ω ω j j j

where ωj and γj are the resonance frequencies and widths of the medium and fj the  so-called “oscillator amplitudes”, with fj = 1. The plasma frequency ωp is given by (38)

ωp2 =

Ne qe2 , ε 0 me

where Ne is the number of electrons (both bound and free) per cubic metre. Equation (37) is very different indeed from (34), consequently the concept of effective mass of photons at visible frequencies in a medium is not useful. However, consider that the resonance frequencies are usually not larger than the near UV. If the frequency of the photon is large enough, far UV or X-rays, the dispersion relation (37) becomes (39)

k2 = ω 2 − ωp2 ,

119

The mass of the particles

γ

a γ

γ

a γ

Ze

Ze a)

b)

Fig. 2. – Primakoff diagrams. a) Production of axion, b) detection of axion in a magnetic field.

which is eq. (34). Photons with a frequency much higher than the resonance frequencies of the medium have an effective mass that is the plasma frequency of the medium. This may be the case, for example, of photons propagating in the interstellar medium. Consider now high frequency photons propagating in a gas. We have the opportunity to change their effective mass, by varying the density of the gas. This is done, for example, in the CAST experiment searching for axion particles. Axions, which we indicate with the symbol a, are hypothetical scalar particles, which have been introduced by Peccei and Quin [27] on theoretical grounds in relation to the strong CP -violation suppression. If they exist, they should be produced, in particular, in the Sun via the Primakoff [28] diagram shown in fig. 2a). Their energies should be in the several keV range. Neither the coupling constant gaγ nor the axion mass ma are predicted by theory. In a transverse magnetic field BT axions convert into photons (X-ray), which can be detected [29], again via Primakoff effect with the diagram of fig. 2b). This “oscillation” can happen even if the spin and parities are different due to the presence of B. The 2 2 conversion efficiency is proportional to BT L , hence intense magnetic fields and long field lengths must be used. The CAST [30] experiment at CERN uses a LHC prototype dipole having B = 9 T on a length L = 9.26 m. It has been mounted on a platform, which can move ±8◦ vertically, pointing at the Sun at sunrise and sunset, and ±40◦ horizontally, in order to see the Sun all the year. The apparatus is hosted in a hall, and can see the axion-Sun through the walls, which are transparent to axions. Background data are collected when Sun is not in view. X-rays produced by the axions in the magnet are focussed at its end and detected by CCD cameras combined with MICROMEGAS and a TPC. Figure 3 shows the present limits reached by CAST together with theoretical expectations. To be sensitive to smaller axion masses, the magnet will be filled with a buffer gas (4 He and 3 He) and the search will be repeated, at variable gas pressure. The reason can be understood with the help of fig. 4, which shows the photon effective squared mass, i.e. the plasma frequency squared, eq. (38), as a function of the electron density, which is proportional to the gas pressure. If the axion mass is in the useful range, a level crossing is present. At the corresponding electron density (gas pressure) the axion mass and the photon effective mass are equal and the conversion probability becomes very large [31].

120

A. Bettini

Fig. 3. – Exclusion limit (95% CL) from the CAST 2003. The shaded band represents typical theoretical models. Also shown is the future CAST sensitivity.

The phenomenon is similar to the MSW [32] effect for neutrinos propagating in matter. Figure 3 shows the expected sensitivity, which will be reached by varying the pressure of the buffer gas between 0 and 60 mbar at T = 1.8 K. 5. – The masses of the flavoured neutral mesons The flavoured, electrically neutral, meson-antimeson pairs are beautiful examples of two-state quantum systems. Their experimental and theoretical study is fundamental for different chapters of particle physics, including oscillation phenomena, CP -violation and tests of the conservation rules.

m2 ton

o ph

m2a

axion

Ne Fig. 4. – Squared axion photon effective mass as a function of the electron density.

121

The mass of the particles

Since the top quark does not bind inside hadrons, there are four such meson doublets, the K 0 s, the D0 s, the B 0 s and the Bs0 s. In each case, the states with definite flavour differ from the stationary states. Consequently, a system which is originally in a state of definite flavour oscillates to the state of opposite flavour and back in its time evolution. This “flavour oscillation” has been observed in all the doublets, in historical order, in the K 0 s, in the B 0 s, in the Bs0 s and in the D0 s. ¯ 0 the generic meson and antimeson states as produced Let us denote with M 0 and M by the strong interactions, i.e. with definite flavour. The stationary states can be written, assuming CP T conservation as (40)

 0*  * ¯ , |ML  = p M 0 + q M  0*  0* ¯ , |MH  = p M − q M

p and q are two complex numbers that satisfy the normalisation condition (41)

|p| + |q| = 1.

Since an overall phase is unphysical, there are two real parameters. In eq. (40) the two eigenstates are labelled as L and H, corresponding to the lighter (meaning with smaller mass) and heavier one. In the case of the K 0 the eigenstates are chosen as those of shorter (Ks ) and longer (KL ) lifetime, respectively. The masses of the two stationary states (mKS and mKL , mBH and mBL , etc.) of each pair are in any case very close to one another, but are not identical. The differences are so small that cannot be appreciated by measuring the two masses. Rather, their absolute values are determined by measuring the oscillation periods, while the measurement of the sign requires an interference phenomenon. The lifetimes, or widths, of the two stationary states of the pair are different too. This difference is very large in the case of K 0 , rather small in the other cases. The most stringent tests of the CP T symmetry are based on the search of a difference between the masses, or the widths, of a particle and of its antiparticle. In particular, one can extract from the measured values of the CP -violation parameters in the K 0 system 0 the limit on the “mass” difference between K 0 and K [33] (42)

mK 0 − mK¯ 0 ≤ 10−18 maverage

at 95% C.L.

In the statement we just made, and which is usually done in such a way, one speaks of the mass of a system which is not in a stationary state. The PDG [33] goes further and gives a value of the K 0 “mass”. Let us see what it is meant. Consider an arbitrary 0 linear combination of K 0 and K , (43)

 +  *  0 |ψ(t) = a K 0 + b K .

122

A. Bettini

Its time evolution is given by the Shroedinger equation, which can be written d i dt

(44)

       Γ a a a = M −i =H , b b b 2

where M and Γ are Hermitian matrices. M and Γ are diagonal in the KS KL base not in the flavour base, which are now considering. 

M11 M21

M≡

(45)

 M12 , M22

 Γ11 Γ≡ Γ21

 Γ12 . Γ22

In the flavour base, however, the diagonal elements of both M and Γ are equal if either CP or CP T are conserved. The diagonal elements of M are the quantities that are improperly called “masses”. Since CP is not conserved by the weak interactions, the equalities (46)

M11 = M22



 mK 0 = mK 0 ,

Γ11 = Γ22



ΓK 0 = ΓK 0



are tests of CP T . 6. – Neutrinos The fascinating subject of neutrino masses and mixing and of their measurements is the subject of the lectures of the present Course. Consequently, I shall limit myself to an exercise meant to elucidate the difference between flavour states and mass eigenstates. In the previous section we considered the two-state systems made by the flavoured neutrally charged meson-antimeson pairs. Strong interactions produce the system in a state of definite flavour, a meson or an anti-meson, which does not have definite mass and lifetime. Rather it is a superposition of the two states of definite mass and lifetime. Since the mesons decay via weak interactions, they can evolve on times much longer than those characteristic of strong interactions. The evolution of the system is an oscillation between the two states of opposite flavour, with a period inversely proportional to the mass difference. The oscillation amplitude decays as a combination of exponentials, because the mesons are unstable. The case of neutrinos is similar, but with important differences: – There are three lepton flavours, defined as the flavours of the charged leptons, the electron, the mu and the tau. They are distinguished by their masses, which are measured on macroscopic distances due to the long lifetimes. Consequently, charged leptons are both mass and flavour eigenstates. There is no mixing. Three neutrinos exist, one for each flavour, νe , νμ and ντ together with their antiparticles. – There are three stationary states of neutrinos, which are superpositions of the flavour neutrino states and three antineutrino stationary states, superpositions of the flavour antineutrino states. The two sets are correlated by the CP T invariance.

123

The mass of the particles

– Neutrinos are stable, hence the oscillation amplitude does not decay in time. The definite flavour states are obtained from the stationary states ν1 , ν2 and ν3 with a transformation, which we assume to be unitary. The transformation is ⎛

⎞ ⎛ Ue1 νe ⎝νμ ⎠ = ⎝Uμ1 Uτ 1 ντ

(47)

Ue2 Uμ2 Uτ 2

⎞⎛ ⎞ ν1 Ue3 Uμ3 ⎠ ⎝ν2 ⎠ , ν3 Uτ 3

analogous to that of the quarks. The total number of independent real parameters in the mixing matrix depends on the nature of neutrinos. In the Standard Model neutrinos are assumed to be Dirac particles, without, however, any experimental verification. Consequently, the possibility that neutrinos are Majorana particles exists. In the latter case, neutrinos are antiparticles of themselves, or better, neutrino and antineutrino are two states of the same particle. For an example think to the photon with its two helicity states. It can be shown [34] that if neutrinos are Dirac particles, the independent mixing parameters are three rotation angles, θ12 , θ23 and θ13 and a phase factor, δ, and that, if they are Majorana particles, there are two more phases, φ1 and φ2 . The latter are irrelevant for oscillations and are observable, in practice, only in the neutrino-less doublebeta decay. Writing cij = cos θij , and sij = sin θij , the transformation matrix is

(48)

⎞⎛ ⎞⎛ ⎞⎛ ⎛ ⎞ 1 0 0 0 s13 e−iδ c13 c12 −s12 0 1 0 0 U = ⎝0 c23 s23 ⎠ ⎝ 0 1 0 ⎠ ⎝s12 c12 0⎠ ⎝0 eiφ1 0 ⎠ . iδ −s13 e 0 0 0 1 0 0 eiφ2 0 −s23 c23 c13

There are overall nine quantities to be measured, three mixing angles, three phases and three masses, m1 , m2 and m3 , of ν1 , ν2 and ν3 . The three phases, if different from 0 and from π, give origin to CP -violating effects in the lepton sector. Notice that if neutrinos were two, one phase factor would still be present if they were Majorana particles, none if Dirac ones. The status and the perspectives have been reviewed by other lectures. For a recent overall fit of the data, see G. L. Fogli et al. [35]. Let us concentrate here on the question: what are the flavour states νe , νμ and ντ ? To be concrete, consider for example the muon-neutrino νμ . This state can be defined in different, but equivalent, ways: a) νμ is the neutrino that, by hitting a nucleus, produces the charged lepton μ− . For example (49)

νμ + N → μ− + hadrons.

b) νμ is the neutral particle produced by weak interactions together with μ+ . For example (50)

p + p¯ → μ+ + νμ + hadrons.

124

A. Bettini

As discussed by Giunti and Kim [36], however, these definitions would be completely equivalent if neutrino masses were zero and are so, to every practical purposes, only due to the smallness of neutrino masses (in comparison to the other particles). As an exercise, consider the decay of a meson M + into a μ+ M + → μ+ + νμ .

(51)

Suppose now we measure in the rest frame of the meson the energy spectrum of the muon. Suppose for simplicity that neutrinos were only two, νμ and ντ and that (52)

1 νμ = √ (ν2 + ν3 ) , 2

1 ντ = √ (ν2 − ν3 ) , 2

as almost true in reality. Since ν2 and ν3 have different masses, m2 and m3 , the muon spectrum will not be monochromatic, but rather di-chromatic with two peaks corresponding to the two masses. Consequently, we may think to prepare an experiment in which we have the neutrinos from the decay interacting with a nuclear target and detect the final charged lepton. We can “tag” each neutrino on the basis of the peak to which the energy of the associated muon belongs. In such a way we know if the neutrino is a ν2 or a ν3 . Taking for example the case 1 ν2 = √ (νμ + ντ ) , 2

(53)

the charged lepton we will observe will be a μ− 50% of the times and a τ − the other 50%. This conclusion looks absurd, because is a clear violation of the flavour lepton number. It is correct, however, but only if neutrinos are detected enough time after their production. Indeed, the experimental resolution must be enough to distinguish the two peaks in the muon spectrum, namely to appreciate the energy difference (54)

Eμ3 − Eμ2 =

Δm2 m23 − m22 = . 4Eμ 4Eμ

But this requires that the system, the neutrino, evolves for enough time, given by the energy-time uncertainty relation (55)

τ>

1 4Eμ 4Eν T , = ≈ = 2 2 Eμ3 − Eμ2 Δm Δm 2π

where we have assumed, for simplicity, the meson mass much larger then the muon mass. We see that T in the last member is just the oscillation period. Indeed, after a time of this order both μ’s and τ ’s are produced in the collision of an originally muon neutrino beam. To be sure, this theoretical prediction has not been directly verified yet, and is the programme of the OPERA experiment [37]. In order to understand better what flavour neutrinos are, suppose neutrino masses were similar to those of the charged leptons (some 10 orders of magnitudes larger than

125

The mass of the particles

their actual values), say m1 = 0.5 MeV, m2 = 100 MeV, m3 = 1800 MeV. Consider the two-body (μ2) decays of the pseudoscalar charged mesons, say (56a)

π − → μ− + νμπμ2 ,

(56b)

K − → μ− + νμKμ2 ,

(56c)

D− → μ− + νμDμ2 ,

(56d)

Ds− → μ− + νμDs μ2 ,

(56e)

B − → μ− + νμBμ2 .

Are the five “muon neutrinos”, which we have indicated with different symbols, the same particle? Find which of the eigenstates ν1 , ν2 and ν3 contribute to each of them. Give the conceptual expression of each “muon neutrino” as a superposition of the eigenstates. Calculate the decay probabilities. With the above given values of neutrino masses, we immediately see that νμπμ2 = ν1 . ν2 and ν3 do not contribute because they are below threshold. In such a world, pions would decay in neutrinos in a mass rather than flavour eigenstate. We further see that both νμKμ2 and νμDμ2 contain ν1 and ν2 , in different proportions, and that νμDs μ2 and νμBμ2 contain ν1 , ν2 and ν3 , in different proportions. Calling generically P the pseudoscalar meson, and with l = e, μ, τ , the “muon neutrinos” states in those decays are [36] (57)

3  +   P μ2 = MliP μ2 Uli |νi  , νl i=1

where MliP μ2 is the matrix element of the transition P − → μ− + νμP μ2 integrated over the phase space. MliP μ2 depends on neutrino masses. If all of them are zero, MliP μ2 = MlP . More generally, the neutrino state produced in a decay together with a certain charged lepton depends both on initial and final states of the decay. Analogously for the production of a charged lepton by a neutrino. In the real word, neutrino masses are so small that any difference is always irrelevant. We understand, however, that the concept of flavour-neutrinos is well defined as a consequence of the smallness of neutrino masses. We leave to the reader to calculate the decay probability as an exercise, giving only the result: ⎧ ⎪ 3 3 2 2 2 2  ⎨ 2 2 mP + m i − m μ 2 GF Γ= (mμ + mi ) (58) |V | |U | Γi = fP2 ud μi ⎪ 2πm2P 2 i=1 i=1 ⎩ ⎡ ⎤1/2 ⎫ 2 ⎪ ⎬ 2 2 mP − mμ 2⎦ ⎣ × − mi , ⎪ 2mP ⎭ where fP is the decay constant of P .

126

A. Bettini

7. – The mass of strongly decaying hadrons The largest fraction of the hadrons decay via strong interactions. The time evolution of these states can be observed over durations typically between 10−24 s and 10−22 s. An important consequence of the shortness of the possible observation times is that the concepts of mass and lifetime, or width, of these states can be defined only with a limited accuracy. As it is well known, these hadrons can be observed in two basic ways: in formation experiments or in production experiments. In both cases there is a “resonance”, corresponding to a pole in the relevant scattering amplitude. The pole is located below the real axis in the centre-of-mass energy plane. The mass of the state is defined to be the real part the pole, its width as the opposite of the imaginary part. The accuracy of this definition decreases with increasing distance of the pole from the real axis, namely with increasing width, and with increasing inelasticity of the process. Let us examine the situation in the two types of experiments. In a production experiment a reaction in which the resonance is produced is studied. For example to study hadrons decaying into π + π − π 0 , one collects a sample of events (59)

π + d → π + π − π 0 pp,

measures the momenta and energies of the final particles and calculates the mass of the π + π − π 0 system (60)

   2 2 m π + π − π 0 = (Eπ+ + Eπ− + Eπ0 ) − (pπ+ + pπ− + pπ0 ) .

Often this quantity is called “invariant” mass of the system, which is again a bad name, because it suggests the existence of non-invariant masses. It is simply the mass. A resonance appears as a peak in the mass distribution. In general other resonances and non-resonant processes lead to the same final state. To determine the mass and the width of the resonance, one fits the data with a model including the contributions of all these channels. The result is always somewhat model-dependent. Even in those very few cases in which the resonant channel is dominating the result still depends on the assumed line shape, which is not necessarily a Breit-Wigner. We take two examples of meson resonances from PDG [33]: the narrow η meson (Γ = 1.30 ± 0.07 MeV) has a mass m = 547.51 ± 0.18 MeV, the wide a1 (1260) has a mass m = 1230 ± 40 MeV and a badly determined width, Γ = 250–600 MeV. As examples of formation, consider the pion-nucleon resonances. These are extracted from the data by means of the phase-shift analysis. The result of the analysis are the scattering amplitudes of defined isospin, angular momentum and parity as functions of the centre-of-mass energy. There are two isospin amplitudes, I = 1/2 and I = 3/2, for each angular momentum and parity. Of these two complex functions an overall phase is arbitrary and we are left with three independent real functions, which are determined by

127

The mass of the particles

qIm(f)

Ecm=m Ecm Ecm=m+Γ/2

1/2 2δ

Ecm=m−Γ/2

qRe(f) η Fig. 5. – The Argand diagram for a Breit-Wigner resonance.

studying the three reactions (61a)

π + p → π + p,

(61b)

π − p → π − p,

(61c)

π − p → π 0 n.

The differential cross-sections of the three processes have been measured, in the 1960s, at small steps of beam energies, with accurate control of all the systematic uncertainties. Measurements on polarised hydrogen target are also needed in order to solve the ambiguities otherwise present in the inversion problem. A partial wave amplitude is characterised by the isotopic spin I, the pion-nucleon angular momentum L (or equivalently the parity) and the total angular momentum J. We denote it with L2I,2J (in practice S11 , S31 for S-waves, P11 , P13 , P31 , P33 for P waves, etc.) and with q the centre-of-mass momentum. The general procedure to infer the presence of a resonance and, if established, to extract its mass and width is to study the Argand diagram, in which is the real and imaginary parts of the function 2qL2I,2J for different values of energy are plotted to form a trajectory. The resonant amplitude is expected to be (62)

L2I,2J =

1 (ηL,I,J exp (i2δL,J,I ) − 1) . 2iq

This function is graphically shown in fig. 5 in the simplest hypothesis of a purely Breit-Wigner amplitude, namely (63)

Γel /2 , m − Ec.m. − iΓ/2

where Γ is the total width, Γel is the elastic one, m is the resonance mass and Ec.m. is the centre-of-mass energy.

128

A. Bettini

a)

b)

c)

d)

Fig. 6. – a) Pure Breit-Wigner, Γel > Γ/2; b) pure Breit-Wigner, Γel < Γ/2; c) Breit-Wigner plus “attractive” background, < Γ/2; d) Breit-Wigner plus “repulsive” background.

If a resonance exists, that function describes a circle, or fraction of it, in the Argand diagram in counter-clock wise direction. In the ideal case of a pure, completely elastic (η = 1) resonance the amplitude follows the unitary circle, the external one in fig. 5, and the resonance energy (the mass) and width are easily determined. However, this is only the case of the Δ33 and usually the situation is different: non-resonant contributions add to eq. (62), the elasticity may be low and varying with energy across the resonance, the resonance may not be perfectly described by the Breit-Wigner of eq. (62), etc. Examples are shown in fig. 6. Several errors in the values of the resonance mass and energy are difficult to estimate. At the 1969 International Conference on Elementary Particles held at Lund, Sweden, in 1969, R. J. Plano [38] listed the following large systematic contributions: 1) The background cannot be separated exactly even if the Argand diagram is exactly known. 2) Phase shift solution are not always unique. 3) Errors on input data are difficult to propagate to the Argand diagram. In several cases the resulting uncertainty on the resonance mass ranges between 50 and 200 MeV. Figure 7 shows as an example the Argand diagram for the P33 amplitude (where the subscripts are 2J and 2I). The most accurate measurements of strongly decaying hadron masses (and widths) are made in formation experiments by using e+ e− colliders. Differently from the just discussed pions and protons, electrons are non-composite particles. Moreover, when they collide and annihilate matter disappears in a pure energy quantum state with well-defined angular momentum, parity and charge-conjugation, J P C = 1−− , the quantum numbers

129

The mass of the particles

Δ(1232)

0.75 0.50

Δ(1600)

Δ(1920)

0.25 0

−0.5

−0.25

0

0.25

0.5

Fig. 7. – Argand diagram of the P33 amplitude in πp scattering. The completely elastic Δ33 (1232) resonance is clearly visible. The extraction of masses and widths of the two resonances at higher energies is more uncertain.

of the photon. We due to B. Touschek who, fascinated by these unique characteristics, was able to make real the dream of generating collisions between matter and antimatter beams, building ADA in Frascati in 1960. Vector mesons are observed in e+ e− colliders by measuring a relevant cross-section as a function of the centre-of-mass energy: e+ e− → π + π − in the case of the ρ, e+ e− → π + π − π 0 in the case of the ω, e+ e− → K + K − , e+ e− → KS0 KL0 and e+ e− → ηγ in the case of the φ, e+ e− → hadrons for the J/ψ, the other ψ’s and the Υ’s. The centre-of-mass energy is determined by measuring the beam energies at the interaction point. This can be done with very high accuracy. Intrinsic limits to the accuracy in the determination of the mass (and even more of the width) of this procedure is the uncertainty on the shape of the resonant line due to our incomplete ability to calculate the strongly interactions in the final state. Again, these uncertainties are increasing functions of the width. The errors are [33]: ±400 keV for the ρ (Γ = 146.4 ± 1.1 MeV); ±120 keV for the ω (Γ = 8.49 ± 0.08 MeV); ±19 keV for φ (Γ = 4.26 ± 0.05 MeV); ±11 keV for the J/ψ (Γ = 93.4 ± 2.1 keV) and ±260 keV for the Υ(1S) (Γ = 54.02 ± 1.25 keV). Notice that in the two latter cases the masses, and consequently the c.m. energies are large, about 3 GeV and almost 9.5 GeV, respectively. The relative errors on the masses are 3.7 p.p.m. and 27 p.p.m. Notice also that the widths are comparable with the energy resolution and that consequently are not directly measured. They are determined by measuring the “peak area”, which is independent of the energy resolution in a first approximation. The accuracy in the determination of mass and width of the ρ meson is difficult due to its large width. To extract the parameters from the cross-section vs. energy data, one needs to assume a definite “line shape” in the fitting procedure. This function is not a relativistic Breit-Wigner with a P -wave width, but requires some additional

130

A. Bettini

parameters [39]. The latter are introduced on a phenomenological basis, in the absence of precise means for QCD calculations at these low energies. Consider now the mass of the Z 0 boson (even if it is not a hadron as those discussed in this section). In this case the Standard Model does provide the theoretical instruments for a perturbative calculation of the line shape, of high accuracy. This is true also in the hadronic channels, because the coupling constant αs is already small enough to allow such expansion at the Z mass. In parallel to the theoretical calculations, an outstanding coordinated programme involving scientists both of the experiments and of the machine led to the astonishing precision on the LEP energy at each interaction √ point of σ( s) = ±2 MeV, which is about 20 p.p.m. Another experimental effort was dedicated to the high-accuracy determination of the luminosity at each experiment by measuring the small-angle Bhabha scattering, leading to a common uncertainty in the cross-sections of 0.061%. The result [33] is mZ = 91.1876 ± 0.0021 GeV, with a relative accuracy of 23 p.p.m. 8. – The quark masses Quarks exist only inside the hadrons, with the exception of top. Since they are never free, their mass is not a physical observable. In other words, quark mass is a property of a coloured object, while we can only measure properties of colour-singlets. Consequently, quark masses can be defined only within a definite theoretical scheme and not without theoretical uncertainties. In the Standard Model one starts from the mass parameters mq appearing in the mass term of the QCD Lagrangian. For the quark q this is (64)

Lqm = mq ψ¯q ψq .

In QED the lepton masses are observable and can be identified in the theory with the pole of the propagator without ambiguity. In QCD, it turns out that, despite the impossibility to observe the quarks free, quark masses can be consistently treated in perturbation theory, similarly to the coupling constants. The procedure leading to finite values of the scattering and decay amplitudes is called renormalisation. This procedure is not unique and several renormalisation schemes can be chosen. Moreover, a scale parameter μ, which has the dimensions of an energy, must be introduced. In this lecture we shall only recall the different types of “mass” that appear in QCD. For a complete discussion, by an expert, see for example [40]. The physical observables must be independent of the choice of the scheme, a property called renormalisation invariance. The set of the transformations that relates analogous quantities in different renormalisation schemes is called renormalisation group. In each scheme the coupling constants of the various interaction terms and the masses of the particle-fields are functions of the energy (or momentum transfer). By imposing the invariance of the physical quantities under the renormalisation group, one obtains a set of differential equations (RGE=Renormalisation Group Equations) for these

131

The mass of the particles

Table I. – Quark masses [33]. Quark

Mass

d

3–7 MeV

u

1.5–3.0 MeV

s

95 ± 25 MeV

c

1.25 ± 0.09 GeV

b

4.20 ± 0.07 GeV

t

172.6 ± 1.4 GeV

functions [41, 42]. The equations can be solved within an appropriate renormalisation scheme, giving the so-called “running” of the couplings and of the masses. The most commonly used renormalisation scheme in QCD is the (modified) Minimal Subtraction scheme M S [43, 44]. Starting from the mass term (64) and from the corresponding “bare” propagator, the procedure leads at each perturbation order to a full propagator (at that order), which is a function of the 4-momentum p, with a pole at certain value of p2 . The square root of this value is called the “pole mass” of the quark q, Mq . The renormalisation group equation is solved using the pole mass as a boundary condition obtaining a function of p2 , m(p ¯ 2 ), called the “running mass”. It is gauge invariant, but renormalisation scheme and scale dependent. One can also define an associated renormalisation group invariant mass m. ˆ Notice that the pole mass cannot be defined with arbitrary accuracy because nonperturbative large-distance, or small-energy, effects are always present. A consequence is that the complete propagator does not have any pole and the “pole mass” loses its meaning outside perturbation theory. Nature has chosen to give to three quarks, u, d and s, masses substantially smaller than the characteristic scale ΛQCD (light quarks) and substantially larger to the other three (c, b and t). Only the masses of the latter are in the perturbative regime. At large distances one exploits the chiral symmetry of the QCD Lagrangian, which holds in the limit of vanishing quark masses. The symmetry is spontaneously broken by the vacuum and explicitly by the quark masses. To extract the light quarks masses, a number of observables including the pseudoscalar mesons squared masses and decay rates are expanded in powers of the quark masses (Chiral Perturbation Theory). Quarks masses as quoted by the Particle Data Group [33] are given in table I. The authors state that their values “have been obtained by using a wide variety of methods. Each method involves it own set of approximations and errors. In most cases, the errors are a best guess at the size of the neglected higher-order corrections or other uncertainties.” All masses are calculated in the M S scheme, but the authors note “that the quark mass values can be significantly different in the different schemes.”

132

A. Bettini

For light quarks, the renormalisation scale has been chosen to be μ = 2 GeV. Notice that the light quark masses are rather sensitive to the scale. For example at 1 GeV, m(1 ¯ GeV)/m(2 ¯ GeV) ≈ 1.35. For two heavy quarks, charm and beauty, the renormalisation scale is chosen to be equal to the quark mass. The quoted values are m ¯ c (μ = m ¯ c) and m ¯ b (μ = m ¯ b ), respectively. The top quark, differently from the other ones, decays before getting trapped in a hadron. Its mass has been measured with a better than 1% accuracy at the TEVATRON collider experiments [45]. The top mass is a very important quantity for precision tests of the Standard Model and because it contributes substantially to the constrains to the Higgs mass and on physics beyond the Standard Model. Consequently, we should investigate what is really the measured quantity and which are the associated theoretical uncertainties. Since top is coloured and only colour singlets are observable, its mass is not a physical observable and one must chose an observable linked to the top mass with theoretical uncertainties as small as possible. There are two main possibilities related respectively with production experiments (presently at the TEVATRON and in the future at the LHC) and formation experiments (that may become possible in a not too close future). The experiments at TEVATRON look for the top in processes like p + p¯ → t + t¯ + X, (65)

t → W + + b → W + + jet(b), W → eνe or → μνμ ,

t¯ → W − + ¯b → W − + jet(¯b),

W → q q¯ → jet + jet,

where jet(b) means a jet containing an identified b candidate. The momenta and energies of the charged leptons and hadrons are measured with the tracking spectrometers and the calorimeters, the jets are then defined and reconstructed. Finally the jet-mass, the mass of the system into which the top decayed, say the jet(b)jet-jet system, is calculated and the top mass extracted from its distribution. The issue of the theoretical uncertainties associated with this top “jet-mass” and with its relationship with the mass in the Lagrangian has been recently discussed by S. Fleming et al. [46]. The authors find that, “while considerable work has and is being invested to control experimental systematic effects, very little theoretical work exists which studies both perturbative and nonperturbative QCD aspects of the resulting invariant mass distribution. Also, to our knowledge, there has been no theoretical work on how the shape and the resonance mass of this distribution are related to a short-distance top mass parameter in the QCD Lagrangian.” The main sources of uncertainty are: 1) Tops are produced at small transverse momentum at the TEVATRON (due to their large mass); consequently the soft radiation and colour reconnection contributions are appreciable, and are uncertain because they must be evaluated in the non-peturbative regime. (The situation will improve at LHC.) 2) The momentum of a given parton is identified with the measured momentum of the jet into which it hadronises, with a procedure that has uncertainties. 3) Parts of the

133

The mass of the particles

underlying event are included in the jet by the algorithms; their subtraction has uncertainties. 4) Uncertainties in the treatment of initial- and final-state radiations. Analysis shows that these effects can shift the jet-mass distribution, and consequently the evalu√ ation of mt by as much as ΛQCD s/mt . This implies that the relationship between the measured top “jet-mass” and the top mass used in the Standard Model calculations may be uncertain by a few GeV. The same authors have analysed the accuracy that might be reached with an e+ e− collider of sufficiently high energy —such as the ILC— to allow the measurement of the cross-section (66)

e+ e− → tt¯

across its threshold. The cross-section will gradually increase in the neighbours of the threshold energy, √ s = 2mt , smeared by the large top width Γt ≈ 1.4 GeV. Notice that now the tt¯ system is in a colour singlet state and as such is directly observable. Moreover the jet systems originating from the two quarks are substantially one in the forward and one in the backward hemispheres. The authors demonstrate that the soft radiation corrections to the top-mass extracted from the behaviour of the cross-section can be precisely controlled. This leads to a short-distance mass parameter that, in principle, can be measured with a precision better than ΛQCD . We shall consider now the experimental evidence available on the running of the quark masses, namely on their variation with momentum transfer, or with the centre of mass energy. The running of α, αs and of the weak angle sin θW has been extracted from the measured cross-sections of relevant processes and found in agreement with the predictions of the Standard Model. The determination of the running quark masses can be done in a similar way, namely by measuring cross-sections, through QCD calculations. This has been done at LEP for the b quark. In general the mass effects on the cross-sections are proportional to m2 /Q2 , where Q is the relevant energy. On the other hand, in order to have a good control on the QCD calculations, one needs to work at Q  ΛQCD , for example at LEP, with the consequence that m2 /Q2 1 and the mass effects are mall. This is why the running has been established for the heaviest quark (of those produced at LEP), the b, for which (67)

m2b ≈ 0.003. MZ2

Consider the three-jet events, corresponding to a gluon radiation by one of the final quarks. Jets originating by b quarks can be identified by observing the B decay vertex with the micro-vertex detectors. The cross-section of three jets in the case of b quarks, as in fig. 8b), has been observed to be a few percent smaller than that for light quarks, as in fig. 8a).

134

A. Bettini

e+

e+

d Z

−

d

b Z

d

b

−

e

b

e a)

b)

Fig. 8. – Tree-level diagrams for single gluon radiation from a) light quark, generically labelled as d and b) b quark.

The measured quantity is the ratio between the branching ratios (68)

R3bd ≡

Γb3j /Γb Γd3j /Γd

.

¯ b (MZ ) = m ¯ b (m ¯ b ). In the We can extract m ¯ b at MZ and search for effects of m M S renormalisation scheme the pole b mass is Mb ≈ 4.7 GeV and its running mass is m ¯ b (m ¯ b ) ≈ 4.2 GeV, as shown in table I. The “running mass” equation can be written at order αs as    m2 2 4 − log 2b . ¯ 2b (μ) 1 + αs (μ) (69) Mb2 = m π 3 μ Define the dimensionless quantity (70)

rb (μ) ≡

m ¯ 2b (μ) . MZ2

Calculations at the next to the leading order lead to the equation   αs (μ) bII [rb (μ)] , (71) R3bd (μ) = 1 + rb (μ) bI [rb (μ)] + π where bI and bII are known functions that we do not need to show here. From this equation we can extract m ¯ 2b (MZ ) from the measurement of R3bd . In practice there are several complications and uncertainties due to: the quark masses values used in the Monte Carlo at the parton level and those used at the hadronisation level, the choice of the fragmentation function, the value taken for the jet-resolution parameter yc , etc. The result of the DELPHI experiment [47] is (72)

m ¯ b (MZ ) = 2.67 ± 0.25(stat.) ± 0.34(frag.) ± 0.27(theo.) GeV,

¯ b ) ≈ 4.2 GeV. Similar results have been obwhich is substantially smaller than m ¯ b (m tained by the other experiments as shown in fig. 9 [48].

135

The mass of the particles

Fig. 9. – The b quark mass running as measured at LEP and SLC.

9. – The mass of the hadrons The mass of the proton is about 1 GeV, those of the d and u quarks it contains are only several MeV. What is the origin of the (vast majority) of the proton (and other hadrons) mass? In principle the hadron mass spectrum can be calculated from first principles from the QCD Lagrangian. However, these calculations cannot be done using a perturbative expansion and are consequently extremely difficult. They are performed on powerful supercomputers simulating the hadronic systems on a four-dimensional lattice (lattice-QCD). The development of a number of theoretical approaches and the present availability of multi-Teraflops dedicated platforms, sometimes developed by the community itself as in the case of the APE series, is now leading to several-percent accuracy results. We shall give here only a semi-quantitative answer to the above question, based on simple physics arguments. Consider first, as a well-known example, the hydrogen atom. Its size, the Bohr radius, is determined by the uncertainty principle. The mass of the system is the sum of the electron and of the proton masses and of the binding energy due to the electromagnetic interaction. It is negative and decreasing with decreasing distance between electron and proton. But the localization of the wave function has an energy cost. The smaller the uncertainty of the electron position, the greater the uncertainty of its momentum, implying that the average value of the momentum itself is larger and, finally, that the average kinetic energy is larger. The atomic radius is the distance at which the sum of potential and kinetic energy is at a minimum. Performing this calculations we have (73)

E=

p2 e2 , − 2me r

136

A. Bettini

where (74)

e2 ≡

qe2 ∼ = 2.3 × 10−28 J m. 4πε0

The uncertainty principle pr = h ¯ gives in eq. (73) (75)

E=

¯2 h e2 . − 2 2me r r

We now find the value of r for which total energy is a minimum  (76)

dE dr

 =0=− a

¯2 h e2 + 2, 3 me a a

that gives (77)

a=

¯2 h = 52.8 pm, me e2

which is the Bohr radius. The binding energy is (78)

E(a) =

e2 e2 e2 − =− = −13.6 eV 2a a 2a

and finally the mass of the atom is (79)

mH = mp + me − 13.6 eV.

In words: the mass of the hydrogen atom is the sum of the masses of its constituents and of the work that must be done on the system to move the constituents in a configuration in which their interaction is zero. This configuration, for the atom, is when the constituents are far apart. The work is negative and small in comparison with the masses of its constituents. Having recalled a familiar case, let us go back to the proton. The QCD interaction amongst the three valence quarks is strong at a distance of the order of the proton radius (a little less than a femtometre). On the other hand, if the three quarks were located at the same point, they would not interact because the three antiscreening clouds would cancel each other out exactly (in the colour singlet configuration in which they are). This cannot happen precisely because of the energy cost of the localisation of the wave functions. The three quarks adjust their positions at the average distance that minimizes the energy, as in the case of the atom. We start with the evaluation of the proton mass. Again this is the sum of the masses of the constituent quarks (a small fraction of the total) and of the work that must be done on the system to bring the constituents into a configuration in which they do not interact;

137

The mass of the particles

this is now where the quarks are very close to each other. The work is positive because it corresponds to the extraction of energy from the system (the “spring” is contracting) and is by far the largest contribution to the proton mass. The scale of the energy difference between an intense and negligible interaction is, of course, ΛQCD . In order of magnitude, the work to bring one quark into a non-interacting configuration is ΛQCD ≈ 300 MeV. In total (three quarks) we have mp ≈ 3ΛQCD ≈ 1 GeV. Having obtained a reasonable value for the proton mass, let us now check if we find a reasonable value for the proton radius. We need to know how the colour interaction energy varies with the distance between two quarks. Simulations on super-computers have been done by D. Leinweber [49]. They show that when the distance between two quarks increases, gradually a “colour tube” takes form between them becoming well developed already at about 0.5 fm. The colour tube contains energy, corresponding to vacuum fluctuations. Since its diameter remains roughly constant when quarks separate, the work needed to separate two quarks by dx is proportional to dx. We shall consequently assume that the energy of the colour field increases proportionally to the average distance x between the quarks, say as kx. The quark velocities are close to the speed of light and we can assume their kinetic energy to be equal to their momentum p. In conclusion the energy of the three quarks is E = 3p + kx. The uncertainty principle now gives px ≈ 1 and we have (80)

E=

3 + kx. x

We now find a relation between the unknown constant k and the equilibrium interquark distance xp by imposing the energy to be minimum  (81)

dE dx

 =0=− xp

3 + k, x2p

which inserted in eq. (80) gives (82)

mp = E (xp ) =

6 . xp

For mp ≈ 1 GeV we have xp ≈ 1.2 fm. This is the average distance between two quarks. If the three quarks are at the vertices of√an equilateral triangle, as it should be on average, the radius of the proton is rp = xp / 3 ≈ 0.7 fm, which is the correct value. This result is even too good for the very rough calculation we made. In conclusion, 98% of the hadron mass, i.e. 98% of the visible matter, is energy of the colour field. (Mass is not an additive quantity.) Even in vacuum, QCD induces non-zero values of the colour field. At the femtometre scale, vacuum is an extremely active dynamical medium. The presence of quarks, in a colour singlet state, triggers the condensation of these fluctuation as hadronic mass. The large majority of the mass of matter we know. Which, however, contributes only as a 4% to the mass-energy budget of the Universe.

138

A. Bettini

10. – Conclusions I have shown examples of errors on elementary concepts, which still persist even in the specialised literature one century after their development. It is always useful to read critically the original papers, rather then to believe blindly to the books and to the review papers (including the present one). In doing so one can think to detect errors even in the greatest authors. Often this is due to a misunderstanding of the reader himself. Sometimes, however, those mistakes are really present. Quandoque bonus dormitat Homerus as the Romans said. More important, the use of wrong or simply misleading concept should be avoided especially when addressing a class of students or the general public. Wrong concepts are the “relativistic” mass (increasing with velocity), the “rest” mass (that is the mass) and the equation E = mc2 , instead of the correct E0 = mc2 (the 0 is important!). We have discussed the meaning of “mass” in different circumstances and how this meaning is often defined only within a finite accuracy. Other concepts to be avoided are the following: The “constituent quark mass”, which is neither a physical observable nor can be rigorously defined theoretically. It is a historical leftover of the period in which the Standard Model was developed. Mass is a property of the stationary states and consequently it is improper and somewhat misleading to speak of K 0 mass and, much more, of “electron neutrino mass”. ∗ ∗ ∗ I am grateful to the Directors, F. Ferroni and F. Vissani, for having given me the opportunity to prepare a “different lecture” at the CLXX Course “Measurement of neutrino mass” of the Italian Physical Society in the beautiful Villa Monastero. I have been helped in the preparation of this lecture by fruitful discussions with G. Busetto, L. Cifarelli, J. Fuster, T. Pich and A. Smirnov. REFERENCES [1] [2] [3] [4]

[5]

[6] [7] [8] [9]

Okun L. B., Phys. Today, June (1989) 31. Okun L. B., Phys. Usp., 178 (2008) 541 (English version 51 (2008) 5). ´ H., C. R. Acad. Sci. Paris, 140 (1905) 1504. Poincare ´ H., Rend. Circ. Matem. Palermo, 21 (1906) 129. For a “modernised” translation Poincare into English see Schwartz H. M., Am. J. Phys., 39 (1971) 1287; ibid. 40 (1972) 862 and 1282. ´ ´ H., L’Etat Poincare actuel et l’avenir de la Physique Math´ematique, lecture delivered at St. Louis, 24/9/1904; Bull. des Sc. Math., 28 (1904) 302 (English translation in The Monist, 15 (1905) 1). Einstein A., Ann. Physik, 17 (1905) 891. Einstein A., Ann. Physik, 18 (1905) 639. Planck M., Verh. Deutsch. Phys. Ges., 8 (1906) 136; Phys. Zs., 9 (1908) 828; Verh. Deutsch. Phys. Ges., 10 (1908) 728. Landau L. D. and Lifschitz E. M., Teoryia polya (Gotstekhizdat, Moscow-Leningrad) 1941.

The mass of the particles

139

[10] Landau L. D. and Lifschitz E. M., The Classical Theory of Fields (Addison-Wesley Press, Cambridge, MA) 1951. [11] Feynman R., Leighton R. and Sands M., The Feynman Lectures on Physics (Addison Weseley, Reading, MA) 1963-1965. [12] Landau L. D. and Rumer Yu. B., What is relativity? (Basic Books, Dover) 1959. ´ E., Arch. Neerl., 5 (1900) 252. [13] Poincare [14] Abraham M., Physik Z., 5 (1904) 576; Theorie der Electrzitat, Vol. 2 (Leipzig, Tuber) 1905. [15] Lorentz H. A., The Theory of Electrons (Dover) 1952. [16] Rohrlich F., Am. J. Phys., 28 (1960) 639; ibid. 38 (1970) 1310; Classical Charged Particles (Addison-Wesley, Reading, MA) 1965; Classical Charged Particles (World Scientific) 2007. [17] Thomson J. J., Philos. Mag., 11 (1881) 229. [18] Fermi E., Z. Physik, 24 (1922) 340; Atti Accad. Naz. Lincei, 31 (1922) 184 and 306. [19] Kwal B., J. Phys. Radium, 10 (1949) 103. [20] Minkowski H., Nachr. Ges. Wiss. G¨ ottn Mth.-Phys. Kl, 53 (1908). [21] Abraham M., Rend. Circ. Matem. Palermo, 28 (1909) 1. [22] Pfeifer R. N. C. et al., Rev. Mod. Phys., 79 (2007) 1197. [23] Jones R. V. and Richards J. C. S., Proc. R. Soc. London, Ser. A, 221 (1954) 480. [24] de Groot S. R. and Suttorp L. G., Foundations of Electrodynamics (North Holland, Amsterdam) 1972; Mikura Z., Phys. Rev. A, 13 (1976) 2265; Israel W., Phys. Lett. B, 67 (1977) 125. [25] Garrison J. C. and Chiao R. Y., Phys. Rev. A, 70 (2004) 053826. [26] Jones R. V. and Leslie B., Proc. R. Soc. London, Ser. B, 360 (1978) 347. [27] Peccei R. D. and Quinn H. R., Phys. Rev. Lett., 38 (1977) 1440; Phys. Rev. D, 16 (1977) 17. [28] Primakoff H., Phys. Rev., 81 (1951) 899. [29] Raffelt G. and Stodolsky L., Phys. Rev. D, 37 (1988) 1237. [30] Zioutis K. et al., hep-ex/0411033. [31] Van Bibber K. et al., Phys. Rev D, 39 (1989) 2089. [32] Wolfenstein L., Phys. Rev. D, 17 (1978) 2369; ibid. 20 (1979) 2634; Mikheyev S. P. and Smirnov A. Yu., Yad. Fiz, 42 (1985) 1441; Nuovo Cimento C, 9 (1986) 17. [33] Yao W.-M., J. Phys. G, 33 (2006) 1. [34] Mohapatra R. and Pal P., Physics of Massive Neutrinos (Word Scientific) 2004. [35] Fogli G. L. et al., hep-ph 0806.2649v1. [36] Giunti C. and Kim C. W., Fundamentals of Neutrino Physics and Astrophysics (Oxford University Press) 2007. [37] OPERA proposal. CERN/SPSC 2000-028; SPSC/P318; LNGS P25/2000. July 10, 2000. [38] Plano R., Proceedings of the Lund International Conference on Elementary Particles (Berlingska Bokttryckeriet, Lund) 1969, p. 323. [39] Pisut J. and Roos M., Nucl. Phys. B, 6 (1968) 325. [40] Narrison S., QCD as a Theory of Hadrons (Cambridge University Press) 2004. [41] Steuckelberg E. C. G. and Peterman A., Helv. Phys. Acta, 26 (1953) 499. [42] Gell-Mann M. and Low F. E., Phys. Rev., 95 (1954) 1300. [43] ‘t Hooft G., Nucl. Phys. B, 61 (1973) 455. [44] Bardeen W. A. et al., Phys. Rev. D, 18 (1978) 3998. [45] Tevatron Electroweak Working Group, (2007) hep-ph/0703034.

140

A. Bettini

[46] Fleming S., Mantry S. and Stewart I. W., Phys. Rev. D, 77 (2008) 074010; Hoang A. H. and Stewart I. W., Phys. Rev. Lett. B, 660 (2008) 483; Fleming S., Mantry S. and Stewart I. W., arXiv:0711.2079, Phys. Rev. D, 77 (2008) 114003; Jain A., Scimemi I. and Stewart I. W., arXiv:0803.4214. [47] Abreu et al., Phys. Lett. B, 418 (1998) 430. [48] Abbiendi G. et al., Eur. Phys. J. C, 21 (2001) 411. [49] Leinweber D., http://www.physics.adelaide.edu.au/theory/staff/leinweber/.

DOI 10.3254/978-1-60750-038-4-141

Neutrinoless double-beta decay: impact, status and experimental techniques A. Giuliani Dipartimento di Fisica e Matematica, Universit` a dell’Insubria Via Valleggio 11 - 22100 Como, Italy

Summary. — This paper summarizes the relevance of neutrinoless double-beta decay for neutrino physics and the implications of this phenomenon for crucial aspects of particle and astroparticle physics. After discussing general experimental concepts, like the different proposed technological approaches and the sensitivity, the present experimental situation is reviewed. The future searches are then described, providing an organic presentation which picks up similarities and differences. As a conclusion, we try to envisage what we expect round the corner and at a longer time scale.

1. – Neutrino mass and Double Beta Decay The Standard Model (SM) of electroweak interactions describes neutrinos as lefthanded massless partners of the charged leptons. The experimental identification of the third generation of quarks and leptons completed the model, incorporating also a description of CP violation. The invisible width of the Z boson, caused by its decay into unobservable channels and measured at the e+ -e− annihilation experiments, show quite confidently that there are just three active neutrinos with masses of less than MZ /2. We know nowadays that neutrino flavors oscillate. From oscillations, we can evaluate the neutrino mixing matrix. The crucial feature is that unlike quark mixings, neutrino mixings are large. The meaning of this difference is not presently understood. Furthermore, oscillations inform us on mass square differences, not on the masses themc Societ`  a Italiana di Fisica

141

142

A. Giuliani

selves. We know that they are much smaller than charged-lepton masses, but the mass pattern is unknown. Anyway, the discovery that neutrinos have mass is a breakthrough by itself. It is the first serious crack in the SM building, after 30 years of almost boring successes. The smallness of the neutrino masses turns out to play a major role in improving our understanding of Grand Unified Theories (GUTs), originated by the efforts to unify the strong and electroweak interactions. Some GUTs allow to explain naturally small neutrino masses —if they are their own antiparticles, a fundamental issue addressed by the study of neutrinoless double-beta decay (0ν2β)— and the matter-antimatter asymmetry of the universe via leptogenesis. GUTs have also the potential to provide relations among the quark mixing matrix, the lepton mixing matrix, the quark masses, and the lepton masses. The peculiar properties of neutrinos, and in particular their mass scale, are a crucial challenge for GUTs and for any unified theoretical framework. Therefore, the experimental determinations of the neutrino mass scale, pattern and nature are essential bench tests for predictive GUTs and for the improvement of our understanding of the basic theory of fundamental interactions. In parallel, the understanding of Big-Bang nucleosynthesis and the features of the Cosmic Microwave Background (CMB) illustrate the important role of neutrinos in the history of the early universe. Neutrino flavor oscillations and other bounds tell us that the heaviest neutrino mass is in the range 0.04–0.6 eV. Therefore, neutrinos are a component of dark matter, but their total mass, although it outweighs the stars, gives only a minor contribution to invisible matter density. Neutrinos are so light to have streamed freely away from developing aggregations of matter until quite recently (in cosmological terms), when they eventually cooled and their speed has decreased to significantly less than the speed of light. What is then the neutrino role in shaping the universe? Do neutrinos allow to understand the matter-antimatter asymmetry of the universe, via leptogenesis? The answer to these questions requires the precise knowledge of the neutrino mass values. It is clear therefore that the neutrino mass scale is crucial over two fronts: progress in the comprehension of elementary particles and solution of hot astroparticle and cosmological problems. The studies of 0ν2β and end-point anomalies in β decay, in particular, are essential and unique in their potential to fix the neutrino masses and to answer keyquestions beyond neutrino physics itself. Both types of measurements will be required to fully untangle the nature of the neutrino mass. . 1 1. Neutrino flavour oscillations and neutrino mass. – Neutrino oscillations can take place since the neutrinos of definite flavor (νe , νμ , ντ ) are not necessarily states of a definite mass (ν1 , ν2 , ν3 ). On the contrary, they are generally coherent superpositions of such states (1)

|νl  =



Uli∗ |νi .

i

When the SM is extended to include neutrino mass, the mixing matrix U is unitary. As

Neutrinoless double-beta decay: impact, status and experimental techniques

143

a consequence the neutrino flavor is no longer a conserved quantity and for neutrinos propagating in vacuum the amplitude of the process νl → νl is not vanishing. The probability of the flavor change is the square of this amplitude. Due to the unitarity of U there is no flavor change if all masses vanish or are exactly degenerate. The idea of oscillations was discussed early on by Pontecorvo, and by Maki, Nakagawa and Sakata. Hence, the mixing matrix U is often associated with these names and the notation UM N S or UP M N S is used. In general, the mixing matrix of 3 neutrinos is parametrized by three angles, conventionally denoted as Θ12 , Θ13 and Θ23 , one CP violating phase δ and two Majorana phases α1 , α2 . Using c for the cosine and s for the sine, the mixing matrix U is then expressed as ⎛

⎞ ⎛ νe c12 c13 ⎝νμ ⎠ = ⎝−s12 c23 − c12 s23 s13 eiδ ντ s12 s23 − c12 c23 s13 eiδ

s12 c13 c12 c23 − s12 s23 s13 eiδ −c12 s23 − s12 c23 s13 eiδ

⎞ ⎛ iα1 /2 ⎞ s13 ν1 e s23 c13 ⎠ ⎝eiα2 /2 ν2 ⎠ . ν3 c23 c13

The three neutrino masses mi have to be added to the parameter set that describes this matrix, giving therefore nine unknown parameters altogether. The evidence for oscillations of solar (νe ) and atmospheric (νμ and ν μ ) neutrinos is compelling and generally accepted. Two of the three angles and the two mass square differences have been determined reasonably well. The unknown quantities, subjects of future oscillation experiments, are the angle Θ13 and the sign of Δm213 . If that sign is positive, the neutrino mass pattern is called a normal mass ordering (m1 < m2 < m3 ) and when it is negative it is called inverted mass ordering (m3 < m1 < m2 ). The extreme mass orderings, m1 < m2 m3 and m3 m1 < m2 , are called the normal and, respectively, inverted hierarchies. When m1 ∼ m2 ∼ m3 , one speaks of degenerate pattern. In addition, the phase δ governing CP violation in the flavor oscillation experiments remains unknown, and a topic of considerable interest. The remaining unknown quantities, i.e. the absolute neutrino mass scale and the two Majorana phases α1 , α2 , are not accessible in oscillation experiments. Their determination is the ultimate goal of 0ν2β and β decay experiments. . 1 2. The neutrino mass scale: a threefold concept. – Three methods can address directly the neutrino mass scale: analysis of CMB temperature fluctuations [1], doublebeta decay [2] and single-beta decay [3]. The quantities probed in these three approaches are however different, and are given respectively by mcosm =

3 

mi ,

i=1

(2)

 3     2 iαi  |Uei | mi e  , mββ =    i=1 7 8 3 8 |Uei |2 m2i . mβ = 9 i=1

144

A. Giuliani

The first method is observational, and performs a purely kinematical estimation of the neutrino masses. Even if very sensitive, it depends critically on cosmological and astrophysical assumptions and requires therefore independent checks. There is a large spread in the limits on mcosm (ranging in the interval 0.5–1.0 eV) according to different authors. The second and third methods are based on laboratory searches. The 0ν2β provides at the moment a sensitivity in the range 0.2–1.0 eV, with an uncertainty dominated by nuclear physics aspects. This process is not sensitive to neutrino masses if the neutrino is a Dirac particle, i.e. if it is not self-conjugate. Single-beta decay endpoint measurements, frequently referred to as “direct searches” for neutrino mass, are essentially free of theoretical assumptions about neutrino properties and are almost fully model-independent. The present limit achieved by this approach is 2.2 eV. The past and any future conceivable experiments are not able to disentangle the three values of the neutrino masses (although this operation would be possible in principle) because the required energy resolution and statistics are out of the reach of the present techniques. That is why single-beta decay is sensitive only to a weighted average of the mass eigenvalues, expressed by the second expression in eq. (2). It is important to stress that the parallel study of the three discussed variants of the mass scale is a crucial task. The parameters in eq. (2) depend on different combinations of the neutrino mass values and oscillation parameters. The 0ν2β decay rate is proportional to the square of a coherent sum of the Majorana neutrino masses because the process originates from exchange of a virtual neutrino. On the other hand, beta decay determines an incoherent sum because a real neutrino is emitted. In cosmology, the three masses play a kinematical role and the mechanisms of weak interactions are not relevant, therefore the testable parameter is a pure sum. That shows clearly that a complete neutrino physics program should renounce none of these three observational/experimental approaches, which are not redundant but rather complementary. They are all required to fully untangle the nature of the neutrino mass. The 0ν2β decay [2] is a rare nuclear process consisting in the simultaneous transformation of two neutrons into two protons in a nucleus, with the emission of two electrons and nothing else. One can visualize it by assuming that the process involves the exchange of proper virtual particles between two single-beta-decay-like vertices, e.g. light or heavy Majorana neutrinos, SUSY particles, and other more exotic options. Of primary interest is the process mediated by the exchange of light Majorana neutrinos interacting through the left-handed V-A weak currents. The decay rate is then (3)

(T0ν )−1 = G0ν (Q, Z) · M0ν · m2ββ , 1/2

where G0ν is the accurately calculable phase space integral (growing with the transition energy Q approximately as Q5 ), mββ is the effective neutrino mass (as defined by the second expression in eq. (2)), and M0ν the nuclear matrix elements. If the 0ν2β decay is observed, and the nuclear matrix elements are known, one can deduce the corresponding mββ value. Due to the presence of the unknown Majorana phases αi , cancellation of terms is possible, and mββ could be smaller than any of the mi . Thanks to the information we have

Neutrinoless double-beta decay: impact, status and experimental techniques

145

from oscillations, it is useful to express mββ in terms of three unknown quantities: the mass scale, represented by the mass of the lightest neutrino mmin , and the two Majorana phases. It is then useful to distinguish the already discussed three mass patterns: normal hierarchy(NH), inverted hierarchy (IH),  and the quasi-degenerate spectrum (QD) where mmin  |Δm231 | as well as mmin  |Δm221 . In the case of normal hierarchy, and assuming that m1 = mmin can be neglected, Θ13 = 0 and inserting the parameters as presently known from the analysis of the oscillation experiments, one obtains mββ = 2.6 ± 0.3 meV. On the other hand, there are possible combinations of Θ13 , Θ12 , Δm231 and Δm221 which provide a partial or complete cancellation, leading to a vanishing mββ . Not only, if mmin > 0 then mββ may vanish even for Θ13 = 0. In the case of the inverted hierarchy, and again assuming that m3 = mmin can be neglected, Θ13 = 0 and inserting the oscillation-derived parameters, one obtains mββ 14–51 meV, depending on the Majorana phases. Finally, for the quasi-degenerate spectrum, m0 being the common mass value and making the same assumption as above, mββ (0.71 ± 0.29) · m0 . For a discussion on the neutrino mass ordering, the Majorana phases and mββ , see for example [4]. If one can experimentally establish that mββ ≥ 50 meV, one can conclude that the QD pattern is the correct one, and one can extract an allowed range of mmin values. On the other hand, if mββ lies in the range 20–50 meV, only an upper limit for mmin can be established, and the pattern is likely IH, even though exceptions exist. Eventually, if one could determine that mββ < 10 meV but non-vanishing (which is unlikely in a foreseeable future), one could conclude that the NH pattern is the correct one. Altogether, observation of the 0ν2β decay, and an accurate determination of the mββ value, would not only establish that neutrinos are massive Majorana particles, but would contribute considerably to the determination of the absolute neutrino mass scale. Moreover, if the neutrino mass scale were known from independent measurements, one could possibly obtain from the measured mββ also some information about the CP violating Majorana phases. 2. – Experimental challenge and strategies When generically speaking of double-beta decay, one refers to a rare nuclear transition proposed by G¨ oppert-Mayer in the far 1935 for the first time. In this process, a metastable isobar changes into a more stable one by the simultaneous emission of two electrons. Such transition can take place in principle for 35 naturally occurring even-even nuclei, whose ordinary β decay is forbidden energetically or severely hindered by a large change of the nuclear spin-parity state. Double-beta decay is a second-order process of the weak interaction and has consequently a very low probability, which leads to extraordinary long lifetimes for the candidate nuclides. Three decay modes are usually discussed. The two-neutrino process (2ν2β), already observed in several nuclides, is described by (4)

− (A, Z) → (A, Z + 2) + e− 1 + e2 + ν 1 + ν 2

146

A. Giuliani

and is fully consistent with the SM. The neutrinoless channel (0ν2β) (5)

− (A, Z) → (A, Z + 2) + e− 1 + e2

violates lepton number conservation and, as already discussed, would definitely imply new physics beyond the SM. The available phase space is quite larger for this process than for the 2ν channel. Finally, a third, more exotic transition has been proposed (6)

− (A, Z) → (A, Z + 2) + e− 1 + e2 + χ,

where χ is a physical Nambu-Goldstone boson named Majoron, a hypothetical neutral pseudoscalar particle with zero mass, associated with the spontaneous breaking of the local or global B-L symmetry. This particle couples to a virtual Majorana neutrino exchanged between the two weak vertices in eq. (6). . 2 1. Experimental approaches and methods. – From the experimental point of view, the shape of the two-electron sum energy spectrum enables to distinguish among the three discussed decay modes. In case of 2ν2β —process of eq. (4)— this spectrum is expected to be a continuum between 0 and Q with a maximum around 1/3 · Q. In the case of Majoron emission —process of eq. (6)— the spectrum is again a continuum, but the maximum is shifted towards the transition energy. For 0ν2β —process of eq. (5)— the spectrum is just a peak at the energy Q, enlarged only by the finite energy resolution of the detector. Additional signatures for the various processes are the single-electron energy distribution and the angular correlation between the two emitted electrons. Q ranges from 2 to 3 MeV for the most promising candidates. The experimental strategies pursued to investigate the 0ν2β decay can be divided into two main classes. 1) Indirect search. It consists in looking for the daughter nuclei (A, Z + 2) in a sample containing a large amount of candidate nuclei (A, Z) and left undisturbed for a long time. Radiochemical and geochemical experiments belong to this class. This approach does not allow to distinguish among the three different channels (4), (5) and (6). Important 20– 30 years ago, it is no longer pursued nowadays. 2) Direct search. In this approach, a proper nuclear detector is developed, with the purpose to reveal the two emitted electrons in real time and to collect their sum energy spectrum as a minimal information. Additional pieces of information can be provided in some cases, like single-electron energy and initial momentum, or, in one proposed approach, the species of the daughter nucleus. The desirable features of this nuclear detector are: – High energy resolution, since a peak must be identified over an almost flat background in case of 0ν2β. – Low background, which requires underground detector operation (to shield cosmic rays), very radiopure materials (the competing natural radioactivity decays

Neutrinoless double-beta decay: impact, status and experimental techniques

147

have typical lifetimes of the order of 109 , 1010 years versus lifetimes longer than 1025 years for 0ν2β), and well-designed passive and/or active shielding against local environmental radioactivity. – Large source, in order to monitor many candidate nuclides. Present sources are of the order of 10 kg in the most sensitive detectors, while the next generation experiments aim at sources in the 100–1000 kg scale. – Event reconstruction method, useful to reject background and to provide additional kinematical information on the emitted electrons. Normally, the listed features cannot be met simultaneously in a single detection method. It is up to the experimentalist to choose the philosophy of the experiment and to select consequently the detector characteristics, privileging some properties with respect to others, having in mind of course the final sensitivity of the set-up to half-life and to mββ . The direct searches can be further classified into two main categories: the so-called calorimetric technique, in which the source is embedded in the detector itself, and the external-source approach, in which source and detector are two separate systems. The calorimetric technique has been proposed and implemented with various types of detectors, such as scintillators, bolometers [5], solid-state devices [6] and gaseous chambers. There are positive (+) and negative (−) features in this technique, here summarized: (−) there are severe constraints on detector material and therefore on the nuclides that can be investigated; (+) due to the intrinsically high efficiency of the method, large source masses are possible: ∼ 10 kg have been demonstrated, ∼ 1000 kg are planned; (+) with a proper choice of the detector, a very high energy resolution (of the order of 0.1%) is achievable, as in Ge diodes or in bolometers; (−) it is difficult to reconstruct event topology, with the exception of liquid or gaseous Xe TPC, but at the price of a low energy resolution. For the external-source approach many different detection techniques have been experimented as well: scintillation, gaseous TPCs, gaseous drift chambers, magnetic field for momentum and charge sign measurement, time of flight. These are the main features, with their positive or negative valence: (−) large source masses are not easy to achieve because of self-absorption in the source, so that the present limit is around 10 kg; (−) normally the energy resolution is low (of the order of 10%), intrinsically limited by the fluctuations of the energy the electrons deposite in the source itself;

148

A. Giuliani

(+) neat event reconstruction is possible, allowing to achieve a virtual zero background: however 0ν2β cannot be distinguished by 2ν2β event by event if the total electron energy is around Q; therefore, because of the low energy resolution, 2ν2β constitutes a severe background source for 0ν2β. . 2 2. The experimental sensitivity. – In order to compare different experiments, it is useful to give an expression providing the sensitivity of an experimental set-up to the 0ν2β lifetime of the investigated candidate, and hence to determine the sensitivity to mββ . The first step involves only detector and set-up parameters, while for the second step one needs reliable calculations of the nuclear matrix elements. The sensitivity to lifetime F can be defined as the lifetime corresponding to the minimum detectable number of events over background at a 1σ confidence level. For the case of a source embedded in the detector and non-zero background, there holds (7)

NA · ε · η F = · A



M ·T b · ΔE

 12 ,

where NA is the Avogadro number, M the detector mass, ε the detector efficiency, η the ratio between the total mass of the candidate nuclides and the detector mass, ΔE the energy resolution, and b the specific background, e.g. the number of spurious counts per mass, time and energy unit. From this formula one can see that, in order to improve the performance of a given set-up, one can use either brute force (e.g. increasing the exposition M · T ) or better technology, improving detector performance (ΔE) and background control (b). Nextgeneration experiments require to work on both fronts. In order to derive the sensitivity to mββ , indicated as Fmββ , one must combine eq. (7) with eq. (3), obtaining

(8)

Fmββ ∝



1 1

(G0ν (Q, Z)) 2 |M 0ν |

·

b · ΔE M ·T

 14 ,

which shows how the nuclide choice is more relevant than the set-up parameters, on which the sensitivity depends quite weakly. Nowadays, several experimental techniques promise to realize zero background investigations in the close future. In this circumstance, eqs. (7) and (8) do not hold anymore. The observation of 0 counts exclude Nb counts at a given confidence level. For instance, Nb = 3 is excluded at the 95% c.l. in a Poisson statistics. Therefore, the sensitivity F0 for a 0 background experiment is given by (9)

F0 =

and eq. (8) modifies accordingly.

NA · ε · η M · T · , A Nb

Neutrinoless double-beta decay: impact, status and experimental techniques

149

Table I. – Summary of the most sensitive direct searches for 0ν2β. Limits are at 90% c.l. Experiment CUORICINO (2007) NEMO3 (2008) Heidelberg-Moscow (2001) IGEX (2002) Mi DBD (2002) Bernabei et al. (2003) Danevich et al. (2003) Ejiri et al. (2001)

Isotope 130

Te Mo 76 Ge 76 Ge 130 Te 136 Xe 116 Cd 100 Mo

100

Half-life (y)

mββ (eV)(a)

mββ (eV)(b)

Ref.

> 3.1 × 1024 > 5.8 × 1023 > 1.9 × 1025 > 1.6 × 1025 > 2.1 × 1023 > 1.2 × 1024 > 1.7 × 1023 > 5.5 × 1022

< 0.2–0.68 < 0.8–1.3 < 0.35 < 0.33–1.35 < 0.9–2.1 < 1.1–2.9 < 1.7 < 2.1

< 0.39–0.60 < 1.0–1.1 < 0.32–0.57 < 0.34–0.62 < 1.5–2.3 < 0.9–1.1 < 1.7–2.1 < 3.3–3.5

[10] [11] [12] [13] [14] [15] [16] [17]

(a ) As quoted by the authors. (b ) As deduced from an updated choice of nuclear matrix elements, using the results of the three most active schools (see text and table II).

Uncertainties coming from nuclear matrix element calculations prevent for the moment from determining precise mββ values in correspondence of a given lifetime. Large spreads in the lifetime predictions for the same mββ , even more than one order of magnitude, existed in the past. Recently, thanks also to the coordinating role of ILIAS(1 ), signs of convergence within different schools showed up. For the evaluation of the sensitivities, it is recommendable to neglect old calculations and to use the results of the still active authors, who go on refining the nuclear models and considering new effects. In particular, three active schools should be considered. Two of them base their calculation on the QRPA method [7, 8], while the third one uses the Interactive Shell Model (ISM) [9]. 3. – Present experimental situation We are at a turning point in the experimental search for double-beta decay. Few experiments have given limits on mββ of about 0.5–1 eV, but they are either over or close to their final sensitivity. On the contrary, several next generation projects, which are in the construction or in the R&D phase, have the potential to improve present limits and to approach the IH region of the neutrino mass pattern. A summary of the present situation is exposed in table I, where NEMO3 is the only running experiment. . 3 1. The Heidelberg-Moscow experiment. – In the Ninties of the last century, the double-beta decay scene was dominated by the Heidelberg-Moscow (HM) experiment [12]. This search was based on a set of five Ge diodes, enriched in the candidate isotope 76 Ge at 86%, and operated underground with high energy resolution (typically, 4 keV FWHM) in the Laboratori Nazionali del Gran Sasso (LNGS), Italy. This search can be considered, (1 ) ILIAS (Integrated Large Infrastructures for Astroparticle Science), is a project funded by the European Commission in the VI Framework Program and aiming at coordinating and structuring the Astroparticle Physics community in Europe.

150

A. Giuliani

even from the historical point of view, as the paradigm of the calorimetric approach discussed in sect. 2. The total mass of the detectors is 10.9 kg, corresponding to a source strength of 7.6 × 1025 76 Ge nuclei, the largest in DBD searches so far. The raw background, impressively low, is 0.17 counts/(keV kg y) around Q (2039 keV). It can be reduced by a further factor 5 using pulse shape analysis to reject multi-site events. The limits on half-life and mββ are, respectively, 1.9 × 1025 y and 0.3–0.6 eV (depending on the nuclear matrix elements chosen for the analysis). Similar results have been obtained by the IGEX collaboration [13], with an experiment based on the same approach. A subset of the HM collaboration has however claimed the discovery of 0ν2β decay in 2001, with a half-life best value of 1.5 × 1025 y ((0.8–18.3) × 1025 y at 95% c.l.), corresponding to a best value for mββ of 0.39 eV (0.05–0.84 eV at 95% c.l. including nuclear matrix element uncertainty) [18]. This claim is based on the identification of tiny peaks in the region of the 0ν2β decay, one of which occurs at the 76 Ge Q-value. However, this announcement raised skepticism in the double-beta decay community [19], including a large part of the HM collaboration itself [20], due to the fact that not all the claimed peaks could be identified and that the statistical significance of the peak looked weaker than the claimed 2.2σ and dependent on the spectral window chosen for the analysis [21, 22]. However, new papers [23] published later gave more convincing supports to the claim. The quality of the data treatment improved and the exposure increased to 71.7 kg y. In addition, a detailed analysis based on pulse shape analysis suggests that the peak at the 76 Ge Q-value is mainly formed by single-site events, as expected in case of double-beta decay, while the nearby recognized γ peaks are compatible with multi-site events, as expected from γ interaction in that energy region and for detectors of that volume. A 4.2σ effect is claimed. Unfortunately, the HM experiment is now over and the final word on this crucial result will be given by other searches. . 3 2. The NEMO3 experiment. – The top level of the external-source technique was reached nowadays by the NEMO3 experiment. The NEMO3 detector, installed underground in the Laboratoire Souterrain de Modane (LSM), in France, is based on wellestablished technologies in experimental particle physics: the electrons emitted by the sources cross a magnetized tracking volume instrumented with Geiger cells and deliver their energy to a calorimeter based on plastic scintillators. Thanks to the division in 20 sectors of the set-up, many nuclides can be studied simultaneously, such as 100 Mo, 82 Se, 150 Nd, 116 Cd, 130 Te, 96 Zr, 48 Ca. Presently, the strongest source is 100 Mo with 4.1 × 1025 nuclei. The energy resolution ranges from 11% to 14.5%. Results achieved with 100 Mo fix the half-life limit to 5.8 × 1023 y, corresponding to limits of 0.8–1.3 eV on mββ [11]. The final sensitivity to this parameter is 0.1–0.3 eV. In NEMO3 experiment, all the best and all the limits of the external-source approach show off. From one side, the NEMO3 detector produces beautiful reconstructions of the sum and single-electron energy spectrum, and precious information about angular distribution. Double-beta decay events can be neatly reconstructed, as shown in fig. 1, with almost no competing background. Thanks to the multi-source approach, 2ν2β decay has been detected in all the seven candidates under obsevation, a superb physical and technical achievment which

Neutrinoless double-beta decay: impact, status and experimental techniques

151

Fig. 1. – Two-electron event (1029 keV + 750 keV) produced in the Mo source foil of the NEMO3 detector. The circle radii indicate the transverse distance of the track from the anod wires of the fired Geiger cells, while the rectangles represent the energy deposited in the calorimeter by the electrons. The track curvature induced by the magnetic field allows to identify the charge sign.

makes the NEMO3 set-up a real “double beta factory”. On the other hand, the lowenergy resolution and the unavoidable “bi-dimensional” structure of the sources make a further improvement of the sensitivity to 0ν2β quite difficult, because of the background from 2ν2β and of the intrinsic limits in the source strength. . 3 3. The CUORICINO experiment. – Bolometric detection of particles [24] is a technique particularly suitable to 0ν2β search, providing high energy resolution and large flexibility in the choice of the sensitive material [5]. It can be considered the most advanced and promising application of the calorimetric approach. In bolometers, the energy deposited in the detector by a nuclear event is measured by recording the temperature increase of the detector as a whole. In order to make this tiny heating appreciable and to reduce all the intrinsic noise sources, the detector must be operated at very low temperatures, of the order of 10 mK for large masses. Several interesting bolometric candidates were proposed and tested. The choice has fallen on natural TeO2 (tellurite) that has reasonable mechanical and thermal properties together with a very large (27% in mass) content of the 2β-candidate 130 Te. This property makes the request of enrichment not compulsory, as it is for the other interesting isotopes. Moreover, the reasonably high transition energy (2530 keV) and the favorable nuclear matrix elements make this nuclide one of the best candidate for 0ν2β search. A large international collaboration has been running an experiment for five years, named CUORICINO (which means “small CUORE —heart—” in Italian), now stopped, which was based on this approach and was installed underground in the Laboratori Nazionali del Gran Sasso [10]. CUORICINO consisted of a tower of 13 modules, containing 62 TeO2 crystals for a total mass of ∼ 41 kg,

152

A. Giuliani

Fig. 2. – Background in the region of 130 Te double-beta decay energy transition collected by the CUORICINO experiment with an exposure of 15.53 130 Te kg y. No structure is visible in correspondence to the Q-value. The continuous lines show the best fit and the limits at 68% and 90% c.l. for a peak at 2530 keV.

corresponding to a source strength of 5.0 × 1025 130 Te nuclei. CUORICINO results are at the level of the HM experiment in terms of sensitivity to mββ . A very low background (of the order of 0.18 counts/(keV kg y)) was obtained in the 0nu2β decay region, similar to the one achieved in the HM set-up. The energy resolution is about 8 keV FWHM, quite reproducible in all the crystals. The spectrum collected in the double-beta decay region is shown in fig. 2. Unfortunately CUORICINO, despite a sensitivity comparable to that of the HM experiment, cannot disprove the 76 Ge claim due to the discrepancies in the nuclear matrix element calculations. This can be seen by translating the half-life interval of the 76 Ge claim into three intervals (one for each of the three nuclear-matrix-element schools mentioned above) for the 130 Te half-life. Of course, this operation does not depend on the mββ value. As clear from fig. 3, the present CUORICINO limit, even if well inside these intervals, does not exclude them in any nuclear model. 4. – The future projects and the related technologies . 4 1. Selection of the candidates and of the technologies. – Due to the importance of the subject for neutrino and fundamental physics, strong efforts are produced all over the world to increase the sensitivity in the search for 0ν2β decay. The general goal of these experimental developments is to reach a sensitivity able in a first phase to approach the IH region of the neutrino mass pattern, i.e. mββ ∼ 50 meV, and in a second phase to cover fully this region, i.e. mββ ∼ 20 meV. Some general considerations apply to all the future searches. First, the importance to get a high Q-value, in terms both of the phase space for the process and of the impact

153

Neutrinoless double-beta decay: impact, status and experimental techniques

Fig. 3. – The three 130 Te half-life bands correspond (for three different nuclear models, designated as QRPA-1 [7], QRPA-2 [8] and ISM [9]) to the 90% c.l. half-life band claimed for 76 Ge. The CUORICINO limit covers a significant part of the bands, but does not exclude them fully.

of the γ background, limits substantially the number of candidate nuclei that are experimentally relevant. The list of the nuclei which are taken into consideration for future searches is reported in table II with their basic features, including the mββ estimations according to the three most active schools in nuclear-matrix-element calculations, designated as QRPA-1 [7], QRPA-2 [8] and ISM [9]. Secondly, given the best estimations of the nuclear matrix elements and the phase space factors, which grow quickly with the Q-value, it is easy to show that, for practically all the nuclei of interest, approaching the inverted hierarchy region means to

Table II. – Properties of the most relevant candidates for 0ν2β decay search. The mββ values are calculated assuming 1027 y half-life, using the results of the three most active schools in nuclear-matrix-element calculations. In the QRPA case, a central value has been used in the range indicated by the authors. The calculation for 150 Nd is not reliable as it does not include the effects of deformation. Candidate nucleus 130

Te Cd 76 Ge 136 Xe 82 Se 100 Mo 150 Nd 48 Ca 116

I.A. (%)

Q-value (keV)

Number of nuclei in 1 ton (×1027 )

mββ (meV) (QRPA-1) [7]

mββ (meV) (QRPA-2) [8]

mββ (meV) (ISM) [9]

33.8 7.5 7.8 8.9 9.2 9.6 5.6 0.187

2530 2802 2039 2479 2995 3034 3367 4270

4.6 5.2 7.9 4.4 7.3 6.0 4.0 12.5

24 27 45 39 25 24 7.5 –

22 22 44 32 31 26 – –

33 25 79 39 39 – – –

154

A. Giuliani

search for 1–10 counts/y/ton, while fully covering it means to be sensitive to 0.1– 1 counts/(y ton). This fixes immediately the size of the future experiments (from hundreds of kg to 1 ton of isotope) and the level of the requested background (that should be of the order of 0 or a very few counts in the region of interest for the total duration of the experiment, normally a few years). In a high energy-resolution experiment (with ΔEFWHM ∼ 1 keV) this request translates into a specific bakground coefficient b of the order of 1 counts/(keV y ton), while the target is even more ambitious for low-energyresolution search, where however the most critical role is played by 2ν2β decay. When designing a future double-beta decay experiment and selecting a detector technology for it, the experimentalist should therefore ask himself or herself three basic questions, the answer to which must be “yes” if that technology is viable and timely: 1) Is the selected technology able to deal with 1 ton of isotope, at least in prospect? 2) Is the choice of the detector and of the related materials compatible with a background of the order of at most 1 counts/(y ton) in the region of interest? 3) Can the experiment be designed and constructed in a few years, and can the chosen technique provide at least 80% live time for several years? The first question needs to be considered also from the economical point of view. As table II shows, practically all the nuclei of interest, with the significant exception of 130 Te, require isotopical enrichment. The cost of this process, when technically feasible, is in the range 10–100 $/g. Therefore, a next generation 0ν2β experiment has a cost in the range of several tens of millions of dollars, just to get the basic material. Let us see now which solutions are under test worldwide to get a positive answer to the three questions listed above. . 4 2. Classification and overview of the experiments. – As already discussed in sect. 2, two approaches are normally followed in 0ν2β decay experiments (calorimetric technique and external source) and two classes of searches can be singled out in terms of detector performance (high energy resolution without tracking capability and low-energy resolution with event topology reconstruction). This classification applies also to future searches. I will shortly review twelve projects, which are reported in fig. 4 and grouped in four categories in relation with the approaches and the performance mentioned above. The first category is characterized by the calorimetric approach and the high-energy resolution, with three planned experiments: – CUORE [25] - 130 Te Array of natural TeO2 bolometers operated at 10 mK, natural expansion of CUORICINO First step: 200 kg of isotope (2012), located in LNGS, Italy It will take advantage from CUORICINO experience Proved energy resolution: 0.25% FWHM Sensitivity to mββ : ∼ 50 meV Construction phase.

Neutrinoless double-beta decay: impact, status and experimental techniques

155

Fig. 4. – The most relevant projects are classified in four groups, according to the basic approach adopted and to the detector performance expected.

– GERDA [26] - 76 Ge Array of enriched Ge diodes operated in liquid argon First phase: 18 kg of isotopes (2009), located in LNGS, Italy; second phase: 40 kg of isotope - LNGS Proved energy resolution: 0.16% FWHM Sensitivity to mββ : ∼ 350 meV in the first phase, 100–300 meV in the second phase Construction phase. – MAJORANA [27] - 76 Ge Array of enriched Ge diodes operated in conventional Cu cryostats Based on 60 kg modules; first step: 2 × 60 kg modules Proved energy resolution: 0.16% FWHM R&D phase Merging with GERDA is foreseen in view of a 1 ton set-up. Even though these experiments do not have tracking capability, some space information and other tools help in reducing the background. An important asset is granularity, which is a major point for CUORE (array of 988 closely packed individual bolometers), MAJORANA (a set of modules with 57 closely packed individual Ge diodes per module) and the lower-energy-resolution experiment COBRA, discussed later (in the final desing, 64000 individual semiconductor detectors). Granularity provides a substantial background suppression thanks to the rejection of simultaneous events in different detector elements, which cannot be ascribed to a 0ν2β process. The way granularity is achieved in the three cases can be appreciated in fig. 5.

156

A. Giuliani

Fig. 5. – Three calorimetric searches exploit granularity to achieve background suppression.

Another tool which can improve the sensitivity of Ge-based calorimetric searches is pulse shape analysis, already used in the HM experiment with remarkable results. It is well known that in ionization detectors one can achieve spatial information looking at the pulse shape of the current pulse. This fact will be exploited in GERDA and in MAJORANA. Space resolution can be substantially improved by segmentation and pixellization of the readout electrodes in semiconductor detectors. A significant R&D activity on this subject is in progress in GERDA, MAJORANA and COBRA. Other techniques to suppress background in calorimetric detectors are sophisticated forms of active shielding. For instance, the operation of the GERDA Ge diodes in liquid argon opens the way, in a second phase of the experiment, to the use of the cryogenic liquid as a scintillating active shield. In bolometers, it was clearly shown that additional bolometric elements thermally connected to the main detector in the form of thin slabs can identify events due to surface contamination [28]. This is a particularly dangerous background source, presently the most limiting factor in the CUORE predicted performance, since surface α’s, degraded in energy, populate the spectral region of interest for 0ν2β decay. This shows that several refinements are possible in the high-energyresolution calorimetric experiments, and that an important R&D activity is mandatory to improve the sensitivity of next-generation experiments. A very promising development of the calorimetric approach realized by means of lowtemperature detectors consists in the realization of scintillating bolometers [29]. The simultaneous detection of heat and scintillation light for the same event allows to reject α particles with 100% efficiency, since the ratio between the photon and phonon yield

Neutrinoless double-beta decay: impact, status and experimental techniques

157

Fig. 6. – Scatter plot showing the light output as a function of the energy-calibrated heat output for events collected with a 140 g CdWO4 bolometer. The beta/gamma band is well separated from the alpha band. No signal appears in the beta band around 2802 keV, Q-value of 116 Cd.

is much lower for α than for γ and β interactions. This possibility becomes formidably promising when applied to candidates with a Q-value higher than 2.6 MeV, i.e. outside the natural gamma radioactivity range, since in this case α’s are the only really disturbing background sources. A complete elimination of α’s for these candidates could easily lead to specific background levels of the order of 10−4 –10−5 counts/keV/kg/y, one or two orders of magnitude better than the presently best estimations for future searches. A research program in this field, partially already accomplished, should therefore imply the identification of scintillating compounds of 48 Ca, 100 Mo, 116 Cd and 82 Se, their test as good bolometric materials and verification of the rejection efficiency. Promising compounds, already tested with success, are: PbMoO4 , CdWO4 , CaMoO4 , SrMoO4 , CaF2 and ZnSe. An impressive proof of the principle of this technique is reported in fig. 6. The second category of future experiments (calorimetric search with low energy resolution and no tracking capability) is represented by three samples which exploit different techniques and solve the low-energy-resolution problem with different measures: – XMASS [30] - 136 Xe Multipurpose scintillating liquid-Xe detector (dark matter, 0ν2β decay, solar neutrinos) to be installed in Kamioka, Japan Three development stages: 3 kg (prototype)-1 ton-10 tons 0ν2β option: low background in the MeV region A special test development is in progress with an eliptic water tank to shield highenergy gamma rays High light yield and collection efficiency can provide high energy resolution down to 1.4% (control of 2ν background)

158

A. Giuliani

Target: to cover inverted hierarchy with 10 ton natural or 1 ton enriched R&D phase for the 0ν2β decay version. – COBRA [31] - 116 Cd as competing candidate - 9ββ isotopes under test Array of 116 Cd-enriched CdZnTe semiconductor detectors at room temperature Final aim: 117 kg of 116 Cd with high granularity Small-scale prototype at LNGS, Italy Proved energy resolution: 1.9% FWHM R&D phase. – SNO++ [32] - 150 Nd SNO detector (Canada) filled with Nd-loaded liquid scintillator Crucial points: Nd enrichment and purity; 150 Nd nuclear matrix elements, whose calculation is made problematic by nucleus deformation 500 kg of isotope with a loading at 0.1% level would provide a sensitivity of 30 meV to mββ A very large statistics can compensate the low energy resolution R&D phase. – CANDLES [33] - 48 Ca Array of natural pure (not Eu doped) CaF2 scintillators Prove of principle completed (CANDLES I and II), with a prototype set-up in Kamkioka Next step (CANDLES III): 191 kg divided in 60 crystals read out by 40 PMT Further step (CANDLES IV: requires R&D): 6.4 tons divided in 600 crystals: 6.4 kg of 48 Ca Final goal (CANDLES V): 100 ton (speculated insertion in SNO or Kamland) Proved energy resolution: 3.4% FWHM (extrapolated from 9.1% at 662 keV) R&D phase. The good point of CANDLES is the high Q-value of 48 Ca: 4.27 MeV, out of γ (2.6 MeV end point), β (3.3 MeV end point) and α (max 2.5 MeV with quench) natural radioactivity. Other background cuts come from pulse shape analysis (α/β different timing) and space-time correlation for Bi-Po and Bi-Tl sequences. A further good point is the special arrangement of the scintillating crystals, which are surrounded by two liquid scintillators envelopes: an internal one which acts as a wavelength shifter for the UV light emitted by the CaF2 crystals; an external one which functions as a veto. The combination of all these features compensates for the lacking of high energy resolution and makes this technique potentially competitive. The third category comprises calorimetric experiments based on detectors which compensate the low energy resolution with tracking or some form of event-topology capability. There are two samples in this group:

Neutrinoless double-beta decay: impact, status and experimental techniques

159

– EXO [34] - 136 Xe TPC of enriched liquid xenon Event position and topology; in prospect, tagging of Ba single ion (2β decay daughter) Next step (EXO-200: funded, under construction): 200 kg of enriched xenon, located in the WIPP facility, US EXO-200 sensitivity to mββ : 270–380 meV Further steps: 1–10 ton Proved energy resolution: 3.3% FWHM (improved thanks to simultaneous measurement of ionization and light) In parallel with the EXO-200 development, R&D for Ba ion grabbing and tagging The [Ba++ e+ e− ] final state is identified through laser fluorescence of the Ba ion [35]. – NEXT [36] - 136 Xe 100 kg High Pressure Xenon TPC, to be located in CANFRANC, Spain - extension to 1 ton is technically possible Clear two-track signature is achievable, thanks to the use of gaseous rather than liquid Xe Estimated energy resolution of the order of 2% FWHM Projected sensitivity to mββ : 60 meV R&D phase. The fourth category is represented by set-ups with external source (which necessarily leads to low energy resolution) and sophisticated tracking capability, allowing to reach virtually zero background in the relevant energy region. Three projects belong to this class: – SUPERNEMO [37] - 82 Se or 150 Nd Modules with source foils, tracking (drift chamber in Geiger mode) and calorimetric (low-Z scintillator) sections-Magnetic field for charge sign It will take advantage from the NEMO3 experience Possible configuration: 20 modules with 5 kg source for each module, providing 100 kg of isotopes, in CANFRANC and/or FREJUS Energy resolution: 4% FWHM Advanced R&D phase. – MOON [38] - 100 Mo or 82 Se or 150 Nd Multilayer plastic scintillators interleaved with source foils + tracking section (PL fibers or MWPC) MOON-1 prototype without tracking section (2006) MOON-2 prototype with tracking section is in progress Proved energy resolution: 6.8% FWHM Final target: collect 5 y ton R&D phase.

160

A. Giuliani

– DCBA [39] - 82 Se or 150 Nd Momentum analyzer for beta particles consisting of source foils inserted in a drift chamber with magnetic field Prototype: Nd2 O3 foils with 2 g of 150 Nd Space resolution ∼ 0.5 mm; energy resolution 11% FWHM at 1 MeV, implying 6% FWHM at 3 MeV Final target: 10 modules with 84 m2 source foil per module (126 through 330 kg total mass) R&D phase. Two promising searches (SNO++ and SUPERNEMO, but also DCBA) depend critically on the possibility to enrich Nd in 150 Nd. A large-scale enrichment set-up is viable through laser isotope separation. This opportunity is under study in France, where a specific project aims at converting a dismissed facility for uranium to the enrichment of Nd [40]. 5. – Prospects and conclusions In the discussion of the prospects for 0ν2β search, it is important to extract from the list examined above those experimental efforts which are in the construction phase (or at least in an advanced R&D phase), and have an approved location, a well-established international collaboration and a reliable financial support from important national funding agencies. If this selection is made, very few projects seem to be now in the position to impact substantially in the future of 0ν2β decay search: CUORE, GERDA, EXO-200, SUPERNEMO and possibly SNO++, if the Nd enrichment is feasible. However, it is not possible to exclude rapid developments of the present R&D programs towards real experiments. The continuation of the R&D activity is crucial, since the future of the search depends critically on the richness and variety of the technologies under development, which can lead to further increases of the sensitivities and to the possibility to study many isotopes with different approaches, essential elements in the medium-long term prospects for 0ν2β decay. The future scenario of double-beta decay depends on the choice made by Nature on the neutrino mass pattern. . 5 1. Quasi degenerate neutrino mass pattern. – In case of QD pattern, i.e. mββ in the range 100–500 meV (this would be in agreement with the 76 Ge claim), we expect the following developments: – GERDA will detect 0ν2β decay in statistics in phase II.

76

Ge, marginally in phase I and with high

– CUORE will detect it in 130 Te and would be technically able to proceed to multiisotope searches simultaneously in a second phase (130 Te-116 Cd-100 Mo) if a large scale enrichment is funded.

161

Neutrinoless double-beta decay: impact, status and experimental techniques

– SUPERNEMO may investigate the mechanism looking at the single electron energy spectrum and at the electron angular distribution in 82 Se or in 150 Nd. – EXO-200 will detect 0ν2β decay in

136

Xe.

– SNO++, if done, could detect 0ν2β decay in

150

Nd.

The redundancy in the candidate with positive observation will help in reducing the uncertainties coming from nuclear matrix element calculation: we would enter the precision measurement era for 0ν2β decay! . 5 2. Inverted Hierarchy neutrino mass pattern. – In case of IH pattern, i.e. mββ in the range 15–50 meV, detection is still possible in the middle term, under the condition that the projects under development achieve the planned sensitivity: – CUORE could detect 0ν2β decay in a couple of isotopes in sequence (after 116 Cd is the most viable candidate, in the scintillating bolometer option). – SUPERNEMO could marginally detect it in – SNO++, if done, could detect it in

150

82

Se or

150

130

Te,

Nd.

Nd.

– GERDA phase III, after merging with MAJORANA, could detect it in

76

Ge.

The discovery in 3 or 4 isotopes is necessary for a convincing evidence, and it is still possible thanks to the variety of projects and techniques under development. . 5 3. Directed Hierarchy neutrino mass pattern. – In case of DH pattern, i.e. mββ in the range 2–5 meV, new strategies have to be developed. Just to give an idea of the size of the dificulty, in this range we expect something like 1–10 counts in 5 years for several tens of tons of isotopes. That means that the most sensitive searches planned today should be expanded by about a factor 100, in 0 background condition! At the moment, no viable solution is conceivable. However, given the importance of the subject, the brains of the experimental physicists are at work, and the running R&D searches are very important to stimulate new ideas in view of this extreme challenge. REFERENCES Hannestad S., Annu. Rev. Nucl. Part. Sci., 56 (2006) 137. Avignone F. T., Elliot S. R. and Engel J., Rev. Mod. Phys., 80 (2008) 481. Otten E. V. and Weinheimer C., Rep. Prog. Phys., 71 (2008) 086201. ¨ ssler A. and Simkovic F., Phys. Rev. D, 70 (2004) 033003. Bilenky S. M., Fa Fiorini E. and Niinikoski T. O., Nucl. Instrum. Methods Phys. Res. A, 224 (1984) 83. Dell’Antonio G. F. and Fiorini E., Suppl. Nuovo Cimento, 17 (1960) 132. Rodin V. A., Faessler A., Simkovic F. and Vogel P., Nucl. Phys. A, 766 (2006) 107; Nucl. Phys. A, 793 (2007) 213. [8] Kortelainen M. and Suhonen J., Phys. Rev. C, 75 (2007) 051303. [9] Caurier E., Nowacki F. and Poves A., Eur. Phys. J. A, 36 (2008) 195. [1] [2] [3] [4] [5] [6] [7]

162

A. Giuliani

[10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23]

Arnaboldi C. et al., Phys. Rev. C, 78 (2008) 035502. Barabash A. S. et al.,, e-print arXiv:hep-ex/0610025, 2006. Klapdor-Kleingrothaus H. V. et al., Eur. Phys. J. A, 12 (2001) 147. Aalseth C. E. et al., Phys. Rev. D, 65 (2002) 092007. Arnaboldi C. et al., Phys. Lett. B, 557 (2003) 167. Bernabei R. et al., Phys. Lett. B, 546 (2002) 23. Danevich F. A. et al., Phys. Rev. C, 68 (2003) 035501. Ejiri H. et al., Phys. Rev. C, 63 (2001) 065501. Klapdor-Kleingrothaus H. V. et al., Mod. Phys. Lett. A, 16 (2001) 2409. Aalseth C. E. et al., Mod. Phys. Lett. A, 17 (2002) 1475. Belyaev S. T. et al., presented at NANP2003, Dubna, Russia, June 23–28, 2003. Feruglio F., Strumia A. and Vissani F., Nucl. Phys. B, 637 (2002) 345. Zdesenko Yu. G. et al., Phys. Lett. B, 546 (2002) 206. Klapdor-Kleingrothaus H. V. et al., Phys. Lett. B, 586 (2004) 198; KlapdorKleingrothaus H. V. and Krivosheina I. V., Mod. Phys. Lett. A, 21 (2006) 1547. Giuliani A., Physica B, 280 (2000) 501. Ardito R. et al., e-print arXiv:hep-ex/0501010, 2005. ¨ nert S. et al., Nucl. Phys. B, Proc. Suppl., 145 (2005) 242. Scho Gaitskell R. et al., e-print arXiv:nuclex/0311013, 2003. Foggetta L. et al., Appl. Phys. Lett., 86 (2005) 134106. Pirro S. et al., e-print arXiv:nucl-ex/0510074, 2005. Takeuchi Y., ICHEP 04, Proceedings of the 32nd International Conference on High Energy Physics (World Scientific, Singapore) 2004. Zuber K., Phys. Lett. B, 519 (2001) 1. Chen M., Nucl. Phys. B, Proc. Suppl., 145 (2005) 65. Umehara S. et al., J. Phys.: Conf. Ser., 39 (2006) 356. Danilov M. et al., Phys. Lett. B, 480 (2000) 12. Neuhauser W. et al., Phys. Rev. A, 22 (1980) 1137; Moe M. K., Phys. Rev. C, 44 (1991) R931. Gomez Cadenas J. J. et al., NEXT, poster presented at Neutrino 2008, Christchurch, New Zealand, May 25–31, 2008. Barabash A. S. et al., Phys. At. Nucl., 67 (2004) 1984. Nakamura H. et al., J. Phys. Soc. Jpn., 76 (2007) 11420. Ishihara N. et al., Nucl. Instrum. Methods Phys. Res. A, 443 (2000) 101. See, for example, Augier C., Jullian S. and Lalanne D., Technical report describing AVLIS techniques applied to Nd isotopic enrichment, in ILIAS annual report, JRA2 (IDEA) section, 2008.

[24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40]

DOI 10.3254/978-1-60750-038-4-163

Deformation and the nuclear matrix elements of the neutrinoless ββ decay ´ndez and A. Poves J. Mene Departamento de F´ısica Te´ orica and IFT-UAM/CSIC, Universidad Aut´ onoma de Madrid E-28049, Madrid, Spain

E. Caurier and F. Nowacki IPHC, IN2P3-CNRS/Universit´ e Louis Pasteur - BP 28, F-67037, Strasbourg Cedex 2, France

Summary. — In this paper we will review the “state of the art” of the calculations of the nuclear matrix element (NME) of the neutrinoless double-beta decays (0νββ) for the nuclei 48 Ca, 76 Ge, 82 Se, 124 Sn, 128 Te, 130 Te and 136 Xe in the framework of the Interacting Shell Model (ISM), and compare them with the NME’s obtained using the Quasi-particle RPA approach (QRPA). We will also discuss the effect of the competition between the pairing and quadrupole correlations in the value of these NME’s. In particular we will show that, as the difference in deformation between parent and grand-daughter grows, the NME’s of both the neutrinoless and the two neutrino modes decrease rapidly.

1. – Introduction The discovery of neutrino oscillations in recent experiments at Super-Kamiokande [1], SNO [2] and KamLAND [3] has changed the old conception of neutrinos by proving that they are massive particles. According to the origin of their mass, neutrinos can be either Dirac or Majorana particles, the latter case being particularly interesting since it c Societ`  a Italiana di Fisica

163

164

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene

would imply an extension to the standard model of electroweak interactions, and, being neutrinos their own antiparticles in this scenario, lepton number conservation would be broken. Besides, it happens that the best way to detect one of these violating processes and consequently establish the Majorana character of the neutrinos would be detection of the neutrinoless double-beta decay (0νββ). Double-beta decay is a very slow weak process. It takes place between two even-even isobars when the single-beta decay is energetically forbidden or hindered by large spin difference. Two neutrinos beta decay is a second-order weak process —the reason of its low rate— and has been measured in a few nuclei. The 0νββ decay is analogous but needs neutrinos to be Majorana particles. With the exception of one unconfirmed claim [4, 5], it has never been observed, and currently there is a number of experiments either taking place [6-8] or expected for the near future —see, e.g., ref. [9]— devoted to detect this processes and to set up firmly the nature of neutrinos. Furthermore, 0νββ decay is also sensitive to the absolute scale of neutrino mass, and hence to the mass hierarchy —at present, only the difference between different mass eigenstates is known. Since the half-life of the decay is determined, together with the masses, by the nuclear matrix element (NME) for this process, the knowledge of these NME’s is essential to predict the most favorable decays and, once detection is achieved, to settle the neutrino mass scale and hierarchy. Two different and complementary methods are mainly used to calculate NME’s for 0νββ decays. One is the family of the quasiparticle random-phase approximation (QRPA). This method has been used by different groups and a variety of techniques is employed, with results for most of the possible emitters [10-12]. This work concerns the alternative, the interacting shell model (ISM) [13]. In previous works [14, 15], the NME’s for the 0νββ decay were calculated taking into account only the dominant terms of the nucleon current. However, in ref. [16] it was noted that the higher-order contributions to the current (HOC) are not negligible and it was claimed that they could reduce up to 20%–30% the final NME’s. Subsequently, other QRPA calculations [17, 18] have also taken into account these terms, although resulting in a somewhat smaller correction. These additional nucleon current contributions have been recently included for the first time in the ISM framework [19]. In addition, the short-range correlations (SRC) are now modeled either by the Jastrow prescription or by the UCOM method [20]. 2. – ISM vs. QRPA nuclear matrix elements The expression for the half-life of the 0νββ decay can be written as [21, 22]   −1  2 mν  2 0νββ + T1/2 (0 → 0+ ) = G01 M 0νββ  , me

 (1) where mν  = |

 k

2 Uek mk | is the averaged neutrino mass, a combination of the neutrino

Deformation and the nuclear matrix elements of the neutrinoless ββ decay

165

7 JY07 TU07 ISM

6

M'

0νββ

5 4 3 2 1 48

76

82

124 A

128

130

136

Fig. 1. – The neutrinoless double-beta decay M  0νββ ’s for ISM and QRPA calculations treating the SRC with the UCOM approach. Tu07 QRPA results from ref. [23] and Jy07 results from refs. [17, 18].

masses mk due to the neutrino mixing matrix U —as we see, the neutrino mass scale is directly related to the decay rate— and G01 is a kinematic factor —dependent on the charge, mass and available energy of the process. M 0νββ is the NME object of study in this work. The kinematic factor G01 depends on the value of the coupling constant gA . Therefore we have to take this into account when comparing the values of NME’s obtained with different gA values. In these cases we will use a NME modified as (2)

M  0νββ =

 g 2 A M 0νββ . 1.25

These M  0νββ ’s are directly comparable between them no matter which was the value of gA employed in their calculation, since they share a common G01 factor —that of gA = 1.25. In this sense, the translation of M  0νββ ’s into half-lives is transparent. The QRPA results obtained with different gA values are already expressed in this way by the authors of refs. [23, 12] while the results of refs. [17, 18, 24] will be translated by us into the above form when compared with other results. We have calculated the ISM NME’s both taking the UCOM and Jastrow ansatzs for the short-range correlations. The former use the correlator of the ST = 01 channel [25], throughout the calculation. The correlator of the other important —even— channel is very similar to this one, and it should not make much difference on this result. In fig. 1 the ISM and QRPA results for the NME’s are compared within this UCOM treatment of the SRC. The same figure but considering Jastrow-type SRC was shown in ref. [19], but, inadvertently, the QRPA results from refs. [17, 18, 24] obtained with gA = 1.0 where not transformed properly. This is corrected in fig. 2. By comparing both

166

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene

JY07 TU07 ISM

5

M'0νββ

4 3 2 1 48

76

82

124 A

128

130

136

Fig. 2. – Same as fig. 1 but with Jastrow-type SRC. Tu07 QRPA results from ref. [12] and Jy08 results from ref. [24].

figures, it is confirmed that there is a common trend; when the nuclei that participate in the decay have a low level of quadrupole correlations, as in the decays of 124 Sn and 136 Xe, both approaches agree. The QRPA in a spherical basis seems not to be able to capture the totality of the quadrupole correlations when they are strong. As these correlations tend to reduce the NME’s, the QRPA produces NME’s that are too large in 76 Ge, 82 Se, 128 Te, and 130 Te. For both ISM and QRPA the only net effect of UCOM is an increase of the Jastrow results of about 20%. 3. – The influence of deformation in the NME’s An important issue regarding 0νββ decay is the role of pairing and deformation. It has recently been discussed in ref. [19] that the pairing interaction favors the 0νββ decay and that, consequently, truncations in seniority, not including the anti-pairing-like effect of the missing uncoupled pairs, tend to overestimate the value of the NME’s. On the other hand, the NME is also reduced when the parent and grand-daughter nuclei have different deformations [26]. Thus, we have studied the interplay between both pairing and deformation, this is, to which extent a wave function in the laboratory frame, truncated in seniority, can capture the correlations induced by the quadrupole-quadrupole part of the nuclear interaction, and its eventual influence in 0νββ NME’s. There is an extra motivation to pursue this study; the possibility to carry on an experiment with 150 Nd, which is a well-deformed nuclei, decaying into 150 Sm which is a much less deformed one. To study the interplay between pairing, seniority truncations, and quadrupole correlations, we need first to decide how to measure the quadrupole correlations of the ground state. Our choice is to refer to non-energy-weighted sum rule (3)

Q2  =

 i

+ 2 |2+ i |Q|0 | .

Deformation and the nuclear matrix elements of the neutrinoless ββ decay

λ=0 λ=1 λ=2

2000

2

4

(fm )

3000

167

1000

0 0

4

sm

8

12

Fig. 3. – Quadrupole correlations in the ground state of 82 Kr as a function of the amount of quadrupole-quadrupole interaction λQ · Q added to the Hamiltonian and of the maximum seniority sm permitted in the wave functions.

The operator Q represents the mass quadrupole. No effective “nuclear” charges are included. Using 82 Kr as our test bench, we proceed to compute Q2 , first with our standing effective interaction and different seniority truncations (sm means the maximum seniority allowed in the wave functions of parent and grand-daughter nuclei). The results are drawn in fig. 3 as the black circles labeled λ = 0. We can see that at sm = 4 —roughly, the implicit level of seniority truncation in the spherical QRPA— some 70% of the full quadrupole correlations are incorporated in the wave function. We would like to know how this behavior evolves when more correlations are enforced in the system. For this we recalculate the ground state of 82 Kr with a new Hamiltonian that consists of the standing one plus a quadrupole-quadrupole term λQ · Q, whose effect will be gauged by its influence in the sum rule. To have an idea of the relevant range of values of Q2  in this nucleus and valence space, we have gone to the limit of pure quadrupole-quadrupole interaction with degenerate single-particle energies, getting Q2  ≈ 4500 fm4 . The results for λ = 1 and λ = 2 are also shown in fig. 3 (λ = 1 corresponds to λqq = 0.025 in figs. 6-9 and λqq = 1 in fig. 10 to λqq = 0.1). It is evident in the figure that, as we try to increase the correlations, the sm = 4 truncation becomes more and more ineffective. For λ = 1, only 57% of the full correlations are present, and for λ = 2 only 50%. The situation is different for 82 Se: while for λ = 0 the values of Q2  as a function of seniority are similar, albeit a bit smaller than the 82 Kr ones, for λ = 1 and λ = 2 there is scarcely any increase of the ground-state correlations. This means also that, as we increase λ, the “deformation” of 82 Kr grows, whereas that of 82 Se remains constant. This behavior offers us the opportunity of exploring the effect of the difference in deformation between parent and grand-daughter in the 0νββ NME’s. To this goal, we have computed the Gamow-Teller matrix element for different values of λ —the amount of extra quadrupole-quadrupole interaction— and sm —the maximum seniority allowed in the wave function. The results are gathered in fig. 4. For sm = 0, we observe that the

168

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene 8

sm=0 sm=4 sm=8 sm=12

MGT(0ν)

6

4

2

0

0

1

λ

2

Fig. 4. – 82 Se → 82 Kr Gamow-Teller matrix element, M GT , as a function of the maximum seniority of the wave functions, for different values of the strength of the extra quadrupolequadrupole interaction.

Gamow-Teller matrix element grows as a function of λ. This may seem paradoxical, but is not, because at this seniority truncation, the only effect of adding more quadrupolequadrupole interaction is to augment the pairing content of the wave functions, thus increasing M GT . At sm = 4, M GT remains constant as a function of λ, meaning that the minor increase of the correlations of 82 Kr, that we have shown in fig. 3, is barely enough to compensate the increase of M GT at sm = 0. On the contrary, the full space results are sensitive to the difference in deformation —or, to be more precise, to the difference in the level of quadrupole correlations in the ground state— between parent and grand-daughter. The effect goes in the direction of reducing the value of M GT . In the A = 82 decay, doubling the quadrupole correlations in 82 Kr, roughly halves M GT . We can go much further in the exploration of the deformation effects, calculating the NME of the decay for initial and final states computed with different amounts of supplementary quadrupole-quadrupole interaction. As before, we measure the quadrupole correlations by means of the mass quadrupole sum rule. The results of this search are plotted in fig. 5. We observe that the NME decreases almost linearly as the difference of the sum rules for the final and initial states increases. In fact, the maximum values of the NME are reached when this difference is close to zero. On the contrary for large differences the NME can be extremely quenched. Notice that the values in the figure range between 0.07 and 2.7, a factor of 40 span. The λ = 0 value is 2.18, indicating that the difference in quadrupole correlations between 82 Kr and 82 Se is not very large. 4. – 0ν (unphysical) mirror decays: a case study We have also studied the transitions between mirror nuclei in order to have a clearer view of the role of deformations in the NME’s. These transitions have the peculiarity that the wave functions of the initial and final nuclei are identical (provided Coulomb

Deformation and the nuclear matrix elements of the neutrinoless ββ decay

169

4

(Kr) - (Se) (in fm )

3000

2000

2

2

2

1000

0

-1000 0

1860=(Kr) 2480 2945 3160 3300 3620 1010 550 0.5

1

1.5

2

2.5

0ν

M

Fig. 5. – 82 Se → 82 Kr NME, M 0ν , as a function of the difference between the mass quadrupole sum rule between 82 Kr and 82 Se for a large number of different values of the strength of the added quadrupole-quadrupole interaction.

effects are neglected) and consequently the interplay of the 0νββ operator and of the nuclear wave functions in the NME may be easier to understand. We have studied four parent nuclei with six valence protons and four valence neutrons, 26 Mg, 50 Cr, 66 Ge and 110 Xe, decaying into the four grand-daughter nuclei with four valence protons and six valence neutrons, 26 Si, 50 Fe, 66 Se and 110 Ba. The valence spaces considered are the sd-shell, the pf -shell, r3 g (1p3/2 , 1p1/2 , 0f5/2 , 0g9/2 ) and r4 h (0g7/2 , 1d5/2 , 1d3/2 , 2s1/2 , 0h11/2 ). The starting interactions are USD [27], KB3 [28], GCN28.50 and GCN50.82 [29]. The deformation of the nuclei is modified as in the previous section, and it is quantified also in the same way. The results for A = 66 in the case of equally deformed initial and final nuclei are shown in fig. 6. There we see that, as the nuclei become more deformed, the NME and the pairing content of the wave function get smaller, while the quadrupole sum rule grows. All these changes are nearly linear for reasonable deformations and then the saturation is approached more smoothly. Note that the purely quadrupole interaction (λqq → ∞ limit) gives a NME which is about a half of the value obtaind with no additional quadrupole. Figure 7 shows the same quantities as fig. 6 but now only the final nucleus has been artificially deformed by adding an extra quadrupole-quadupole term. In addition, the overlap between initial and final wave functions has been included. We see that now, the reduction of the NME is more pronounced and, what is more interesting, that it follows closely the overlap between wave functions. This means that, if we write the final wave function as |Ψ = a|Ψ0  + b|Ψqq , the 0νββ operator only connects the parts of the wave functions that have the same deformation among themselves. The behavior of the NME’s with respect to the difference of deformation between parent and grand-daughter is common to all the other transitions between mirror nuclei that we have studied. Therefore we can submit that this is a robust result. However, when we consider the transitions between equally deformed nuclei, the evolution of the

170

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene 5 1 4.5 0.9

NME

0.8 3.5 0.7

,<pair>

4

3 0.6 NME <pair>

2.5

0.5

2 0

0.05

0.1

0.15

λqq

0.2

0.6

1

1.4

Fig. 6. – 66 Ge → 66 Se NME, M 0ν , as a function of the strength of the added quadrupole-quadrupole interaction. Equally deformed case; the same amount of extra QQ interaction is added to 66 Ge and 66 Se. On the right-hand y axis the pairing and quadrupole sum rules are represented, normalized so that their maximum value is 1. Note the change of scale in the x-axis at λ = 0.2.

NME’s with the deformation that we have found in A = 66 is only shared by the A = 110 case. When the valence space is a full major oscillator shell —A = 26 and A = 50— the situation is quite different. Indeed, what is observed is that the NME does not decrease for moderate values of λ but remains rather constant until a point —with large deformation— where its value increases significantly —up to 50%. This is due to the 5

4

0.8

3 NME

0.6

2

0.4 NMEnondiag <pair>

1

,<pair>,

1

0.2

0

0 0

0.05

0.1

0.15

λqq

0.2

0.6

1

1.4

Fig. 7. – Same as the previous figure, but now the additional quadrupole interaction is only added to 66 Se. The normalized overlap between the initial and final states is also included.

Deformation and the nuclear matrix elements of the neutrinoless ββ decay

171

1 0.9

0.25

0.8 0.7 0.6 0.15

0.5

0.1

2ν NME

0.05

<pair>

0.4

,<pair>

2ν NME

0.2

0.3 0.2 0.1

0

0 0

Fig. 8. – Equally deformed λ = 0.2.

66

0.05

0.1

Ge →

66

0.15

λqq

0.2

0.6

1

1.4

Se 2νNME. Note the change of scale in the x axis at

fact that, at this point, the major contribution to the NME ceases to come only form the decay of pairs coupled to J = 0, since other values like J = 2, 4, 6, which usually have a contribution to the NME contrary to that of J = 0, reverse sign and grow until being comparable with this contribution, thus resulting in this notorious rise of the NME. In the sd-shell and pf -shell cases, the λqq → ∞ limit is equivalent to Elliott’s SU (3) limit, and the fact that both the initial and final nuclei should belong to the same irrep of SU (3) may be the reason of the increase of the NME, but, for the moment we have not found a formal explanation. 5. – 2ν (unphysical) mirror decays: a case study Very similar conclusions may be reached for the effect of deformation in 2νββ decay. For instance, the mirror nuclei diagonal and non-diagonal NME’s are represented as in the 0νββ case in figs. 8 and 9 for the A = 66 transition. We see that the figures resemble very much that of the previous section, with the only exception that, in the equally deformed case, the lowering of the NME due to deformation is more pronounced. If we look to a non-mirror —but again fictitious— transition, for instance that of 48 Ti → 48 Cr, we get the results shown in fig. 10. If we compare with those of ref. [26], which are again the equivalent ones for the 0νββ transition, we see that there are not substantial changes. In this sense, deformation seems to affect similarly 0νββ and 2νββ decays. 6. – Summary After a brief discussion of the “state of the art” results for the nuclear matrix elements of the neutrinoless double beta decay in the context of the Interacting Shell Model and

172

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene 1

0.8

2ν NME

0.2 0.6 0.15

0.1

2ν NMEnondiag

0.05

<pair>

0.4

,<pair>,

0.25

0.2

0

0 0

0.05

0.1

0.15

λqq

0.2

0.6

1

1.4

Fig. 9. – The same as the previous figure, but now the only nucleus calculated with additional quadrupole interaction is the final one. The normalized overlap between initial and final states is also included. 0.4

λ qq(Cr)=-2 λ qq(Cr)=0 λ qq(Cr)=+2

MGT

2ν

0.3

0.2

0.1 -2

-1

Fig. 10. – Influence of deformation in the

48

0

λ qq(Ti)

1

2

Ti → 48 Cr decay.

of the Quasiparticle Random Phase Approximation, we have analyzed the role of the pairing correlations and the deformation in the NME’s, concluding that seniority truncations are less reliable when the quadrupole correlations are large. Since the NME’s are reduced when the deformation of parent and grand-daughter is different, a bad treatment of the quadrupole correlations can lead to an artificial enhancement of the NME’s in the transitions among nuclei with unequal deformations, or in the cases of nuclei with different —and large— amounts of quadrupole correlations.

Deformation and the nuclear matrix elements of the neutrinoless ββ decay

173

∗ ∗ ∗ This work has been supported by a grant of the Spanish Ministry of Education and Science, FPA2007-66069, by the IN2P3-CICyT collaboration agreements, by the Spanish Consolider-Ingenio 2010 Program CPAN (CSD2007-00042), and by the Comunidad de Madrid (Spain), project HEPHACOS P-ESP-00346. REFERENCES [1] Fukuda Y., Hayakawa T., Ichihara E., Inoue K., Ishihara K., Ishino H., Itow Y., Kajita T., Kameda J., Kasuga S., Kobayashi K., Kobayashi Y., Koshio Y., Miura M., Nakahata M., Nakayama S., Okada A., Okumura K., Sakurai N., Shiozawa M., Suzuki Y., Takeuchi Y., Totsuka Y., Yamada S., Earl M., Habig A. and Kearns E., Phys. Rev. Lett., 81 (1998) 1562. [2] Ahmad Q. R., Allen R. C., Andersen T. C., D. Anglin J., Barton J. C., Beier E. W., Bercovitch M., Bigu J., Biller S. D., Black R. A., Blevis I., Boardman R. J., Boger J., Bonvin E., Boulay M. G., Bowler M. G., Bowles T. J., Brice ¨hler G., Cameron J., Chan Y. D., Chen S. J., Browne M. C., Bullard T. V., B u H. H., Chen M., Chen X. and Cleveland B. T., Phys. Rev. Lett., 89 (2002) 011301. [3] Eguchi K., Enomoto S., Furuno K., Goldman J., Hanada H., Ikeda H., Ikeda K., Inoue K., Ishihara K., Itoh W., Iwamoto T., Kawaguchi T., Kawashima T., Kinoshita H., Kishimoto Y., Koga M., Koseki Y., Maeda T., Mitsui T., Motoki M., Nakajima K., Nakajima M., Nakajima T., Ogawa H., Owada K., Sakabe T. and Shimizu I., Phys. Rev. Lett., 90 (2003) 021802. [4] Klapdor-Kleingrothaus H. V., Dietz A., Harney H. L. and Krivosheina I. V., Mod. Phys. Lett. A, 16 (2001) 2409. [5] Klapdor-Kleingrothaus H. V., Krivosheina I. V., Dietz A. and Chkvorets O., Phys. Lett. B, 586 (2004) 198. [6] Arnold R., Augier C., Baker J., Barabash A., Broudin G., Brudanin V., Caffrey A. J., Caurier E., Egorov V., Errahmane K., Etienvre A. I., Guyonnet J. L., Hubert F., Hubert P., Jollet C., Jullian S., Kochetov O., Kovalenko V., Konovalov S., Lalanne D., Leccia F., Longuemare C., Lutter G., Marquet C., Mauger F., Nowacki F., Ohsumi H., Piquemal F., Reyss J. L., Saakyan R., Sarazin X., Simard L., Simkovic F., Shitov Y., Smolnikov A., Stekl L., Suhonen J., Sutton C. S., Szklarz G., Thomas J., Timkin V., Tretyak V., Umatov V., Vala L., Vanushin I., Vasilyev V., Vorobel V. and Vylov T., Phys. Rev. Lett., 95 (2005) 182302. [7] Arnaboldi C., Artusa D. R., Avignone F. T., Balata M., Bandac I., Barucci M., Beeman J. W., Brofferio C., Bucci C., Capelli S., Carbone L., Cebrian S., Cremonesi O., Creswick R. J., de Waard A., Farach H. A., Fiorini E., Frossati G., Guardincerri E., Giuliani A., Gorla P., Haller E. E., McDonald R. J., Morales A., Norman E. B., Nucciotti A., Olivieri E., Pallavicini M., Palmieri E., Pasca E., Pavan M., Pedretti M., Pessina G., Pirro S., Previtali E., Risegari L., Rosenfeld C., Sangiorgio S., Sisti M., Smith A. R., Torres L. and Ventura G., Phys. Rev. Lett., 95 (2005) 142501. [8] Bloxham T., Boston A., Dawson J., Dobos D., Fox S. P., Freer M., Fulton ¨ ssling C., Harrison P. F., Junker M., Kiel H., McGrath J., Morgan B. R., Go ¨nstermann D., Nolan P., Oehl S., Ramachers Y., Reeve C., Stewart D., B., Mu Wadsworth R., Wilson J. R. and Zuber K., Phys. Rev. C, 76 (2007) 025501.

174

´ndez, A. Poves, E. Caurier and F. Nowacki J. Mene

[9] [10] [11] [12] [13]

Avignone F. T., Elliott S. R. and Engel J., Rev. Mod. Phys., 80 (2008) 481. Suhonen J. and Civitarese O., Phys. Rept., 300 (1998) 123. Rodin V. A., Faessler A., Simkovic F. and Vogel P., Nucl. Phys. A, 766 (2006) 107. Rodin V. A., Faessler A., Simkovic F. and Vogel P., Nucl. Phys. A, 793 (2007) 213. Caurier E., Martinez-Pinedo G., Nowacki F., Poves A. and Zuker A. P., Rev. Mod. Phys., 77 (2005) 427. Retamosa J., Caurier E. and Nowacki F., Phys. Rev. C, 51 (1995) 371. Caurier E., Nowacki F., Poves A. and Retamosa J., Phys. Rev. Lett., 77 (1996) 1954. Simkovic F., Pantis G., Vergados J. D. and Faessler A., Phys. Rev. C, 60 (1999) 055502. Kortelainen M. and Suhonen J., Phys. Rev. C, 75 (2007) 051303. Kortelainen M. and Suhonen J., Phys. Rev. C, 76 (2007) 024315. Caurier E., Menendez J., Nowacki F. and Poves A., Phys. Rev. Lett., 100 (2008) 052503. Feldmeier H., Neff T., Roth R. and Schnack J., Nucl. Phys. A, 632 (1998) 61. Doi M., Kotani T., Nishiura H., Okuda K. and Takasugi E., Phys. Lett. B, 103 (1981) 219. Doi M., Kotani T. and Takasugi E., Prog. Theor. Phys. Suppl., 83 (1985) 1. Simkovic F., Faessler A., Rodin V. A., Vogel P. and Engel J., Phys. Rev. C, 77 (2008) 045503. Suhonen J. and Kortelainen M., Int. J. Mod. Phys. E, 17 (2008) 1. Roth R., Hergert H., Papakonstantinou P., Neff T. and Feldmeier H., Phys. Rev. C, 72 (2005) 034002. Caurier E., Nowacki F. and Poves A., Eur. Phys. J. A, 36 (2008) 195. Wildenthal B. H., Prog. Part. Nucl. Phys., 11 (1984) 5. Poves A. and Zuker A., Phys. Rep., 70 (1981) 235. Gniady A., Caurier E. and Nowacki F., to be published.

[14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29]

DOI 10.3254/978-1-60750-038-4-175

Charge-exchange reactions and nuclear matrix elements for ββ decay D. Frekers Institut f¨ ur Kernphysik, Westf¨ alische Wilhelms-Universit¨ at - D-48149 M¨ unster, Germany

Summary. — Charge-exchange reactions of (n, p) and (p, n) type at intermediate energies are a powerful tool for the study of nuclear matrix element in ββ decay. The present paper reviews some of the most recent experiments in this context. Here, the (n, p) type reactions are realized through (d, 2 He), where 2 He refers to two protons in a singlet 1 S0 state and where both of these are momentum analyzed and detected by the same spectrometer and detector. These reactions have been developed and performed exclusively at KVI, Groningen (NL), using an incident deuteron energy of 183 MeV. Final-state resolutions of about 100 keV have routinely been available. On the other hand, the (3 He, t) reaction is of (p, n) type and was developed at the RCNP facility in Osaka (JP). Measurements with an unprecedented high resolution of 30 keV at incident energies of 420 MeV are now readily possible. Using both reaction types, one can extract the Gamow-Teller transition strengths B(GT+ ) and B(GT− ), which define the two “legs” of the ββ decay matrix elements for the 2νββ decay. The high-resolution available in both reactions allows a detailed insight into the excitations of the intermediate odd-odd nuclei and, as will be shown, some unexpected features are being unveiled.

1. – Charge-exchange reactions Charge-exchange reactions of (p, n) and (n, p) type at intermediate energies and at forward angles, i.e., low momentum transfers (qtr ∼ 0 and ΔL = 0), selectively excite c Societ`  a Italiana di Fisica

175

176

D. Frekers

GT transitions owing to the dominance of the Vστ component of the effective interaction [1-4]. However, experiments which employ the elementary (p, n) and (n, p) reactions have rather limited resolution and alternatives to them have now successfully been established through the (n, p)-type (d, 2 He) or (t, 3 He) reactions and the (p, n)-type (3 He, t) reaction. These have been performed at the Kernfysisch Versneller Instituut (KVI), Groningen [5, 6], at the National Superconducting Cyclotron Laboratory at Michigan State University [7], and at the Research Center for Nuclear Physics (RCNP), Osaka [8,9]. Resolutions on the order of 100 keV in the case of (d, 2 He), 190 keV for (t, 3 He) and 30 keV for (3 He, t) have routinely been achieved. The high resolution of 30 keV using a 420 MeV 3 He beam for the (3 He, t) reaction at the RCNP and of 100 keV using a 180 MeV d beam for the (d, 2 He) reaction at the KVI is unprecedented and unique in the world. It allows one to obtain detailed and much warranted information about the nuclear structure that is relevant for the 2νββ decay as well as (though to a lesser extent) for the 0νββ decay. This has recently been exemplified in the cases of 48 Ca 116 Cd and 64 Zn [10-13]. A more recent experiment at RCNP centered around 76 Ge, 82 Se, 96 Zr and 100 Mo has produced results which give even more importance to the high resolution. In the present context it may first be instructive to recall the connection between the 2νββ-decay rate Γ(β2ν− β − ) and the GT transition strength B(GT):    (2ν) 2 Γ(β2ν− β − ) = G2ν (Q, Z) MDGT  .

(1)

G2ν (Q, Z) is a phase-space factor depending on the Q-value of the reaction and the Z-value of the decaying nucleus. It further contains the weak interaction coupling constant. The 2νββ decay matrix element can be deduced by combining GT+ and GT− distributions in the following way: (2)

(2ν) MDGT

=

 )  − + − (i) +  0(f g.s. || k σk τk ||1m 1m || k σk τk ||0g.s.  m

=

 m

(3)

B(GT± ) =

1/ Q (0(f ) ) 2 ββ g.s. +

+ Ex (1+ m ) − E0 −

GT GT Mm · Mm 1/ Q (0(f ) ) 2 ββ g.s.

+ Ex (1+ m ) − E0

± 1 |M GT |2 . 2Ji + 1

1+ state and Here, E(1+ m ) − E0 is the energy difference between the m-th intermediate  the initial ground state, Qββ the Q-value of the ββ decay, and the sum k runs over all the neutrons of the decaying nucleus. In this formula the only unknowns are the GamowTeller transition strength values B(GT), which are the quantities to be extracted from the charge-exchange reactions. Of course, the 0νββ decay is potentially the most interesting one, because in weak-interaction gauge theories it requires the neutrino to be a massive Majorana particle

Charge-exchange reactions and nuclear matrix elements etc.

177

irrespective of the mechanism which drives the decay [14]. Its decay rate is given as (4)

Γ(β0ν− β − )

=G

0ν

 2  (0ν) gV (0ν)   (Q, Z) MDGT − M mνe 2 . gA DF 

G0ν (Q, Z) is in general a more favorable phase-space factor than the one in 2νββ mode, (0ν) (0ν) although it only scales with Q5 . The quantities MDGT and MDF are generalized GamowTeller and Fermi matrix elements for 0νββ decay, and mνe  is the effective Majorana neutrino mass given as     (5) mνe  =  Uei2 mi  . i

The Uei are the elements of the mixing matrix containing two mixing angles θ12 and θ13 as well as two CP phases φ12 and φ13 , and mi are the three corresponding mass eigenvalues. In order to extract the neutrino mass from an observed decay rate, the nuclear matrix elements need to be known with some reasonable reliability. Whereas the matrix elements in the 2νββ decay have a rather simple structure, the ones for the 0νββ decay are significantly more complex, since the neutrino enters into the description as a virtual particle. Usually, the generalized matrix elements are expressed in terms of a neutrino potential operator (cf. refs. [15-18] and references therein): (0ν)

(6)

MDGT = f |

(7)

MDF = f |



σl σk τl− τk− HGT (rlk , Ea )|i

lk

(0ν)



τl− τk− HF (rlk , Ea )|i,

lk

where rlk is the proton-neutron distance in the nucleus, and Ea is an energy parameter related to the excitation energy. (Note that short-range effects become important here.) As the distance rlk is of order the size of the nucleus, the momentum transfers involved can be large, typically of order 0.5 fm−1 , which then allows excitation of many intermediate states and many multipoles up to considerably high energies (∼ 50 MeV). An experimental determination of these matrix elements is an almost impossible task. Further, because of the different operator active for exciting high-J states in hadronic reactions, one cannot easily relate the strength observed in the charge-exchange reaction with the one in the weak-interaction process of ββ decay anymore. Instead, one is forced to resort to theoretical models, but in order for them to be reliable, they must at least be confronted with the experimental matrix elements for the 2νββ decay. 2. – The case of

48

Ca and

64

Zn

In this section we briefly review the experiments, which were performed on the mass A = 48 (48 Ca and 48 Ti) and the mass A = 64 system (64 Zn and 64 Ni). Both experiments have been published in refs. [10,11,13,19], and we refer to these as many of the intricacies of the experiments and the analyses can be found there.

178

D. Frekers

Fig. 1. – Excitation spectra for the 48 Ca(3 He, t)48 Sc (upper left panel, from ref. [11]) and 48 Ti(d, 2 He)48 Sc experiments (lower left panel, from ref. [10]). On the right side are the excitation spectra for the 64 Zn(d, 2 He)64 Cu (upper right panel, from ref. [13]) and 64 Ni(3 He, t)64 Cu experiments (lower right panel, from ref. [19]). Levels excited in both spectra are connected by the vertical lines.

The (d, 2 He) experiment on 48 Ti at the KVI Groningen [10] and the (3 He, t) experiment on 48 Ca at the RCNP [11] yielded a resolution of about 100 keV and 40 keV, respectively. The results of the two experiments are shown in fig. 1. Most surprising in the case of 48 Ca was the strong anti-correlation of the GT+ strength with its GT− counterpart, i.e. intermediate states, which were strongly excited via the (p, n)-type reaction were only weakly excited via the (n, p) reaction and vice versa. This anti-correlation has an immediate bearing on the size of the ββ matrix element and, therefore, on the half-life 2ν of 48 Ca. The extracted ββ matrix element was MDGT = 0.063 ± 0.016 MeV−1 and the 48 2ν half-life of the ββ decay of Ca was in the range of 2.4 × 1019 y < T1/2 < 12.9 × 1019 y. The approach of quoting two extremes as the likely interval for the true 48 Ca ββ-decay half-life is due to fact that charge-exchange reactions do not provide information about the sign of the matrix elements [11]. Shell model calculations make some predictions about phases, and in the above paper [11] we have tried to accommodate this additional information, which then widens the interval for the extracted half-life. The result is in agreement with the recently communicated counting result from the NEMO-III experi2ν ment T1/2 = 3.9 × 1019 y [20, 21]. One should note, however, that the present studies are not primarily geared towards a precise determination of the half-life, but rather to bring the details of the underlying nuclear structure to light.

Charge-exchange reactions and nuclear matrix elements etc.

179

The anti-correlation of the GT+ and GT− strength was a surprising effect and it was speculated that this was due to the difference of the intrinsic deformation of the mother nucleus 48 Ca and the grand-daughter nucleus 48 Ti. The difference of deformation could, in fact, be a new aspect in the theoretical treatment of ββ decay, which has so far been dealt with only in a rather coarse way. We will see this effect re-appearing in a much more pronounced way in the case of 76 Ge. Figure 1 also shows results from a similar study in the mass A = 64 system, i.e. 64 Zn and 64 Ni. Here, 64 Zn is a candidate for ββ decay into the β + β + direction. We performed a 64 Zn(d, 2 He)64 Cu measurement at the KVI Groningen [13] and compared that to a 64 Ni(3 He, t)64 Cu measurement performed at the RCNP [19]. Through these two measurements the β + β + decay matrix elements were constructed. This marks the first time that experimental ββ decay nuclear matrix elements have been measured for a nucleus, which decays in the β + β + direction. As β + β + decaying nuclei feature a comparatively low neutron excess (e.g., N –Z = 4 for 64 Zn), the GT+ suppression owing to the Pauli blocking of occupied levels in the daughter nucleus was expected to be less severe than for typical β − β − decaying nuclei. This is what was observed by the relatively large B(GT+ ) strength extracted from the 64 Cu daughter at low excitation energies. These large B(GT+ ) values then yielded a comparatively large 2νββ decay matrix element, which in the present case was about an order of magnitude larger than that of 48 Ca. This larger matrix element of 64 Zn accelerates the 2νββ decay by about 2 orders of magnitude, which indicates the general importance of the nuclear structure entering into the dynamics of the ββ decay. Unfortunately, this rather advantageous factor does not offset the large extra suppression, which enters through the β + β + phase space factor compared to the β − β − case, let alone the experimental difficulties associated with the detection of the decay. Using the phase space factors for 2νβ + EC and 2νECEC decay given in ref. [22], one then arrives at half-lives for the 64 Zn decay T1/2 (2νβ + EC) = (4.7 ± 0.9) · 1031 y, T1/2 (2νECEC) = (1.2 ± 0.2) · 1025 y. Here, the rather large value for the 2νβ + EC decay is due to the fact that the Q-value of the 64 Zn decay is only 1.096 MeV leaving for the 2 neutrinos and the positron a mere 74 keV to share (Q − 2m0 c2 ). 3. – The case of

76

Ge

The nucleus 76 Ge is considered one of the most important ββ decaying nuclei. This is the only nucleus, for which a signature for 0νββ decay has so far been reported [23, 24]. The positive report has prompted two new efforts, GERDA and MAJORANA, which will put this observation to a serious test [25, 26]. Both experiments expect to increase the sensitivity level by about 2 orders of magnitude compared to the previous experiment. This constitutes an enormous challenge and both experiments will have to be staged over

2.22 MeV (1+)

1.03 MeV (1+)

0.03

0.04 MeV (1+,2–)

0.04

1.63 MeV (1+) 1.86 MeV (1+)

D. Frekers 0.20 76Se(d,2He)76As Θc.m. ~ 0.4° ∆E = 120 keV KVI 2005

0.10

0.01

0.05

1.45 MeV (1+)

1.82 MeV (1+) 2.03 MeV (1+)

1.13 MeV (1+)

0.13 MeV (1+)

100

76Ge(3He,t)76As Θc.m. ~ 0.3° ∆E = 30 keV RCNP 2007

60

0.05 0.10 0.15

20 -1

bckgnd. B(GT+)

0

0 140

76Se(d,2He)76As Θc.m. ~ 0.4° ∆E = 120 keV

B(GT+)

0.15

0.02

0.09 MeV (1+)

d2σ/dΩdEx[cts/sr 10 keV]

d2σ/dΩdEx[mb/sr 50 keV]

180

0

1

2

3

4 5 Ex[MeV]

0.20

76Ge(3He,t)76As Θc.m. ~ 0.3° ∆E = 30 keV

B(GT-)

0

1

2

3

4

5 Ex[MeV]

Fig. 2. – The top left shows the excitation spectra for the 76 Se(d, 2 He)76 As reaction (from ref. [27]), below the 76 Ge(3 He, t)76 As reaction. Levels marked in red are identified as J π = 1+ . An anti-correlation of the transition strength is observed as indicated in the extracted B(GT) values in the figure on the right. Red bars show levels that can be correlated, whereas full black bars show levels that do not have a clearly visible partner.

several phases. Clearly, if a positive result is found, one wishes to extract the mass of the Majorana neutrino with as little theoretical uncertainty as possible. We performed the 76 Se(d, 2 He)76 As experiment at the KVI [27], which yielded a resolution of 120 keV and the 76 Ge(3 He, t)76 As experiment at RCNP with an energy resolution of about 30 keV (see fig. 2). In this A = 76 system we find again a surprisingly strong anti-correlation between the GT− and GT+ transition strengths, which is even more strongly pronounced than in the case of 48 Ca. Many 1+ states are observed in the direction of (3 He, t) and only a few clearly visible states in the direction of (d, 2 He). Moreover, those that do show up strongly in one of the two directions are not significantly correlated with the other. In the right part of fig. 2 we show the experimental distribution of GT strength for the two directions covering the low-energy region up to about 5 MeV. The significant lack of correlation indicates a significant lack of overlap between the wave functions involved and thereby a significant lack of connectivity between the two paths. 2ν In fig. 3 (left) we show the running sum of the matrix element MDGT evaluated from the B(GT) values of the two directions. Assuming an undifferentiated and evenly distributed general background of 0.2 units in the B(GT+ ) distribution up to about 5 MeV (as was identified from the (d, 2 He) reaction, see ref. [27]), then correlating this with all relevant transitions appearing in the (3 He, t) direction and adding this on top of those transitions that can be uniquely connected from the two reaction sides, one arrives at almost exactly the matrix element one would extract from the known half-life. The extracted half-life of 2ν the 2νββ decay of 76 Ge is T1/2 = (1.2±0.2)×1021 y, which agrees with the recommended

Charge-exchange reactions and nuclear matrix elements etc.

181

2ν for the 2νββ decay of 76 Ge. The broFig. 3. – The left side shows the running sum of the MDGT ken line corresponds to a running sum from correlated and clearly visible transitions from both directions, whereas the full line includes the contribution from the undifferentiated background, 2ν ≈ 0.16 MeV−1 . The half-life calculated from this value corresponds which then adds to MDGT to the reported half-life from the counting experiments. The right side shows the overlap of BCS wave functions in a deformed QRPA calculation as a function of the difference of intrinsic deformation of the two nuclei 76 Ge and 76 Se (from ref. [28]). This overlap can be taken as a rough measure of the relative size of the matrix elements.

2ν average experimental value of T1/2 = (1.5 ± 0.1) × 1021 y [29]. ˇ In fig. 3 (right) we also show the result of a recent calculation by Simkovic et al. [28], who have calculated the BCS wave function overlap between the two nuclei 76 Ge and 76 Se as a function of the difference between their intrinsic deformation. The shaded area indicates the variation of the results as function of the absolute size of the deformation (here from β = −0.2 to β = +0.2). The idea here is that one can assume that the BCS overlap of the two wave functions is a rough indicator for the relative size of the ββ matrix element. It is generally accepted that the two nuclei 76 Ge and 76 Se have different intrinsic deformation, and we may therefore speculate that the present observation of the mismatch between the GT transition from the different paths could be a result of this wave function mismatch. At present, the theoretical calculations do not give guidance to what the effect of the intrinsic deformation could be on the more interesting 0νββ decay. Two important conclusions may be drawn from these experimental findings:

– The low excitation energy region seems to exhaust almost all the relevant contri2ν butions to the 2νββ decay matrix element MDGT , which is an observation already 48 64 made in the cases of Ca and Zn. – The effect of deformation seems to manifest itself in a mismatch between the different transitions rather than in an overall suppression of B(GT) strength. Further, taking theoretical models as a guide, it seems that the difference of the intrinsic de-

0.04

96Mo(d,2He)96Nb Θ c.m. < 1.3° ΔE = 115 keV

0.69 MeV (1+)

150

96Zr(3He,t)96Nb Θ c.m. ~ 0.3° ΔE = 32 keV

0.69 MeV (1+)

100

0.02

0 0

200 0.63 MeV (2+)

0.06

d2s/dWdEx [cts/sr 13 keV]

D. Frekers

0.51 MeV (2-)

d2σ/dΩdEx [mb/sr/50 keV]

182

50

1

2

3

4 5 Ex [MeV]

0

1

2

3

4 5 Ex [MeV]

Fig. 4. – Excitation energy spectrum of the 96 Mo(d, 2 He)96 Nb experiment [30] (left spectrum) performed at KVI and the 96 Zr(3 He, t)96 Nb experiment (right spectrum) performed at RCNP. The entire low-energy GT+ and GT− strength is concentrated in one single state only.

formation between mother and grand-daughter nucleus and not their absolute size has the largest bearing on the overall reduction of the ββ-decay matrix element. 4. – The case of

96

Zr

The GT distribution in the charge-exchange reaction on the mass A = 96 system is completely contrary to what was observed in the A = 76 system. In the (d, 2 He) reaction [30] only one strong GT transition was found at 0.69 MeV with B(GT) = 0.3 units (see left part of fig. 4). This is rather remarkable, since in the simple shell model the conversion of any of the two g9/2 valence protons into a g7/2 neutron can proceed largely unhindered and should, in fact, give rise to several comparatively strong GT transitions. On the other hand, comparing this to the (3 He, t) reaction, we find that the only strongly excited 1+ state is again the one at 0.69 MeV. Almost all of the low-energy GT− strength is concentrated in this state as shown in the right part of fig. 4. This is a rather unique situation of the single state dominance (SSD), which is a term given by Ejiri et al. [31]. A subsequent evaluation of the 2νββ matrix element shows that the entire transition path for the 2νββ decay indeed seems to proceed through this state only. In fact, the extracted half-life from the charge-exchange experiments is T1/2 = (2.4 ± 0.3) × 1019 y, in perfect agreement with the half-life measured by the NEMO experiment [32] given as 2ν 19 19 T1/2 = (2.1+0.8 −0.4 ) × 10 y and recently updated to T1/2 = (2.3 ± 0.3) × 10 y [33]. 5. – The case of

100

Mo

The nucleus 100 Mo is interesting not only from the aspect of ββ decay, but also and foremost, because in a sufficiently large experiment like MOON [34] or SUPER-NEMO

183

yield/10keV

Charge-exchange reactions and nuclear matrix elements etc.

500 100Mo(3He,t)100Tc Θc.m. ~ 0.3° ΔE = 29 keV

400

300 g.s. 200

100

0

-1

0

1

2

3 Ex [MeV]

Fig. 5. – Excitation energy spectrum of the 100 Mo(3 He, t)100 Tc experiment performed at RCNP. The entire GT− strength is concentrated in one single state only, similar to the case of 96 Zr(3 He, t).

it can be used as a neutrino detector for solar neutrinos or even for neutrinos from a supernova explosion. The measured 100 Mo(3 He, t) spectrum leading to the intermediate nucleus 100 Tc is shown in fig. 5. Similar to the case of 96 Zr(3 He, t)96 Nb, we observe that the entire low-energy GT− strength up to at least 5 MeV is concentrated in one single transition only, which is even the one to the ground state. Again, we are faced here with another example of a near perfect SSD situation. Apart from the relevance to ββ decay, this feature has important and significant advantages for the detection of neutrinos, in particular for those originating from a nearby (i.e. in our Galaxy) supernova explosion. These neutrinos, whose mean energy would be about 10 MeV, will almost exclusively populate the ground state through the charged current 100 Mo(ν, e− )100 Tc reaction, thereby leaving their full energy to the electron, which subsequently can be tagged by the 15 s delayed β − decay (Emax = 3.202 MeV) of 100 Tc. This constitutes a rather unique way to measure the neutrino temperature spectrum and possible distortions imprinted onto it due to collective flavor transitions mediated through the self-interactions and matter potentials, as is discussed in ref. [35]. 6. – Conclusion Double-beta decay is presently at the forefront of experimental research in sub-atomic physics. This is because a mere observation of the 0νββ-decay mode would imply the neutrino to be a Majorana particle and thereby signal physics beyond the Standard Model. However, the rate of the 0ν decay critically depends on two unknowns, the mass

184

D. Frekers

of the neutrino on the one side and the underlying nuclear physics embedded in the nuclear matrix elements on the other. This is a rather uncomfortable situation, as it makes solid experimental planning a challenge. We have shown that charge-exchange reactions like (d, 2 He) and (3 He, t) can probe the ββ decay matrix elements at least for the 2ν variant in a rather detailed way. This was exemplified by new results for the masses A = 76, 96, and 100. Good experimental resolution was one of the important pre-requisites. We have also shown that some new aspects seem to emerge, one of them being the influence of deformation on the size of the matrix elements. A suppression of the matrix elements can be expected if the mother and grand-daughter nuclei exhibit rather different intrinsic deformations. However, this suppression is not caused by a general suppression of the GT strength, but rather by an overall mismatch of the strength in the GT+ and GT− direction. On the other hand, the nuclear structure in the region of A 100 exhibits rather simple features, which theoretical models should be able to deal with. Clearly, in view of the various upcoming initiatives for measuring ββ decay in different systems, a concerted theoretical and experimental effort is needed to address the important issue of the ββ decay nuclear matrix elements. REFERENCES [1] Goodman C. D. et al., Phys. Rev. Lett., 44 (1980) 1755. [2] Taddeucci T. N. et al., Nucl. Phys. A, 469 (1987) 125. [3] Alford W. P. and Jackson K. P., Proceedings of the Workshop on Isovector Excitations in Nuclei, Can. J. Phys., 65 (1987). [4] Jackson K. P. et al., Phys. Lett. B, 201 (1988) 25. [5] Rakers S. et al., Nucl. Instrum. Methods Phys. Res. B, 481 (2002) 253. [6] Rakers S. et al., Phys. Rev. C, 65 (2002) 044323. [7] Hitt G. W. et al., Nucl. Instrum. Methods Phys. Res. A, 566 (2006) 264. [8] Adachi T. et al., Phys. Rev. C, 73 (2006) 024311. [9] Fujita Y. et al., Phys. Rev. Lett., 95 (2005) 212501. [10] Rakers S. et al., Phys. Rev. C, 70 (2004) 054302. [11] Grewe E.-W. et al., Phys. Rev. C, 76 (2007) 054307. [12] Rakers S. et al., Phys. Rev. C, 71 (2005) 054313. [13] Grewe E.-W. et al., Phys. Rev. C, 77 (2008) 064303. [14] Schlechter J. and Valle J. W. F., Phys. Rev. D, 25 (1982) 2951. [15] Suhonen J. and Civitarese O., Phys. Rep., 300 (1998) 123. [16] Suhonen J., Khadkikar S. B. and Faessler A., Phys. Lett. B, 237 (1990) 8. [17] Suhonen J., Khadkikar S. B. and Faessler A., Nucl. Phys. A, 529 (1991) 727. [18] Vergados J. D., Nucl. Phys. A, 506 (1990) 482. [19] Popescu L., Ph.D. thesis, Gent University (2006); Popescu L. et al., to be published (2009). [20] Arnold R. et al., Nucl. Instrum. Methods Phys. Res. A, 536 (2005) 79. [21] Vasiliev V., preliminary value communicated during Physics of Massive Neutrinos, Blaubeuren, Germany, July 2007, Joint Annual Meeting of EU project ILIAS, N4 IDEA, ¨ssler A., Giuliani A., Lalanne D. and Rodin and N6/WP1 ENTApP, organized by Fa V. [22] Kim C. W. and Kubodera K., Phys. Rev. D, 27 (1983) 2765.

Charge-exchange reactions and nuclear matrix elements etc.

185

[23] Klapdor-Kleingrothaus H.-V. et al., Mod. Phys. Lett. A, 16 (2001) 2409. [24] Klapdor-Kleingrothaus H.-V. et al., Phys. Lett. B, 586 (2004) 198. KlapdorKleingrothaus H.-V. et al., Nucl. Instrum. Methods Phys. Res. A, 522 (2004) 371. [25] Simgen H. et al., Nucl. Phys. B, 143 (2005) 567; Abt I. et al., hep-ex/0404039, GERDA proposal submitted to Gran Sasso Scientific Committee. [26] Aalseth C. E. et al., Nucl. Phys. B. Proc. Suppl., 138 (2005) 217; Aalseth C. E. et al., Phys. At. Nuclei, 67 (2004) 2002. [27] Grewe E.-W. et al., Phys. Rev. C, 78 (2008) 044301. ˇ [28] Simkovic F. et al., arXiv:nucl-th/0308037 (2003). [29] Barabash A. S., Czech. J. Phys., 56 (2006) 437. [30] Dohmann H. et al., Phys. Rev. C, 78 (2008) 041602. [31] Ejiri H. et al., Phys. Lett. B, 258 (1991) 17. [32] Arnold R. et al., Nucl. Phys. A, 658 (1999) 299. [33] Barabash A., arXiv:0807.2336v2 [nucl-ex] (2008). [34] Ejiri H. et al., Phys. Rev. Lett., 85 (2000) 2917; Ejiri H., Phys. Rep., 338 (2000) 265; Ejiri H. et al., Nucl. Phys. B. Proc. Suppl., 110 (2002) 375; Ejiri H. et al., Phys. Lett. B, 530 (27) 2002; Doe P. et al., Nucl. Phys. A, 721 (2003) 517c; Hazama R. et al., Nucl. Phys. B. Proc. Suppl., 138 (2005) 102; Nomachi H. et al., Nucl. Phys. B. Proc. Suppl., 138 (2005) 221. [35] Fogli G. L. et al., Phys. Rev. D, 78 (2008) 097301; Fogli G. L. et al., arXiv: 0812.3031[hep-ph].

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-187

Cosmological probes of neutrino masses S. Pastor Institut de F´ısica Corpuscular (CSIC-Universitat de Val` encia) Ed. Instituts d’Investigaci´ o, Ap. correus 22085, 46071 Val` encia, Spain

Summary. — Neutrinos can play an important role in the evolution of the Universe, modifying some of the cosmological observables. In this contribution we summarize the main aspects of cosmological relic neutrinos and we describe how the precision of present cosmological data can be used to learn about neutrino properties, in particular their mass, providing complementary information with respect to beta decay and neutrinoless double-beta decay experiments. We show how the analysis of current cosmological observations, such as the anisotropies of the cosmic microwave background or the distribution of large-scale structure, provides an upper bound on the sum of neutrino masses, with very good perspectives from future cosmological measurements which are expected to be sensitive to neutrino masses well into the sub-eV range.

1. – Introduction In this contribution I summarize the topics discussed in my lectures at the CLXX Course of the International School of Physics “Enrico Fermi”. The subject of my presentations was the role of neutrinos in Cosmology, one of the best examples of the very close ties that have developed between nuclear physics, particle physics, astrophysics and cosmology. I tried to present the most interesting aspects, but many others that were left out can be found in the review by A. D. Dolgov [1]. c Societ`  a Italiana di Fisica

187

188

S. Pastor

We begin with a description of the properties and evolution of the background of relic neutrinos that fills the Universe. Then we review the influence of neutrinos on Primordial Nucleosynthesis and the possible effects of neutrino oscillations on Cosmology. The largest part of this contribution is devoted to the impact of massive neutrinos on cosmological observables, that can be used to extract bounds on neutrino masses from present data. Finally we discuss the sensitivities on neutrino masses from future cosmological experiments. Note that light massive neutrinos could also play a role in the generation of the baryon asymmetry of the Universe from a previously created lepton asymmetry. In these leptogenesis scenarios, one can also obtain quite restrictive bounds on light neutrino masses, which are, however, strongly model-dependent. We do not discuss this subject here, as was covered by other lecturer at the School [2]. For further details, the reader is referred to the short reviews on neutrino cosmology [3] or [4], while more information can be found in [5] and in particular in [6]. A more general review on the connection between particle physics and cosmology can be found in [7]. 2. – The cosmic neutrino background The existence of a relic sea of neutrinos is a generic feature of the standard hot Big-Bang model, in number only slightly below that of relic photons that constitute the cosmic microwave background (CMB). This cosmic neutrino background (CNB) has not been detected yet, but its presence is indirectly established by the accurate agreement between the calculated and observed primordial abundances of light elements, as well as from the analysis of the power spectrum of CMB anisotropies. In this section we will summarize the evolution and main properties of the CNB. . 2 1. Relic neutrino production and decoupling. – Produced at large temperatures by frequent weak interactions, cosmic neutrinos of any flavour (νe , νμ , ντ ) were kept in equilibrium until these processes became ineffective in the course of the expansion of the early Universe. While coupled to the rest of the primeval plasma (relativistic particles such as electrons, positrons and photons), neutrinos had a momentum spectrum with an equilibrium Fermi-Dirac form with temperature T ,  −1 p − μν feq (p, T ) = exp +1 , T 

(1)



which is just one example of the general case of particles in equilibrium (fermions or bosons, relativistic or non-relativistic), as shown, e.g., in [8]. In the previous equation we have included a neutrino chemical potential μν that would exist in the presence of . a neutrino-antineutrino asymmetry, but we will see later in subsect. 5 1 that even if it exists, its contribution can be safely ignored. As the Universe cools, the weak interaction rate Γν falls below the expansion rate and one says that neutrinos decouple from the rest of the plasma. An estimate of the

189

Cosmological probes of neutrino masses

decoupling temperature Tdec can be found by equating the thermally averaged value of the weak interaction rate (2)

Γν = σν nν ,

where σν ∝ G2F is the cross section of the electron-neutrino processes with GF the Fermi constant and nν is the neutrino number density, with the expansion rate given by the Hubble parameter H (3)

H2 =

8πρ , 3MP2

where ρ ∝ T 4 is the total energy density, dominated by relativistic particles, and MP = 1/G1/2 is the Planck mass. If we approximate the numerical factors to unity, with Γν ≈ G2F T 5 and H ≈ T 2 /MP , we obtain the rough estimate Tdec ≈ 1 MeV. More accurate calculations give slightly higher values of Tdec which are flavour-dependent since electron neutrinos and antineutrinos are in closer contact with electrons and positrons, as shown, e.g., in [1]. Although neutrino decoupling is not described by a unique Tdec , it can be approximated as an instantaneous process. The standard picture of instantaneous neutrino decoupling is very simple (see, e.g., [8] or [9]) and reasonably accurate. In this approximation, the spectrum in eq. (1) is preserved after decoupling, since both neutrino momenta and temperature redshift identically with the expansion of the Universe. In other words, the number density of non-interacting neutrinos remains constant in a comoving volume since the decoupling epoch. We will see later that active neutrinos cannot possess masses much larger than 1 eV, so they were ultra-relativistic at decoupling. This is the reason why the momentum distribution in eq. (1) does not depend on the neutrino masses, even after decoupling, i.e. there is no neutrino energy in the exponential of feq (p). When calculating quantities related to relic neutrinos, one must consider the various possible degrees of freedom per flavour. If neutrinos are massless or Majorana particles, there are two degrees of freedom for each flavour, one for neutrinos (one negative helicity state) and one for antineutrinos (one positive helicity state). Instead, for Dirac neutrinos there are in principle twice more degrees of freedom, corresponding to the two helicity states. However, the extra degrees of freedom should be included in the computation only if they are populated and brought into equilibrium before the time of neutrino decoupling. In practice, the Dirac neutrinos with the “wrong-helicity” states do not interact with the plasma at temperatures of the MeV order and have a vanishingly small density with respect to the usual left-handed neutrinos (unless neutrinos have masses close to the keV range, as explained in sect. 6.4 of [1], but such a large mass is excluded for active neutrinos). Thus the relic density of active neutrinos does not depend on their nature, either Dirac or Majorana particles. Shortly after neutrino decoupling the temperature drops below the electron mass, favouring e± annihilations that heat the photons. If one assumes that this entropy

190

S. Pastor

1.5

10 TJ = 1.401 TQ

1.4

1 Ti (MeV)

1.3 TJ / TQ

neutrinos photons

e+e- oJJ

1.2

0.1 1.1 TJ = TQ

1 10

1

0.01 0.1

0.1 TJ (MeV)

1 a/a(1 MeV)

10

Fig. 1. – Photon and neutrino temperatures during the process of e± annihilations: evolution of their ratio (left) and their decrease with the expansion of the Universe (right).

transfer did not affect the neutrinos because they were already completely decoupled, it is easy to calculate the change in the photon temperature before any e± annihilation and after the electron-positron pairs disappear by assuming entropy conservation of the electromagnetic plasma. The result is (4)

Tγafter = Tγbefore



11 4

1/3

1.40102,

which is also the ratio between the temperatures of relic photons and neutrinos Tγ /Tν = (11/4)1/3 . The evolution of this ratio during the process of e± annihilations is shown in the left panel of fig. 1, while one can see in the right panel how in this epoch the photon temperature decreases with the expansion less than the inverse of the scale factor a. Instead the temperature of the decoupled neutrinos always falls as 1/a. It turns out that the standard picture of neutrino decoupling described above is slightly modified: the processes of neutrino decoupling and e± annihilations are sufficiently close in time so that some relic interactions between e± and neutrinos exist. These relic processes are more efficient for larger neutrino energies, leading to non-thermal distortions in the neutrino spectra at the per cent level and a slightly smaller increase of the comoving photon temperature, as noted in a series of works (see the full list given in the review [1]). A proper calculation of the process of non-instantaneous neutrino decoupling demands solving the momentum-dependent Boltzmann equations for the neutrino spectra, a set of integro-differential kinetic equations that are difficult to solve numerically. The most recent analysis [10] of this problem has included the effect of flavour neutrino oscillations on the neutrino decoupling process. One finds an increase in the neutrino energy densities with respect to the instantaneous decoupling approximation (0.73% and

Cosmological probes of neutrino masses

191

0.52% for νe ’s and νμ,τ ’s, respectively) and a value of the comoving photon temperature after e± annihilations which is a factor 1.3978 larger, instead of 1.40102. These changes modify the contribution of relativistic relic neutrinos to the total energy density which is taken into account using Neff 3.046, as defined later in eq. (12). In practice, the distortions calculated in [10] only have small consequences on the evolution of cosmological perturbations, and for many purposes they can be safely neglected. Any quantity related to relic neutrinos can be calculated after decoupling with the spectrum in eq. (1) and Tν . For instance, the number density per flavour is fixed by the temperature, (5)

nν =

3 6ζ(3) 3 nγ = T , 11 11π 2 γ

which leads to a present value of 113 neutrinos and antineutrinos of each flavour per cm3 . Instead, the energy density for massive neutrinos should in principle be calculated numerically, with two well-defined analytical limits, (6a) (6b)

 4/3 7π 2 4 Tγ4 , 120 11 ρν (mν  Tν ) = mν nν .

ρν (mν Tν ) =

. 2 2. Background evolution. – Let us discuss the evolution of the CNB after decoupling in the expanding Universe, which is described by the Friedmann-Robertson-Walker metric [9] (7)

ds2 = dt2 − a(t)2 δij dxi dxj ,

where we assumed negligible spatial curvature. Here a(t) is the scale factor usually normalized to unity now (a(t0 ) = 1) and related to the redshift z as a = 1/(1 + z). General relativity tells us the relation between the metric and the matter and energy in the Universe via the Einstein equations, whose time-time component is the Friedmann equation (8)

 2 8πG ρ a˙ ρ = H02 0 , = H2 = a 3 ρc

that gives the Hubble rate in terms of the total energy density ρ. At any time, the critical density ρc is defined as ρc = 3H 2 /8πG, and the current value H0 of the Hubble parameter gives the critical density today (9)

ρ0c = 1.8788 × 10−29 h2 g cm−3 ,

where h ≡ H0 /(100 km s−1 Mpc−1 ). The different contributions to the total energy

192

S. Pastor

TQ (eV) 10

Ui1/4 (eV)

10

10

6

3

TQ (K)

1

10

-3

1

cdm b J / Q3 Q2 Q1

3

1

10

9

10

6

10

3

1.95

0.1

:i

10

6

0.01

-3

BBN

10

J dec.

0.001

10-9

10-6 a/a0

10-3

1e-04 1

10-9

10-6 a/a0

10-3

1

Fig. 2. – Evolution of the background energy densities (left) and density fractions Ωi (right) from the time when Tν = 1 MeV until now, for each component of a flat Universe with h = 0.7 and current density fractions ΩΛ = 0.70, Ωb = 0.05, Ων = 0.0013 and Ωcdm = 1 − ΩΛ − Ωb − Ων . The three neutrino masses are m1 = 0, m2 = 0.009 eV and m3 = 0.05 eV.

density are (10)

ρ = ργ + ρcdm + ρb + ρν + ρΛ ,

and the evolution of each component is given by the energy conservation law in an expanding Universe, ρ˙ = −3H(ρ + p), where p is the pressure. Thus the homogeneous density of photons ργ scales like a−4 , that of non-relativistic matter (ρcdm for cold dark matter and ρb for baryons) like a−3 , and the cosmological constant density ρΛ is of course time-independent. Instead, the energy density of neutrinos contributes to the radiation density at early times but behaves as matter after the non-relativistic transition. The evolution of all densities is shown on the left plot of fig. 2, starting at MeV temperatures until now. We also display the characteristic times for the end of Primordial Nucleosynthesis and for photon decoupling or recombination. The evolution of the density fractions Ωi ≡ ρi /ρc is shown on the right panel, where it is easier to see which of the Universe components is dominant, fixing its expansion rate: first radiation in the form of photons and neutrinos (Radiation Domination or RD), then matter which can be CDM, baryons and massive neutrinos at late times (Matter Domination or MD) and finally the cosmological constant density takes over at low redshift (typically z < 0.5). Massive neutrinos are the only particles that present the transition from radiation to matter, when their density is clearly enhanced (upper solid lines in the right panel of fig. 2). Obviously the contribution of massive neutrinos to the energy density in the nonrelativistic limit is a function of the mass (or the sum of all masses for which mi  Tν ), and the present value Ων could be of order unity for eV masses (see sect. 6).

193

Cosmological probes of neutrino masses

3. – Neutrinos and primordial nucleosynthesis In the course of its expansion, when the early Universe was only less than a second old, the conditions of temperature and density of its nucleon component were such that light nuclei could be created via nuclear reactions (for a recent review, see [11]). During this epoch, known as Primordial or Big-Bang Nucleosynthesis (BBN), the primordial abundances of light elements were produced: mostly 4 He but also smaller quantities of less stable nuclei such as D, 3 He and 7 Li. Heavier elements could not be produced because of the rapid evolution of the Universe and its small nucleon content, related to the small value of the baryon asymmetry which normalized to the photon density, ηb ≡ (nb −nb¯ )/nγ , was about a few times 10−10 . Measuring these primordial abundances today is a very difficult task, because stellar process may have altered the chemical compositions. Still, data on the primordial abundances of 4 He, D and 7 Li exist and can be compared with the theoretical predictions to learn about the conditions of the Universe at such an early period. Thus BBN can be used as a cosmological test of any non-standard physics or cosmology [12]. The physics of BBN is well understood, since in principle only involves the Standard Model of particle physics and the time evolution of the expansion rate as given by the Friedmann equation (3). In the first phase of BBN the weak processes that had kept the neutrons and protons in equilibrium,

(11)

n + νe ↔ p + e− ,

n + e+ ↔ p + ν¯e ,

freeze and the neutron-to-proton ratio becomes a constant (later diminished due to neutron decays, n → p + e− + ν¯e ). This ratio largely fixes the produced 4 He abundance. Later all the primordial abundances of light elements are produced and their value depend on the competition between the nuclear reaction rates and the expansion rate of the Universe. These values can be quite precisely calculated with a BBN numerical code (see, e.g., [13]). At present there exists a nice agreement with the observed abundance of D for a value of the baryon asymmetry η = 6.1 ± 0.6 [11], which also agrees with the region determined by CMB and large-scale structure data (LSS). Instead, the predicted primordial abundance of 4 He tends to be a bit larger than the observed value. However, it is difficult to consider this as a serious discrepancy, because the accuracy of the observations of 4 He is limited by systematic uncertainties. There are two main effects of relic neutrinos at BBN. The first one is that they contribute to the relativistic energy density of the universe (if mν Tν ), thus fixing the expansion rate. This is why BBN gave the first allowed range of the number of neutrino species before accelerators (see the next section). On the other hand, BBN is the last period of the Universe sensitive to neutrino flavour, since electron neutrinos and antineutrinos play a direct role in the processes in eq. (11). We will see some examples of BBN bounds on neutrinos (effective number or oscillations) in the following sections.

194

S. Pastor

4. – Extra radiation and the effective number of neutrinos Together with photons, in the standard case neutrinos fix the expansion rate during the cosmological era when the Universe is dominated by radiation. Their contribution to the total radiation content can be parametrized in terms of the effective number of neutrinos Neff , through the relation 

(12)

7 ρr = ργ + ρν = 1 + 8



4 11



4/3 Neff

ργ ,

where we have normalized to the photon energy density because its value today is known from the measurement of the CMB temperature. This equation is valid when neutrino decoupling is complete and holds as long as all neutrinos are relativistic. We know that the number of light neutrinos sensitive to weak interactions (flavour or active neutrinos) equals three from the analysis of the invisible Z-boson width at LEP, Nν = 2.994 ± 0.012 [14], and we saw in a previous section from the analysis of neutrino decoupling that they contribute as Neff 3.046. Any departure of Neff from this last value would be due to non-standard neutrino features or to the contribution of other relativistic relics. For instance, the energy density of a hypothetical scalar particle φ in equilibrium with the same temperature as neutrinos would be ρφ = (π/30) Tν4 , leading to a departure of Neff from the standard value of 4/7. A detailed discussion of cosmological scenarios where Neff is not fixed to three can be found in [12] or [1]. In the previous section we saw that the expansion rate during BBN fixes the produced abundances of light elements, and in particular that of 4 He. Thus the value of Neff can be constrained at the BBN epoch from the comparison of theoretical predictions and experimental data on the primordial abundances of light elements. In addition, a value of Neff different from the standard one would modify the transition epoch from a radiation-dominated to a matter-dominated Universe, which has some consequences on some cosmological observables such as the power spectrum of CMB anisotropies, leading to independent bounds on the radiation content. These are two complementary ways of constraining Neff at very different epochs. Here, as an example, we will only describe the results of a recent analysis [15] (see the references therein for a list of recent works), who considered both BBN and CMB/LSS data. The allowed regions on the plane defined by Neff and the baryon contribution to the present energy density Ωb h2 are shown in fig. 3. The BBN contours were calculated with the 4 He and D abundances, leading to the allowed range Neff = 3.1+1.4 −1.2 (95% CL). Instead, the filled contours correspond to the regions found from the analysis of the most recent cosmological data on CMB temperature anisotropies and polarization, Large Scale galaxy clustering from SDSS and 2dF and luminosity distances of type-Ia Supernovae (we will describe these measurements later in sect. 8). The bounds on the effective number of neutrinos for this case are Neff = 5.2+2.7 −2.2 , while in a less conservative analysis data on the Lyman-α absorption clouds (Ly-α) and the Baryonic Acoustic Oscillations (BAO) from SDSS were added, leading to Neff = 4.6+1.6 −1.5 .

Cosmological probes of neutrino masses

195

Fig. 3. – Allowed regions on the (ωb , Nνeff )-plane at 68% and 95% CL from the analysis of BBN (dotted lines) and cosmological data from other observables as shown (filled contours). The horizontal lines correspond to the standard prediction of Neff  3.046. From [15].

These ranges are in reasonable agreement with the standard prediction of Neff 3.046, shown as a horizontal line on the plots in fig. 3. Moreover, they show that there exists an allowed region of Neff values that is common at early (BBN) and more recent epochs, although some tension remains particularly when adding Lyman-α and BAO data. However, the reader should be cautious in the interpretation of any of these allowed regions as an indication for relativistic degrees of freedom beyond the contribution of flavour neutrinos. Similar results for Neff with more updated cosmological data can be found in [16-18]. 5. – Neutrino oscillations in the Early Universe Nowadays there exist compelling evidences for flavour neutrino oscillations from a variety of experimental data on solar, atmospheric, reactor and accelerator neutrinos. These are very important results, because the existence of flavour change implies that neutrinos mix and have non-zero masses, which in turn requires particle physics beyond the Standard Model. Thus, it is interesting to check whether neutrino oscillations can modify any of the cosmological observables. More on neutrino oscillations and their implications can be found in [19] or any of the existing reviews such as [20-22], to which we refer the reader for more details. It turns out that in the standard cosmological picture all flavour neutrinos were pro. duced with the same energy spectrum, as we saw in subsect. 2 1, so we do not expect any effect from the oscillations among these three states. This is true up to the small spectral distortion caused by the heating of neutrinos from e+ e− annihilations [10], as we described before. In this section we will briefly consider two cases where neutrino oscillations could have cosmological consequences: flavour oscillations with non-zero relic neutrino asymmetries and active-sterile neutrino oscillations.

196

S. Pastor

. 5 1. Active-active neutrino oscillations: relic neutrino asymmetries. – A non-zero relic neutrino asymmetry exists when the number densities of neutrinos and antineutrinos of a given flavour are different. Such a putative asymmetry, that was produced by some mechanism in the very early Universe well before the thermal decoupling epoch, can be quantified assuming that a given flavour is characterized by a Fermi-Dirac distribution as in eq. (1) with a non-zero chemical potential μν or equivalently with the dimensionless degeneracy parameter ξν ≡ μν /T (for antineutrinos, ξν¯ = −ξν ). In such a case, sometimes one says that the relic neutrinos are degenerate (but not in the sense of equal masses). Degenerate electron neutrinos have a direct effect on BBN: we saw in sect. 3 that any change in the νe /¯ νe spectra modifies the primordial neutron-to-proton ratio, which in this case is n/p ∝ exp[−ξνe ]. Therefore, a positive ξνe decreases the primordial 4 He mass fraction, while a negative ξνe increases it, leading to an allowed range −0.01 < ξνe < 0.07,

(13)

compatible with ξνe = 0 and very restrictive for negative values. In addition a non-zero relic neutrino asymmetry always enhances the contribution of the CNB to the relativistic energy density, since for any ξν one has a departure from the standard value of the effective number of neutrinos Neff given by (14)

ΔNeff

    4 2 15 ξν ξν 2 . = + 7 π π

We have seen that this increased radiation modifies the outcome of BBN and that bounds on Neff can be obtained. In addition, another consequence of the extra radiation density is that it postpones the epoch of matter-radiation equality, producing observable effects on the spectrum of CMB anisotropies and the distribution of cosmic large-scale structures (LSS). Both independent bounds on the radiation content can be translated into flavourindependent limits on ξν . Altogether these cosmological limits on the neutrino chemical potentials or relic neutrino asymmetries are not very restrictive, since at least for BBN their effect in the νμ or ντ sector can be compensated by a positive ξνe . For example, an analysis of the combined effect of a non-zero neutrino asymmetry on BBN and CMB/LSS yields the allowed regions [23] (15)

−0.01 < ξνe < 0.22,

|ξνμ,τ | < 2.6,

in agreement with similar but more updated bounds as cited in [6]. These limits allow for a very significant radiation contribution of degenerate neutrinos, leading many authors to discuss the implications of a large neutrino asymmetry in different physical situations (see, e.g., [1]).

Cosmological probes of neutrino masses

197

It is obvious that the limits in eq. (15) would be modified if neutrino flavour oscillations were effective before BBN, equalizing the neutrino chemical potentials. Actually, it was shown in [24] that this is the case for the neutrino mixing parameters in the region favoured by present data. This result is obtained only after the proper inclusion of the refractive terms produced by the background neutrinos, which synchronize the oscillations of neutrinos with different momenta (which would evolve independently without them). In summary, since flavour equilibrium is reached before BBN, the restrictive limits on ξνe in eq. (13) apply to all flavours. The current bounds on the common value of the neutrino degeneracy parameter ξν ≡ μν /T are −0.05 < ξν < 0.07 at 2σ [25]. Thus the contribution of a relic neutrino asymmetry can be safely ignored, in turn implying that the cosmic neutrino radiation density is close to its standard value. . 5 2. Active-sterile neutrino oscillations. – In addition to the flavour or active neutrinos (three species as we saw from accelerator data), there could also exist extra massive neutrino states that are sterile, i.e. singlets of the Standard Model gauge group and thus insensitive to weak interactions. These sterile states νs were either not present in the early Universe or severely suppressed with respect to the active ones, but they could be populated through the effect of active-sterile oscillations if non-zero mixing exists, additional to that among the flavour states. This “thermalization” of the sterile neutrinos is a well-known phenomenon that is very difficult to avoid unless the cosmological scenario is drastically modified. For instance, the suppression of active-sterile oscillations may require very large pre-existing neutrino asymmetries (see, e.g., [26] and references therein). There are two possible regimes for the active-sterile oscillations in cosmology, depending if they are effective before or after the decoupling of the flavour states. If oscillations occur before thermal decoupling, the abundance of sterile neutrinos grows via the conversion of the active states, whose spectrum is kept in equilibrium by the frequent weak interactions. In such a case, the contribution of sterile neutrinos to the radiation energy density is additional to that of the active states, leading to an extra Neff between 0 and 1 (for only one sterile species, it would be larger for more states) depending on how effective was the thermalization of the sterile neutrinos. Instead, for active-sterile oscillations effective after T < 1 MeV, i.e. after decoupling, the total number of neutrinos is conserved and the main feature is that large distortions may appear on the spectra of both the sterile and the active states, with its consequences on BBN when the active neutrinos are of the electron flavour (see, e.g. [27], also for the case of non-zero initial νs abundance). The detailed evolution of active-sterile oscillations in the early Universe is a difficult task, that requires solving the corresponding kinetic equations taking into account the medium effects. More details can be found, for instance, in the works [28] and [29] where detailed numerical calculations were carried out also including the unavoidable mixing between the flavour neutrinos (a 4 × 4 neutrino case). In general, one can obtain bounds on the region of active-sterile mixing parameters from the comparison with BBN and CMB/LSS data, as can be seen in the figures of the previous references or the summary in [1].

198

S. Pastor

Albeit the current data on neutrino oscillations does not seem to favour the existence of mixing with sterile states, the cosmological bounds provide complementary information valid also for some regions of parameters beyond the sensitivity of the laboratory experiments. Note, however, that in order to explain the results of the Liquid Scintillator Neutrino Detector (LSND) [30], an experiment that measured the appearance of electron antineutrinos in a muon antineutrino beam, a fourth sterile neutrino would be required with mass of O(eV). Recently, the MiniBoone experiment [31] has excluded almost completely two-neutrino oscillations as an explanation of the LSND results. In any case, the existence of light sterile neutrinos would have profound consequences in cosmology, first of all because it is very difficult to avoid its full thermalization via active-sterile oscillations. 6. – Massive neutrinos as Dark Matter Nowadays the existence of Dark Matter (DM), the dominant non-baryonic component of the matter density in the Universe, is well established. A priori, massive neutrinos are excellent DM candidates, in particular because we are certain that they exist, in contrast with other candidate particles. Together with CMB photons, relic neutrinos can be found anywhere in the Universe with a number density given by the present value of eq. (5) of 339 neutrinos and antineutrinos per cm3 , and their energy density in units of the critical value of the energy density (see eq. (9)) is  ρν i mi . Ων = 0 = ρc 93.14 h2 eV

(16)

 Here i mi includes all masses of the neutrino states which are non-relativistic today. It is also useful to define the neutrino density fraction fν with respect to the total matter density fν ≡

(17)

Ων ρν = . (ρcdm + ρb + ρν ) Ωm

In order to check whether relic neutrinos can have a contribution of order unity to the present values of Ων or fν , we should consider which neutrino masses are allowed by non-cosmological data. Oscillation experiments measure the differences of squared neutrino masses Δm221 = m22 − m21 and Δm231 = m23 − m21 , the relevant ones for solar and atmospheric neutrinos, respectively [19]. As a reference, we take the following 3σ ranges of mixing parameters from an update of [20], (18)

−5 Δm221 = (7.6+0.7 eV2 , −0.5 ) × 10

s212 = 0.32+0.08 −0.06 ,

|Δm231 | = (2.4 ± 0.4) × 10−3 eV2 ,

s223 = 0.50+0.17 −0.16 ,

s213 ≤ 0.05.

Here sij = sin θij , where θij (ij = 12, 23 or 13) are the three mixing angles. Unfortunately oscillation experiments are insensitive to the absolute scale of neutrino masses, since the

199

Cosmological probes of neutrino masses

1

3 Inverted Normal 1 3

6mi (eV)

mi (eV)

0.1

1, 2 2

0.3

0.01 0.1 1

0.001 0.05

3

0.1

Inverted Normal 0.3 6mi (eV)

0.5

1

0.03 0.001

0.01 0.1 lightest mQ (eV)

1

Fig. 4. – Expected values of neutrino masses according to the values in eq. (18). Left: individual neutrino masses as a function of the total mass for the best-fit values of the Δm2 . Right: ranges of total neutrino mass as a function of the lightest state within the 3σ regions (thick lines) and for a future determination at the 5% level (thin lines).

knowledge of Δm221 > 0 and |Δm231 | leads to the two possible schemes shown in fig. 1 of [6], but leaves one neutrino mass unconstrained. These two schemes are known as normal (NH) and inverted (IH) hierarchies, characterized by the sign of Δm231 , positive and negative, respectively. For small values of the lightest neutrino mass m0 , i.e. m1 (m3 ) for NH (IH), the mass states follow a hierarchical scenario, while for masses much larger than the differences all neutrinos share in practice the same mass and then we say that they are degenerate. In general, the relation between the individual masses and the total neutrino mass can be found numerically, as shown in fig. 4. There are two types of laboratory experiments searching for the absolute scale of neutrino masses, a crucial piece of information for constructing models of neutrino masses and mixings [32]. The neutrinoless double-beta decay (Z, A) → (Z + 2, A) + 2e− (in short 0ν2β) is a rare nuclear processes where lepton number is violated and whose observation would mean that neutrinos are Majorana particles. If the 0ν2β process is mediated by a light neutrino, the results from neutrinoless double-beta decay experiments are converted into an upper bound or a measurement of the effective mass mββ (19)

mββ = |c212 c213 m1 + s212 c213 m2 eiφ2 + s213 m3 eiφ3 |,

where φ1,2 are the two Majorana phases that appear in lepton-number–violating processes. An important issue for 0ν2β results is related to the uncertainties on the corresponding nuclear matrix elements, that were discussed in detail by other speakers in the School [33-35]. For more details and the current experimental results, see [36]. Beta decay experiments, which involve only the kinematics of electrons, are in principle the best strategy for measuring directly the neutrino mass [37,38]. The current limits

200

S. Pastor

from tritium beta decay apply only to the range of degenerate neutrino masses, so that mβ m0 , where (20)

mβ = (c212 c213 m21 + s212 c213 m22 + s213 m23 )1/2 ,

is the relevant parameter for beta decay experiments. The bound at 95% CL is m0 < 2.05–2.3 eV from the Troitsk and Mainz experiments, respectively. This value is expected to be improved by the KATRIN project to reach a discovery potential for 0.3–0.35 eV masses (or a sensitivity of 0.2 eV at 90% CL). Taking into account this upper bound and the minimal values of the total neutrino mass in the normal (inverted) hierarchy, the sum of neutrino masses is restricted to the approximate range  (21) 0.06 (0.1) eV  mi  6 eV. i

As we discuss in the next sections, cosmology is at first order sensitive to the total  neutrino mass i mi if all states have the same number density, providing information on m0 but blind to neutrino mixing angles or possible CP violating phases. Thus cosmological results are complementary to terrestrial experiments. The interested reader can find the allowed regions in the parameter space defined by any pair of parameters  ( i mi , mββ , mβ ) in [21, 39]. Now we can find the possible present values of Ων in agreement with the three neutrino masses shown in fig. 4 and the approximate bounds of eq. (21). Note that even if the three neutrinos are non-degenerate in mass, eq. (16) can be safely applied, because we know from neutrino oscillation data that at least two of the neutrino states are nonrelativistic today, since both (Δm231 )1/2 0.05 eV and (Δm221 )1/2 0.009 eV are larger than the temperature Tν 1.96 K 1.7 × 10−4 eV. If the third neutrino state is very light and still relativistic, its relative contribution to Ων is negligible and eq. (16) remains an excellent approximation of the total density. One finds that Ων is restricted to the approximate range (22)

0.0013 (0.0022)  Ων  0.13,

where we already included that h ≈ 0.7. This applies only to the standard case of three light active neutrinos, while in general a cosmological upper bound on Ων has been used since the 1970s to constrain the possible values of neutrino masses. For instance, if we demand that neutrinos should not be heavy enough to overclose the Universe (Ων < 1),  we obtain an upper bound i mi  45 eV (again fixing h = 0.7). Moreover, since from present analyses of cosmological data we know that the approximate contribution of  matter is Ωm 0.3, the neutrino masses should obey the stronger bound i mi  15 eV. We see that with this simple argument one obtains a bound which is roughly only a factor 2 worse than the bound from tritium beta decay, but of course with the caveats that apply to any cosmological analysis. In the three-neutrino case, these bounds should  be understood in terms of m0 = i mi /3.

Cosmological probes of neutrino masses

201

Dark-matter particles with a large velocity dispersion such as that of neutrinos are called hot dark matter (HDM). The role of neutrinos as HDM particles has been widely discussed since the 1970s, and the reader can find a historical review in [40]. It was realized in the mid-1980s that HDM affects the evolution of cosmological perturbations in a particular way: it erases the density contrasts on wavelengths smaller than a massdependent free-streaming scale. In a universe dominated by HDM, this suppression is in contradiction with various observations. For instance, large objects such as superclusters of galaxies form first, while smaller structures like clusters and galaxies form via a fragmentation process. This top-down scenario is at odds with the fact that galaxies seem older than clusters. Given the failure of HDM-dominated scenarios, the attention then turned to cold dark matter (CDM) candidates, i.e. particles which were non-relativistic at the epoch when the universe became matter-dominated, which provided a better agreement with observations. Still in the mid-1990s it appeared that a small mixture of HDM in a universe dominated by CDM fitted better the observational data on density fluctuations at small scales than a pure CDM model. However, within the presently favoured ΛCDM model dominated at late times by a cosmological constant (or some form of dark energy) there is no need for a significant contribution of HDM. Instead, one can use the available cosmological data to find how large the neutrino contribution can be, as we will see later. Before concluding this section, we would like to mention the case of a sterile neutrino with a mass of the order of a few keV’s and a very small mixing with the flavour neutrinos. Such “heavy” neutrinos could be produced by active-sterile oscillations but not fully thermalized, so that they could play the role of dark matter and replace the usual CDM component. But due to their large thermal velocity (slightly smaller than that of active neutrinos), they would behave as Warm Dark Matter and erase small-scale cosmological structures. Their mass can be bounded from below using Lyman-α forest data from quasar spectra, and from above using X-ray observations. The viability of this scenario is currently under careful examination (see, e.g., [41, 42] for recent analyses and a list of references). 7. – Effects of neutrino masses on cosmology In this section we will briefly describe the main cosmological observables and the effects that neutrino masses cause on them. A more detailed discussion of the effects of massive neutrinos on the evolution of cosmological perturbations can be found in sects. 4.5 and 4.6 of [6]. . 7 1. Brief description of cosmological observables. – Although there exist many different types of cosmological measurements, here we will restrict the discussion to those that are at present the more important for obtaining an upper bound or eventually a measurement of neutrino masses. First of all, we have the CMB temperature anisotropy power spectrum [43], defined as the angular two-point correlation function of CMB maps δT /T¯(ˆ n) (ˆ n being a direction

202

S. Pastor

in the sky). This function is usually expanded in Legendre multipoles  (23)

  ∞ δT  (2l + 1) δT Cl Pl (ˆ ) = n·n ˆ  ), (ˆ n ) (ˆ n ¯ ¯ 4π T T l=0

where Pl (x) are the Legendre polynomials. For Gaussian fluctuations, all the information is encoded in the multipoles Cl which probe correlations on angular scales θ = π/l. We have seen that each neutrino family can only have a mass of the order of 1 eV, so that the transition of relic neutrinos to the non-relativistic regime is expected to take place after the time of recombination between electrons and nucleons, i.e. after photon decoupling. Since the shape of the CMB spectrum is related mainly to the physical evolution before recombination, it will be only marginally affected by the neutrino mass, except for an indirect effect through the modified background evolution. There exists interesting complementary information to the temperature power spectrum if the CMB polarization is measured, and currently we have some less precise data on the temperature × E-polarization (TE) correlation function and the E-polarization self-correlation spectrum (EE). The current Large Scale Structure (LSS) of the Universe is probed by the matter power spectrum, observed with various techniques described in the next section (directly or indirectly, today or in the near past at redshift z). It is defined as the two-point correlation function of non-relativistic matter fluctuations in Fourier space (24)

P (k, z) = |δm (k, z)|2 ,

ρm . Usually P (k) refers to the matter power spectrum evaluated where δm = δρm /¯ today (at z = 0). In the case of several fluids (e.g., CDM, baryons and non-relativistic neutrinos), the total matter perturbation can be expanded as  ρ¯i δi (25) δm = i . ¯i i ρ Since the energy density is related to the mass density of non-relativistic matter through E = mc2 , δm represents indifferently the energy or mass power spectrum. The shape of the matter power spectrum is affected in a scale-dependent way by the free streaming caused by small neutrino masses of O(eV) and thus it is the key observable for constraining mν with cosmological methods. We will show later in fig. 5 the typical shape of both the CMB temperature anisotropy spectrum Cl and the matter power spectrum P (k). . 7 2. Neutrino free streaming. – After thermal decoupling, relic neutrinos constitute a collisionless fluid, where the individual particles free-stream with a characteristic velocity that, in average, is the thermal velocity vth . It is possible to define a horizon as the typical distance on which particles travel between time ti and t. When the Universe was dominated by radiation or matter t  ti , this horizon is, as usual, asymptotically equal

203

Cosmological probes of neutrino masses

no Q’s fQ=0

5000

fQ=0.1

10

4

10

3

10

2

3

P(k) (Mpc/h)

l(l+1) Cl / 2S (PK)

2

6000

4000 3000 2000

no Q’s fQ=0

1000

fQ=0.1 0 2

200

400

600

800 l

1000

1200

1400

10

-3

-2

10 k (h/Mpc)

10

-1

Fig. 5. – CMB temperature anisotropy spectrum ClT and matter power spectrum P (k) for three models: the neutrinoless ΛCDM model, a more realistic ΛCDM model with three massless neutrinos (fν  0), and finally a ΛMDM model with three massive degenerate neutrinos and a total density fraction fν = 0.1. In all models, the values of the cosmological parameters (ωb = Ωb h2 , ωm = Ωm h2 , ΩΛ , As , n, τ ) have been kept fixed. From [6].

to vth /H, up to a numerical factor of order one. Similar to the definition of the Jeans length (see sect. 4.4 in [6]), we can define the neutrino free-streaming wave number and length as 1/2 4πG¯ ρ(t)a2 (t) kFS (t) = , 2 (t) vth ) a(t) 2 vth (t) λFS (t) = 2π = 2π . kFS (t) 3 H(t) 

(26a)

(26b)

As long as neutrinos are relativistic, they travel at the speed of light and their freestreaming length is simply equal to the Hubble radius. When they become nonrelativistic, their thermal velocity decays like (27)

vth

  3Tν 3Tν0  a0  1 eV p

=

150(1 + z) km s−1 , ≡ m m m a m

where we used for the present neutrino temperature Tν0 (4/11)1/3 Tγ0 and Tγ0 2.726 K. This gives for the free-streaming wavelength and wave number during matter or Λ domination 

(28a) (28b)

ΩΛ + Ωm (1 + z)3  m  h Mpc−1 , (1 + z)2 1 eV   1 eV 1+z  h−1 Mpc , λFS (t) = 7.7 3 m ΩΛ + Ωm (1 + z) kFS (t) = 0.82

204

S. Pastor

where ΩΛ and Ωm are the cosmological constant and matter density fractions, respectively, evaluated today. After the non-relativistic transition and during matter domination, the free-streaming length continues to increase, but only like (aH)−1 ∝ t1/3 , i.e. more slowly than the scale factor a ∝ t2/3 . Therefore, the comoving free-streaming length λFS /a actually decreases like (a2 H)−1 ∝ t−1/3 . As a consequence, for neutrinos becoming non-relativistic during matter domination, the comoving free-streaming wave number passes through a minimum knr at the time of the transition, i.e. when m = p = 3Tν and a0 /a = (1 + z) = 2.0 × 103 (m/1 eV). This minimum value is found to be (29)

knr 0.018 Ω1/2 m

 m 1/2 h Mpc−1 . 1 eV

The physical effect of free streaming is to damp small-scale neutrino density fluctuations: neutrinos cannot be confined into (or kept outside of) regions smaller than the free-streaming length, for obvious kinematic reasons. There exists a gravitational backreaction effect that also damps the metric perturbations on those scales. Instead, on scales much larger than the free-streaming scale the neutrino velocity can be effectively considered as vanishing and after the non-relativistic transition the neutrino perturbations behave like CDM perturbations. In particular, modes with k < knr are never affected by free-streaming and evolve like in a pure ΛCDM model. . 7 3. Impact of massive neutrinos on the matter power spectrum. – The small initial cosmological perturbations in the early Universe evolve, under the linear regime at any scale at early times and on the largest scales more recently, and produce the structures we see today. We will not review here all the details (see [6] and references therein), but we will emphasize the main effects caused by massive neutrinos in the framework of the standard cosmological scenario: a Λ Mixed Dark Matter (ΛMDM) model, where Mixed refers to the inclusion of some HDM component. First let us describe the changes in the background evolution of the Universe. We have seen that massless neutrinos are always part of the radiation content, so in this case the present value of the matter contribution Ω0m is equal to the contribution of CDM and baryons. Instead, massive neutrinos contribute to radiation at early times but to matter after becoming non-relativistic. Thus with respect to the massless neutrino case, massive neutrinos also contribute to Ω0m , reducing the values of Ω0CDM and Ω0b . As a result, if these massive neutrinos have not yet become non-relativistic at the time of radiation/matter equality (the epoch of the Universe when its starts to be dominated by matter and the contribution of radiation becomes subdominant), then this transition is delayed. The consequence of a late equality for the LSS matter power spectrum is the following: since on sub-Hubble scales the matter density contrast δm grows more efficiently during MD than during RD, the matter power spectrum is suppressed on small scales relatively to large scales. At the perturbation level, we also saw that free-streaming damps small-scale neutrino density fluctuations. This produces a direct effect on the matter power spectrum

205

Cosmological probes of neutrino masses

(see sect. 4.5 of [6]) that depends on the value k with respect to knr in eq. (29),  (30)

P (k) =  = =

δρcdm + δρb + δρν ρcdm + ρb + ρν

2 

Ωcdm δcdm + Ωb δb + Ων δν Ωcdm + Ωb + Ων

 2 δcdm ,

2 , [1 − Ων /Ωm ]2 δcdm

2 

for k < knr , for k  knr ,

with Ωm ≡ Ωcdm + Ωb + Ων . Thus the role of the neutrino masses would be simply to cut the power spectrum by a factor [1 − Ων /Ωm ]2 for k  knr . However, it turns out that the presence of neutrinos actually modifies the evolution of the CDM and baryon density contrasts in such way that the suppression factor is greatly enhanced, more or less by a factor four. In conclusion, the combined effect of the shift in the time of equality and of the reduced CDM fluctuation growth during matter domination produces an attenuation of small-scale perturbations for k > knr . It can be shown that for small values of fν this effect can be approximated in the large k limit by the well-known linear expression [44] (31)

P (k)fν

1 − 8 fν . P (k)fν =0

For the comparison with the data, one could use instead some better analytical approximations to the full MDM or ΛMDM matter power spectrum, valid for arbitrary scales and redshifts, as listed in [6]. However, nowadays the analyses are performed using the matter power spectra calculated by Boltzmann codes such as cmbfast [45] or camb [46], that solve numerically the evolution of the cosmological perturbations. An example of P (k) with and without massive neutrinos is shown in fig. 5, where the effect of mν at large k’s can be clearly visible. Such suppression is probably better seen in fig. 6, where we plot the ratio of the matter power spectrum for ΛMDM over that of ΛCDM, for different values of fν and three degenerate massive neutrinos, but for fixed parameters (ωm , ΩΛ ). For large k’s, eq. (31) is a reasonable first-order approximation for 0 < fν < 0.07. Is it possible to mimic the effect of massive neutrinos on the matter power spectrum with some combination of other cosmological parameters? If so, one would say that a parameter degeneracy exists, reducing the sensitivity to neutrino masses. This possibility depends on the interval [kmin , kmax ] in which the P (k) can be accurately measured. Ideally, if we could have kmin ≤ 10−2 h Mpc−1 and kmax ≥ 1 h Mpc−1 , the effect of the neutrino mass would be non-degenerate, because of its very characteristic step-like effect. In contrast, other cosmological parameters like the scalar tilt or the tilt running change the spectrum slope on all scales. The problem is that usually the matter power spectrum can only be accurately measured in the intermediate region where the mass

206

S. Pastor 1.2 knr

0.8 0.6

f

P(k) ν / P(k) ν

f =0

1

0.4 0.2 0 10-4

10-3

10-2 10-1 k (h/Mpc)

1

Fig. 6. – Ratio of the matter power spectrum including three degenerate massive neutrinos with density fraction fν to that with three massless neutrinos. The parameters (ωm , ΩΛ ) = (0.147, 0.70) are kept fixed, and from top to bottom the curves correspond to fν = 0.01, 0.02, 0.03, . . . , 0.10. The individual masses mν range from 0.046 to 0.46 eV, and the scale knr from 2.1 × 10−3 h Mpc−1 to 6.7 × 10−3 h Mpc−1 as shown on the top of the figure. From [6].

effect is neither null nor maximal: in other words, many experiments only have access to the transition region in the step-like transfer function. In this region, the neutrino mass affects the slope of the matter power spectrum in a way which can be easily confused with the effect of other cosmological parameters. Because of these parameter degeneracies, the LSS data alone cannot provide significant constraints on the neutrino mass, and it is necessary to combine them with other cosmological data, in particular the CMB anisotropy spectrum, which could lift most of the degeneracies. Still, for exotic models with, e.g., extra relativistic degrees of freedom, a constant equation-of-state parameter of the dark energy different from −1 or a non-power-law primordial spectrum, the neutrino mass bound can become significantly weaker. . 7 4. Impact of massive neutrinos on the CMB anisotropy spectrum. – For neutrino masses of the order of 1 eV (about fν ≤ 0.1) the three neutrino species are still relativistic at the time of photon decoupling, and the direct effect of free-streaming neutrinos on the evolution of the baryon-photon acoustic oscillations is the same in the ΛCDM and ΛMDM cases. Therefore, the effect of the mass is indirect, appearing only at the level of the background evolution: the fact that the neutrinos account today for a fraction Ων of the critical density implies some change either in the present value of the spatial curvature, or in the relative density of other species. If neutrinos were heavier than a few eV, they would already be non-relativistic at decoupling. This case would have more complicated consequences for the CMB, as described in [47]. However, we will see later that this situation is disfavoured by current upper bounds on the neutrino mass.

Cosmological probes of neutrino masses

207

Let us describe one example: we choose to maintain a flat Universe (the sum of all Ωi is one) with fixed (ωb = Ωb h2 , ωm = Ωm h2 , ΩΛ ). Thus, while Ωb and ΩΛ are constant, Ωcdm is constrained to decrease as Ων increases. The main effect on the CMB anisotropy spectrum results from a change in the time of equality. Since neutrinos are still relativistic at decoupling, they should be counted as radiation instead of matter around the time of equality, which is found by solving ρb + ρcdm = ργ + ρν . This gives aeq = Ωr /(Ωb +Ωcdm ), where Ωr stands for the radiation density extrapolated until today assuming that all neutrinos would remain massless, given by eq. (12) with Neff 3.04. So, when fν increases, aeq increases proportionally to [1 − fν ]−1 : equality is postponed. This produces an enhancement of small-scale perturbations, especially near the first acoustic peak. Also, postponing the time of equality increases slightly the size of the sound horizon at recombination. These two features explain why in fig. 5 the acoustic peaks are slightly enhanced and shifted to the left in the ΛMDM case. Since the effect of the neutrino mass on CMB fluctuations is indirect and appears only at the background level, one could think that by changing the value of other cosmological parameters it would be possible to cancel exactly this effect (i.e. a parameter degeneracy). It can be actually shown that in the simplest ΛMDM model, with only seven cosmological parameters, one cannot vary the neutrino mass while keeping fixed aeq and all other quantities governing the CMB spectrum. Therefore, it is possible to constrain the neutrino mass using CMB experiments alone [48, 6], although neutrinos are still relativistic at decoupling. This conclusion can be altered in more complicated models with extra cosmological parameters. For instance, allowing for an open Universe or varying the number of relativistic degrees of freedom. In such extended models the CMB alone is not sufficient for constraining the mass, but fortunately the LSS power spectrum can lift the degeneracy. 8. – Current bounds on neutrino masses In this section we review how the available cosmological data is used to get information on the absolute scale of neutrino masses, complementary to laboratory experiments. Note that the bounds in the next subsections are all based on the Bayesian inference method, and the upper bounds on the sum of neutrino masses are given at 95% CL after marginalization over all free cosmological parameters. We refer the reader to sect. 5.1 of [6] for a detailed discussion on this statistical method, as well as for most of the references for the experimental data or parameter analysis. . 8 1. CMB anisotropies. – The experimental situation of the measurement of the CMB anisotropies is dominated by the five-year release of WMAP data (WMAP5), which improved the already precise TT and TE angular power spectra of the previous data releases (WMAP3 and WMAP1), and adds a detection of the E-polarization self-correlation spectrum (EE). On similar or smaller angular scales than WMAP, we have results from experiments that are either ground-based (ACBAR, VSA, CBI, DASI, . . . ) or balloonborne (ARCHEOPS, BOOMERANG, MAXIMA, . . . ). When using data from different

208

S. Pastor

CMB experiments, one should take into account that they overlap in some multipole region, and not all data are uncorrelated. More details can by found in [43]. We saw in the previous section that the signature on the CMB spectrum of a neutrino mass smaller than 0.5 eV is small but does not vanish due to a background effect, proportional to Ων , which changes some characteristic times and scales in the evolution of the Universe, and affects mainly the amplitude of the first acoustic peak as well as the location of all the peaks. Therefore, it is possible to constrain neutrino masses using CMB experiments only, down to the level at which this background effect is masked by instrumental noise, or by cosmic variance, or by parameter degeneracies in the case of some cosmological models beyond the minimal Λ Mixed Dark matter framework. Here it is assumed that the total neutrino mass was the only additional parameter with respect to a flat ΛCDM cosmological model characterized by 6 parameters (this will be the case for the bounds reviewed in this section, unless specified otherwise). In this framework, many analyses support the conclusion that a sensible bound on neutrino  masses exists using CMB data only, of order of 2–3 eV for the total mass Mν ≡ i mi (depending on the data included in addition to WMAP data). The most recent analyses found an upper limit of Mν < 1.2–1.3 eV [49, 50, 39]. This is an important result, since it does not depend on the uncertainties from LSS data discussed next. . 8 2. Galaxy redshift surveys. – We have seen that free streaming of massive neutrinos produces a direct effect on the formation of cosmological structures. As shown in fig. 6, the presence of neutrino masses leads to an attenuation of the linear matter power spectrum on small scales. In a seminal paper [44] it was shown that an efficient way to probe neutrino masses of order eV was to use data from large redshift surveys, which measure the distance to a large number of galaxies, giving us a three-dimensional picture of the universe. At present, we have data from two large projects: the 2 degree Field (2dF) galaxy redshift survey, whose final results were obtained from more than 220000 galaxy redshifts, and the Sloan Digital Sky Survey (SDSS), which will be completed soon with data from one million galaxies. One of the main goals of galaxy redshift surveys is to reconstruct the power spectrum of matter fluctuations on very large scales, whose cosmological evolution is described entirely by linear perturbation theory. However, the linear power spectrum must be reconstructed from individual galaxies which underwent a strongly non-linear evolution. A simple analytic model of structure formation suggests that on large scales, the galaxygalaxy correlation function should be, not equal, but proportional to the linear matter density power spectrum, up to a constant factor that is called the light-to-mass bias (b). This parameter can be obtained from independent methods, which tend to confirm that the linear biasing assumption is correct, at least in first approximation. A conservative way to use the measurements of galaxy-galaxy correlations in an analysis of cosmological data is to take the bias as a free parameter, i.e. to consider only the shape of the matter power spectrum at the corresponding scales and not its amplitude (denoted as galaxy clustering data). An upper limit on Mν between 0.8 and 1.7 eV is found from the analysis of galaxy clustering data (SDSS and/or 2dF, leaving the bias

Cosmological probes of neutrino masses

209

as a free parameter) added to CMB data. These values improve those found with CMB data only. In general, one obtains weaker bounds on neutrino masses using preliminary SDSS results instead of 2dF data, but this conclusion could change after the next SDSS releases. The bounds on neutrino masses are more stringent when the amplitude of the matter power spectrum is fixed with a measurement of the bias, instead of leaving it as a free parameter. The upper limits on Mν are reduced to values of order 0.5–0.9 eV although some analyses also add Lyman-α data (see next subsection). Finally, a galaxy redshift survey performed in a large volume can also be sensitive to the imprint created by the baryon acoustic oscillations (BAO) at large scales on the power spectrum of non-relativistic matter. Since baryons are only a subdominant component of the non-relativistic matter, the BAO feature is manifested as a small single peak in the galaxy correlation function in real space that was recently detected from the analysis of the SDSS luminous red galaxy (LRG) sample. The observed position of this baryon oscillation peak provides a way to measure the angular diameter distance out to the typical LRG redshift of z = 0.35, which in turn can be used to constrain the parameters of the underlying cosmological model. The SDSS measurement was included by [51] to get a bound of 0.44 eV on the total neutrino mass Mν , while an upper limit of Mν < 0.61 eV was recently found [50] including BAO but without data on the shape of the galaxy power spectra. . 8 3. Lyman-α forest. – The matter power spectrum on small scales can also be inferred from data on the so-called Lyman-α forest. This corresponds to the Lyman-α absorption of photons traveling from distant quasars (z ∼ 2–3) by the neutral hydrogen in the intergalactic medium. As an effect of the Universe expansion, photons are continuously red-shifted along the line of sight, and can be absorbed when they reach a wavelength of 1216 ˚ A in the rest frame of the intervening medium. Therefore, the quasar spectrum contains a series of absorption lines, whose amplitude as a function of wavelength traces back the density and temperature fluctuations of neutral hydrogen along the line of sight. It is then possible to infer the matter density fluctuations in the linear or quasi-linear regime. In order to use the Lyman-α forest data, one needs to recover the matter power spectrum from the spectrum of the transmitted flux, a task that requires the use of hydro-dynamical simulations for the corresponding cosmological model. This is a difficult procedure, and given the various systematics involved in the analysis, the robustness of Lyman-α forest data is still a subject of intense discussion between experts. In any case, the recovered matter power spectrum is again sensitive to the suppression of growth of mass fluctuations caused by massive neutrinos, and in many cosmological analyses the Lyman-α data is added to CMB and other LSS data. For a free bias, one finds that Lyman-α data help to reduce the upper bounds on the total neutrino mass to the level Mν < 0.5–0.7 eV. But those analyses that include Lyman-α data and a measurement of the bias do not always lead to a lower limit, ranging from 0.4 to 0.7 eV. Finally, [51] found the upper bound Mν < 0.30 eV adding simultaneously Lyα and BAO data, both from SDSS.

210

S. Pastor Present bounds

3

CMB only

Total neutrino mass MQ (eV)

+ 2dF/SDSS-gal

1

+ bias and/or Ly-D and/or SDSS-BAO

0.3

0.1

Inverted Normal 0.03 0.001

0.01 0.1 lightest mQ (eV)

1

Fig. 7. – Current upper bounds (95%CL) from cosmological data on the sum of neutrino masses, compared to the values in agreement at a 3σ level with neutrino oscillation data in eq. (18). From [6].

. 8 4. Summary and discussion of current bounds. – The upper bounds on Mν from the previous subsections are representative of an important fact: a single cosmological bound on neutrino masses does not exist. A graphical summary is presented in fig. 7, where the cosmological bounds correspond to the bands, which were grouped according to the included set of data and whose thickness roughly describes the spread of values obtained from similar cosmological data: 1.3–3 eV for CMB only, 0.9–1.7 eV for CMB and 2dF/SDSS-gal or 0.2–0.9 eV with the inclusion of a measurement of the bias and/or Lyman-α forest data and/or the SDSS measurement of the baryon oscillation peak. For a recent discussion on the dependence of the upper limits on the considered set of cosmological data, see, e.g., [39]. Note that it is usual to add other measurements of cosmological parameters to CMB and LSS data. Probably the most important case is the measurement of the present value of the Hubble parameter by the Key Project of the Hubble Space Telescope [52], giving h = 0.72 ± 0.08 (1σ), which excludes low values of h and leads to a stronger upper bound on the total neutrino mass. In addition, one can include the constraints on the current density of the dark-energy component deduced from the redshift dependence of type-Ia supernovae (SNIa) luminosity, which measures the late evolution of the expansion rate of the Universe [53]. For a flat Universe with a cosmological constant, these constraints can be translated into bounds for the matter density Ωm . One can see from fig. 7 that current cosmological data probe the region of neutrino masses where the 3 neutrino states are degenerate, with a mass Mν /3. This mass region is conservatively bounded to values below approximately 1 eV from CMB results

Cosmological probes of neutrino masses

211

combined only with galaxy clustering data from 2dF and/or SDSS (i.e. the shape of the matter power spectrum for the relevant scales). The addition of further data leads to an improvement of the bounds, which reach the lowest values when data from Lyman-α and/or the SDSS measurement of the baryon oscillation peak are included or the bias is fixed. In such cases the contribution of a total neutrino mass of the order 0.2–0.6 eV seems already disfavoured. It is interesting to compare these bounds with those coming from tritium beta decay and neutrinoless double beta decay, as recently done in [21, 39]. Finally, we remind the reader that the impressive cosmological bounds on neutrino masses shown in fig. 7 may change if additional cosmological parameters, beyond those included in the minimal ΛCDM, are allowed. This could be the case whenever a new parameter degeneracy with the neutrino masses arises. For instance, in the presence of extra radiation parametrized by a larger Neff the bound on Mν gets less stringent [54]. Another possible parameter degeneracy exists between neutrino masses and the parameter w, that characterizes the equation of state of the dark-energy component X (pX = wρX ). This degeneracy can be broken adding data on baryon acoustic oscillations [51]. Finally, the cosmological implications of neutrino masses could be very different if the spectrum or evolution of the cosmic neutrino background was non-standard (see the discussion in sect. 5.7 of [6]). 9. – Future sensitivities on neutrino masses from cosmology In the near future we will have more precise data on cosmological observables from various experimental techniques and experiments. If the characteristics of these future experiments are known with some precision, it is possible to assume a “fiducial model”, i.e. a cosmological model that would yield the best fit to future data, and to estimate the error bar on a particular parameter that will be obtained after marginalizing the hypothetical likelihood distribution over all the other free parameters. Technically, the simplest way to forecast this error is to compute a Fisher matrix, a technique has been widely used in the literature, for many different models and hypothetical datasets, now complemented by Monte Carlo methods. Here we will focus on the results for σ(Mν ), the forecast 68% CL error on the total neutrino mass, assuming various combinations of future observations: CMB anisotropies measured with ground-based experiments or satellites such as Planck, galaxy redshift surveys, galaxy cluster surveys, . . . . In particular, the potentiality for measuring small neutrino masses of weak lensing experiments has been recently emphasized, which will look for the lensing effect caused by the large-scale structure of the neighboring universe, either on the CMB signal [55, 56] or on the apparent shape of galaxies as measured by cosmic shear surveys, see, e.g., [57, 58]. For these two observables we refer the reader to sect. 6 of [6] for further details. We give a graphical summary of the forecast sensitivities to neutrino masses of different cosmological data in fig. 8, compared to the allowed values of neutrino masses in the two possible 3-neutrino schemes. One can see from this figure that there are very good prospects for testing neutrino masses in the degenerate and quasi-degenerate mass regions above 0.2 eV or so. A detection at a significant level of the minimal value of the

212

S. Pastor

3

3

PLANCK

1

CMBpol or PLANCK+SDSS

0.3

2V sensitivities including CMB lensing / cosmic shear surveys

Inverted Normal

6mi (eV)

6mi (eV)

1

2V sensitivities without weak lensing

CMBpol+SDSS

0.1

0.3

PLANCK lensing + S300/S1000

0.1 Inverted Normal

0.03 0.001

0.01 0.1 lightest mQ (eV)

1

PLANCK lensing

0.03 0.001

CMBpol lensing CMBpol lensing + G2S/G4S

0.01 0.1 lightest mQ (eV)

1

Fig. 8. – Forecast 2σ sensitivities to the total neutrino mass from future cosmological experiments compared to the values in agreement with present neutrino oscillation data in eq. (18) (assuming a future determination at the 5% level). Left: sensitivities expected for future CMB experiments (without lensing extraction), alone and combined with the completed SDSS galaxy redshift survey. Right: sensitivities expected for future CMB experiments including lensing information, alone and combined with future cosmic shear surveys. Here CMBpol refers to a hypothetical CMB experiment roughly corresponding to the Inflation Probe mission. From [6].

total neutrino mass in the inverted hierarchy scheme will demand the combination of future data from CMB lensing and cosmic shear surveys, whose more ambitious projects will provide a 2σ sensitivity to the minimal value in the case of normal hierarchy (of order 0.05 eV). The combination of CMB observations with future galaxy cluster surveys [59], derived from the same weak lensing observations, as well as X-ray and Sunyaev-Zel’dovich surveys, should yield a similar sensitivity. Finally, before concluding we would like to briefly comment on a new cosmological observable that can potentially probe small-scale modifications of the matter power spectrum at intermediate redshifts (20 < z < 6). It has been shown [60, 61] that the study of fluctuations in the 21 cm line emitted by neutral H could provide stronger constraints on neutrino masses than even very large galaxy surveys, thanks in part to the fact that at higher redshifts the problem of non-linearities becomes less important. The authors of [61] conclude that future low-frequency radio observations could enhance the sensitivity to neutrino masses down to the 0.01 eV scale. 10. – Conclusions Neutrinos, despite the weakness of their interactions and their small masses, can play an important role in Cosmology that we have reviewed in this contribution. In addition,

213

Cosmological probes of neutrino masses

cosmological data can be used to constrain neutrino properties, providing information on these elusive particles that complements the efforts of laboratory experiments. In particular, the data on cosmological observables have been used to bound the effective number of neutrinos (including a potential extra contribution from other relativistic particles). But probably the most important contribution of Cosmology to our knowledge of neutrino properties is the information it can provide on the absolute scale of neutrino masses. We have seen that the analysis of cosmological data can lead to either a bound or a measurement of the sum of neutrino masses, an important result complementary to terrestrial experiments such as tritium beta decay and neutrinoless double-beta decay experiments. In the next future, thanks to the data from new cosmological experiments, we could even hope to test the minimal values of neutrino masses guaranteed by the present evidences for flavour neutrino oscillations. For this and many other reasons, we expect that neutrino cosmology will remain an active research field in the next years. ∗ ∗ ∗ I thank the organizers of the International School of Physics “Enrico Fermi” for their invitation and hospitality. Many of the topics discussed here were developed in an enjoyable collaboration with J. Lesgourgues. This work was supported by the European Union (contracts No. RII3-CT-2004-506222 and MRTN-CT-2004-503369) and the Spanish grant FPA2005-01269, as well as by a Ram´ on y Cajal contract of MEC.

REFERENCES [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21]

Dolgov A. D., Phys. Rep., 370 (2002) 333. Riotto A., this volume, p. 341. Hannestad S., New J. Phys., 6 (2004) 108. Elgarøy Ø. and Lahav O., New J. Phys., 7 (2005) 61. Hannestad S., Annu. Rev. Nucl. Part. Sci., 56 (2006) 137. Lesgourgues J. and Pastor S., Phys. Rep., 429 (2006) 307. Kamionkowski M. and Kosowsky A., Annu. Rev. Nucl. Part. Sci., 49 (1999) 77. Kolb E. W. and Turner M. S., The Early Universe (Addison-Wesley) 1990. Dodelson S., Modern Cosmology (Academic Press) 2003. Mangano G. et al., Nucl. Phys. B, 729 (2005) 221. Steigman G., Int. J. Mod. Phys. E, 15 (2006) 1. Sarkar S., Rep. Prog. Phys., 59 (1996) 1493. Cuoco A. et al., Int. J. Mod. Phys. A, 19 (2004) 4431. Yao W. M. et al. (Particle Data Group), J. Phys. G, 33 (2006) 1. Mangano G. et al., J. Cosmol. Astroparticle Phys., 0703 (2007) 006. Hamann J. et al., J. Cosmol. Astroparticle Phys., 0708 (2007) 021. Ichikawa K., Sekiguchi T. and Takahashi T., Phys. Rev. D, 78 (2008) 083526. Simha V. and Steigman G., J. Cosmol. Astroparticle Phys., 0806 (2008) 016. Strumia A., this volume, p. 21. Maltoni M. et al., New J. Phys., 6 (2004) 122. Fogli G. L. et al., Prog. Part. Nucl. Phys., 57 (2006) 742.

214

S. Pastor

[22] [23] [24] [25] [26] [27]

´lez-Garc´ıa M. C., Phys. Rep., 460 (2008) 1. Maltoni M. and Gonza Hansen S. H. et al., Phys. Rev. D, 65 (2002) 023511. Dolgov A. D. et al., Nucl. Phys. B, 632 (2002) 363. Serpico P. D. and Raffelt G. G., Phys. Rev. D, 71 (2005) 127301. Kishimoto C. T. and Fuller G. M., Phys. Rev. D, 78 (2008) 023524. Kirilova D. P. and Panayotova M. P., J. Cosmol. Astroparticle Phys., 0612 (2006) 014. Dolgov A. D. and Villante F. L., Nucl. Phys. B, 679 (2004) 261. Cirelli M. et al., Nucl. Phys. B, 708 (2005) 215. Aguilar A. et al. (LSND Collaboration), Phys. Rev. D, 64 (2001) 112007. Aguilar-Arevalo A. A. et al. (MiniBooNE Collaboration), Phys. Rev. Lett., 98 (2007) 231801. ´ G., this volume, p. 269. Senjanovic Vogel P., this volume, p. 49. Frekers D., this volume, p. 175. Poves A., this volume, p. 163. Giuliani A., this volume, p. 141. Gatti F., this volume, p. 323. Weinheimer C., this volume, p. 215. Fogli G. L. et al., Phys. Rev. D, 78 (2008) 033010. Primack J. R., preprint arXiv:astro-ph/0112336. Viel M. et al., Phys. Rev. Lett., 97 (2006) 071301. Palazzo A. et al., Phys. Rev. D, 76 (2007) 103511. de Bernardis P., this volume, p. 245. Hu W. et al., Phys. Rev. Lett., 80 (1998) 5255. Seljak U. and Zaldarriaga M., Astrophys. J., 469 (1996) 437; see also the webpage http://cmbfast.org. Lewis A., Challinor A. and Lasenby A., Astrophys. J., 538 (2000) 473; see also the webpage http://camb.info. Dodelson S., Gates E. and Stebbins A., Astrophys. J., 467 (1996) 10. Ichikawa K. et al., Phys. Rev. D, 71 (2005) 043001. Dunkley J. et al. (WMAP Collaboration), preprint arXiv:0803.0586. Komatsu E. et al. (WMAP Collaboration), preprint arXiv:0803.0547. Goobar A. et al., J. Cosmol. Astroparticle Phys., 0606 (2006) 019. Freedman W. L. et al. (HST Collaboration), Astrophys. J., 553 (2001) 47. Astier P. et al. (SNLS Collaboration), Astron. Astrophys., 447 (2006) 31. Crotty P., Lesgourgues J. and Pastor S., Phys. Rev. D, 69 (2004) 123007. Lesgourgues J. et al., Phys. Rev. D, 73 (2006) 045021. Perotto L. et al., J. Cosmol. Astroparticle Phys., 0610 (2006) 013. Song Y. S. and Knox L., Phys. Rev. D, 70 (2004) 063510. Hannestad S., Tu H. and Wong Y. Y. Y., J. Cosmol. Astroparticle Phys., 0606 (2006) 025. Wang S. et al., Phys. Rev. Lett., 95 (2005) 011302. Loeb A. and Wyithe S., Phys. Rev. Lett., 100 (2008) 161301. Pritchard J. R. and Pierpaoli E., Phys. Rev. D, 78 (2008) 065009.

[28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40] [41] [42] [43] [44] [45] [46] [47] [48] [49] [50] [51] [52] [53] [54] [55] [56] [57] [58] [59] [60] [61]

DOI 10.3254/978-1-60750-038-4-215

Direct determination of neutrino mass from 3 H β-spectrum C. Weinheimer(∗ ) Institut f¨ ur Kernphysik, Westf¨ alische Wilhelms-Universit¨ at M¨ unster D-48149 M¨ unster, Germany

Summary. — The investigation of the endpoint region of the tritium β decay spectrum is still the most sensitive direct method to determine the neutrino mass scale. In the nineties and the beginning of this century the tritium β decay experiments at Mainz and Troitsk reached a sensitivity on the neutrino mass of 2 eV/c2 . They were using a new type of high-resolution spectrometer with large sensitivity, the MACE-Filter, and were studying the systematics in detail. Currently, the KATRIN experiment is being set up at Forschungszentrum Karlsruhe, Germany. KATRIN will improve the neutrino mass sensitivity by one order of magnitude down to 0.2 eV/c2 , sufficient to cover the degenerate neutrino mass scenarios and the cosmologically relevant neutrino mass range.

1. – Introduction We know from neutrino oscillation experiments that the different neutrino flavors mix and can oscillate during flight from one flavor state into another. The analysis of all neutrino oscillation experiments yields the mixing angles and the differences of squared neutrino mass eigenstates [1]. Clearly these findings prove that neutrinos have (∗ ) E-mail: [email protected] c Societ`  a Italiana di Fisica

215

216

C. Weinheimer

Fig. 1. – Neutrino mass eigenvalues m(νi ) (solid P lines) and one third of the cosmologically relevant sum of the three neutrino mass eigenvalues m(νi )/3 (dashed line) as a function of the smallest neutrino mass eigenvalue mmin for normal hierarchy m(ν3 ) > m(ν2 ) > m(ν1 ) (left) and inverted hierarchy m(ν2 ) > m(ν1 ) > m(ν3 ) (right). The upper limit from the tritium β decay experiments at Mainz and Troitsk on P m(νe ) (solid line), which holds in the degenerate neutrino mass region for each m(νi ), and for m(νi )/3 (dashed line) is also marked. P The hot dark-matter m(νi )/3 is indicated contribution Ων of the universe relating to the average neutrino mass by the right scale in the normal hierarchy plot and compared to all other known matter/energy contributions in the universe (middle). With the relic neutrino density of 336/cm3 the laboratory neutrino mass limit from tritium β decay m(νe ) < 2 eV/c2 corresponds to a maximum allowed neutrino matter contribution in the universe of Ων < 0.12.

non-zero masses, but such “interference experiments” cannot probe the absolute mass scale. We have to parametrize our ignorance by a free parameter mmin , the mass of the smallest neutrino mass eigenstate (see fig. 1). The huge abundance of neutrinos left over in the universe from the Big Bang (336/cm3 ) and their contribution to structure formation [2] as well as the key role of neutrino masses in finding the new Standard Model of particle physics [3, 4] make the absolute value of the neutrino mass one of the most urgent questions of astroparticle physics and cosmology as well as of nuclear and particle physics. There exist 3 different approaches to the absolute neutrino mass scale: – Cosmology Essentially the size of fluctuations is observed at different scales by using cosmic microwave background and large scale structure data. Since the light neutrinos would have smeared out fluctuations at small scales, the power spectrum at small scales is sensitive to the neutrino mass. Up to now, only limits on the sum of the  3 neutrino masses have been obtained around m(νi ) < 0.61 eV/c2 [5], which are to some extent model and analysis dependent [2, 6].

Direct determination of neutrino mass from 3 H β-spectrum

217

– Neutrinoless double β decay (0νββ) A neutrinoless double β decay (two β decays in the same nucleus at the same time with emission of two β electrons (positrons) while the (anti)neutrino emitted at one vertex is absorbed at the other vertex as a neutrino (antineutrino)) is forbidden in the Standard Model of particle physics. It could exist, if the neutrino is its own antiparticle (“Majorana-neutrino” in contrast to “Dirac-neutrino”). Furthermore, a finite neutrino mass is required in order to produce in the chirality-selective interaction a neutrino with a small component of opposite handedness on which this neutrino exchange subsists. The decay rate would scale with the absolute square of the so-called effective neutrino mass, which takes into account the neutrino mixing matrix U :  2   (1) Γ0νββ ∝  Uei2 m(νi ) := mee 2 . Here mee represents the coherent sum of the m(νi ) components of the 0νββ decay amplitudes and hence carries their relative phases (the usual CP -violating phase of a unitary 3 × 3 mixing matrix plus two so-called Majorana phases). A significant additional uncertainty which enters the relation of mee and the decay rate is the nuclear matrix element of the neutrinoless double β decay. There is one claim for evidence at mee ≈ 0.4 eV/c2 by part of the Heidelberg-Moscow collaboration [7] and limits from different experiments in the 1 eV/c2 range [8]. – Direct neutrino mass determination The direct neutrino mass determination is based purely on relativistic kinematics without further assumptions. Therefore it is sensitive to the neutrino mass squared m2 (ν). In principle there are two methods: time-of-flight measurements and precision investigations of weak decays. The former requires very long baselines and therefore very strong sources, which only cataclysmic cosmological events like a core-collapse supernova could provide. The non-observation of the dependence of the arrival time on the energy of supernova neutrinos from SN1987a gave an upper limit on the neutrino mass of 5.7 eV/c2 [9]. Unfortunately nearby supernova explosions are too rare and too little understood to allow an improvement into the sub-eV range. Therefore, aiming for this sensitivity, the investigation of the kinematics of weak decays and more explicitly the investigation of the endpoint region of a β decay spectrum is still the most sensitive model-independent and direct method to determine the neutrino mass. Here the neutrino is not observed but the charged decay products are precisely measured. Using energy and momentum conservation the neutrino mass can be obtained. In the case of the investigation of a β spectrum usually the “average electron neutrino mass” m(νe ) is determined (see sect. 2 below):  |Uei2 |m(νi )2 . (2) m(νe )2 := This incoherent sum is not sensitive to the phases of the neutrino mixing matrix.

218

C. Weinheimer

Fig. 2. – Observables of neutrinoless double β decay mee (open band) and of direct neutrino end of the mee mass determination by single β decay m(νe ) (thin gray area sitting at the upper P band) versus the cosmologically relevant sum of neutrino mass eigenvalues m(νi ) for the case of normal hierarchy (left) and of inverted hierarchy (right). The width of the bands/areas is caused by the experimental uncertainties of the neutrino mixing angles [9] and in the case of mee also by the completely unknown Majorana and CP phases. Uncertainties of the nuclear matrix elements, which enter mee , are not considered.

Figure 2 demonstrates that the different methods are complementary to each other and compares them. These lecture notes are structured as follows: In sect. 2 the neutrino mass determination from the kinematics of tritium β decay is described. Section 3 presents the previous tritium β decay experiments, especially the experiments at Mainz and Troitsk. In sect. 4 an overview of the present KATRIN experiment is given. This paper closes with a conclusion in sect. 5. For a more detailed and complete overview on this subject we would like to refer to the reviews [10-13], with [14] being the most recent one. 2. – Neutrino mass from the tritium β decay spectrum According Fermi’s Golden Rule the decay rate for a β decay is given by the square of the transition matrix element M summed and integrated over all possible discrete and continuous final states f (from here on we use the convention h ¯ = 1 = c for simplicity): (3)

Γ = 2π



|M 2 |df.

Let us first calculate the density of the final states. The number of different final states dn of outgoing particles inside a normalization volume V into the solid angle dΩ with momenta between p and p + dp, or, respectively, with energies in the corresponding

Direct determination of neutrino mass from 3 H β-spectrum

219

interval around the total energy Etot , is (4)

dn =

V · p2 · dp · dΩ V · p2 · dp · dΩ V · p · Etot · dEtot · dΩ = = . 3 3 h (2π) (2π)3

This gives a state density per energy interval and solid angle of V · p · Etot dn = . dEtot dΩ (2π)3

(5)

Since the mass of the nucleus is —especially in our case— much larger than the energies of the two emitted leptons, we can use the following simplification: The nucleus takes nearly no energy but balances all momenta. The recoil energy of the daughter nucleus of mass mdaught is bound within the following limits: (6)

0 ≤ Erec =

( p + pν )2 p2max E 2 + 2E0 m ≤ Erec,max = = 0 . 2mdaught 2mdaught 2mdaught

Here we denote without indices the quantities of the electron and with index ν the ones of the neutrinos. Since we will reserve the notation E for the kinetic energy of the β electron, we denote its total energy with Ee . E0 is the maximum kinetic energy the electron can obtain. Therefore we need to count the state density of the electron and the neutrino only (7)

dne dnν V 2 · pe · Ee · pν · Eν · = dEe dΩe dEν dΩν (2π)6   V 2 · Ee2 − m2 · Ee · Eν2 − m2 (νe ) · Eν = . (2π)6

ρ(Ee , Eν , dΩe , dΩν ) =

The transition matrix element M can be divided into a leptonic part, Mlep , and a hadronic one, Mnucl . Usually the coupling is written separately and expressed in terms of Fermi’s coupling constant GF and the Cabibbo angle ΘC : (8)

M = GF · cos ΘC · Mlep · Mnucl .

2 | essenFor an allowed or superallowed decay like that in tritium, the leptonic part |Mlep tially results in the probability of the two leptons to be found at the nucleus, which is 1/V for the neutrino and 1/V · F (E, Z + 1) for the electron, yielding

(9)

2 |Mlep |=

1 · F (E, Z + 1). V2

The Fermi function F (E, Z+1) takes into account the final electromagnetic interaction of the emitted β electron with the daughter nucleus of nuclear charge (Z + 1). The Fermi

220

C. Weinheimer

function is approximately given by [11] (10)

F (E, Z + 1) =

2πη , 1 − exp(−2πη)

with the Sommerfeld parameter η = α(Z + 1)/β. The spin structure and coupling to the nuclear spin, as well as its (β, ν) angular correlation, is usually contracted into the nuclear matrix element. For an allowed or super-allowed transition the hadronic matrix element is independent of the kinetic energy of the electron. Generally it can be divided into a vector current or Fermi part (ΔInucl = 0) and into an axial current or Gamov-Teller part (ΔInucl = ±1). In the former case, the spins of electron and neutrino couple to S = 0, in the latter case to S = 1. Summing over spin states and averaging over the (β, ν) angular correlation factor 1 + a · (β · βν )

(11)

(with the electron velocity β = v/c and the neutrino velocity βν = vν /c), the hadronic matrix element for tritium is [10] 2 |Mnucl (tritium)| = 5.55.

(12)

The phase space density (7) is distributed over a surface in the two-particle phase space which is defined by a δ-function conserving the decay energy. With this prescription, we can integrate (3) over the continuum states and get the partial decay rate into a single channel; for instance, the ground state of the daughter system with probability P0 

(13)

2 G2F · cos2 ΘC · |Mnucl |· · F (E, Z + 1) 5 (2π) Etot ,Etot,ν ,Ω,Ων     ·β ν ) · Ee2 − m2 · Ee · Eν2 − m2 (νe ) · Eν · 1 + a · (β

Γ 0 = P0 ·

· δ(Q + m − Etot − Etot,ν − Erec ) dEtot dEtot,ν dΩ dΩν . A correct integration over the unobserved neutrino variables in (13) has to respect the (β, ν) angular correlation factor (11), which enters the recoil energy (6). The variation of Erec near the endpoint is tiny [15]. Even for the most sensitive tritium β decay experiment, the upcoming KATRIN experiment, the variation of Erec over the energy interval of investigation (the last 25 eV below the endpoint) can be neglected and replaced with a constant value of Erec = 1.72 eV, yielding a fixed endpoint [16] (14)

E0 = Q − Erec .

We can then integrate over Etot,ν simply by fixing it through the δ-function to the missing energy Etot,ν = (E0 − E): the difference between endpoint energy E0 and kinetic

Direct determination of neutrino mass from 3 H β-spectrum

221

energy E of the β electron. Further integration over the angles yields through (11) an averaged nuclear matrix element, as mentioned above. Besides integrating over the (β, ν)-continuum, we have to sum over all other final states. It is a double sum, one over the 3 neutrino mass eigenstates m(νi ) with probabilities |Uei2 |, the other over all of the electronic final states of the daughter system with probabilities Pj and excitation energies Vj . The latter are caused by the sudden change of the nuclear charge and the different nuclear charge of the daughter atom/molecule. They give rise to shifted endpoint energies. Introducing the definition ε := (E0 − E),

(15)

the total neutrino energy now amounts to Etot,ν = ε − Vj . Rather than in the total decay rate, we are interested in its energy spectrum γ = dΓ/dE, which we can read directly from (13) without performing the second integration over the β energy. Written in terms of ε and summed up over the final states it reads (16)

γ=

G2F · cos2 ΘC 2 · |Mnucl | · F (E, Z + 1) 2π 3  · (E0 + m − ε) · (E0 + m − ε)2 − m2   2 · |Uei | · Pj · (ε − Vj ) · (ε − Vj )2 − m2 (νi ) · Θ(ε − Vj − m(νi )). i,j

We directly see the validity of the definition of the average electron neutrino mass squared m2 (νe ) by (2), if the different neutrino mass states cannot be resolved experimentally. The Θ-function confines the spectral components to the physical sector ε−Vj −m(νi ) > 0. This causes a technical difficulty in fitting mass values smaller than the sensitivity limit of the data, as statistical fluctuations of the measured spectrum might occur which can no longer be fitted within the allowed physical parameter space. Therefore, one has to define a reasonable mathematical continuation of the spectrum into the region which leads to χ2 -parabolas around m2 (νi ) ≈ 0 (see, e.g., [15]). But one may equally well use formulas describing a physical model with the signature of a spectrum stretching beyond E0 like tachyonic neutrinos [17] (with the caution, of course, that one should not jump to spectacular conclusions from significant fit values m2 (νi ) < 0 instead of carefully searching for systematic errors in the data). Furthermore, one may apply radiative corrections to the spectrum [18, 19]. However, they are quite small and would influence the result on m2 (νe ) only by few a percent of its present systematic uncertainty. One may also raise the point of whether possible contributions from right-handed currents might lead to measurable spectral anomalies [20, 21]. It has been checked that the present limits on the corresponding right-handed boson mass [9, 22] rule out a sizeable contribution within present experimental uncertainties. Even the forthcoming KATRIN experiment will hardly be sensitive to this problem [23]. The β electrons are leaving the nucleus on a time scale much shorter than the typical Bohr velocities of the shell electrons of the mother isotope. Therefore, the excitation

222

C. Weinheimer

probabilies of electronic states —and of vibrational-rotational excitations in the case of molecules— can be calculated in the so-called sudden approximation from the overlap of the primary electron wave function Ψ0 with the wave functions of the daughter ion Ψf,j Vj = |Ψ0 |Ψf,j |2 .

(17)

We will calculate the first excited electronic states for the case of a decaying tritium atom. The tritium (i.e., hydrogen) wave function for the electronic ground state is Ψ0 = ΨZ=1 100 (r, ϑ, φ) = 

(18)

1 πa30

· e−r/a0 ,

with Bohr radius a0 = 4πε0 /me2 . The final daughter atom is a 3 He+ ion. Therefore its wave functions Ψf,j = ΨZ=2 nlm are hydrogen-like functions with nuclear charge Z = 2. Due to the orthogonality of the spherical harmonics Ylm (ϑ, φ) the overlap intergral (17) can only be non-zero for excited final states Ψf,j = ΨZ=2 n00 . For Z = 2 the first 3 hydrogen-like wave functions are : 8 ΨZ=2 (19) · e−2r/a0 , 100 = πa30 (20)

ΨZ=2 200 = 

(21)

ΨZ=2 300

: =

1 πa30

· (1 − r/a0 ) · e−r/a0 ,

  4r 8r2 8 · e−2r/3a0 . · 1 − + 27πa30 3a0 27a20

We can compute the overlap integral (17) using the following relation:  (22)

∞

rn exp (−r/μ) dr = n! μn+1 .

0

The transition probability P0 to the 3 He+ ground state (n = 1) amounts to

(23)

P0 =

=

=

=

 2 :       8 1 −r/a0 −2r/a0 2    · e · · e · r sin θdθdφ dr 3  % &' (  πa0 πa30  =4π 2  √   8 2    3 · e−3r/a0 r2 dr   a0  √ 2  8 2 2a3     3 · 0  a0 27   √ 2  16 2  512   = 0.702.   =  27  729

Direct determination of neutrino mass from 3 H β-spectrum

223

Fig. 3. – Excitation spectrum of the daugther (3 HeT)+ in β decay of molecular tritium [24].

The transition probability P1 to the first excited state of the 3 He+ ion (n = 2) is

(24)

 2       1 1 −r/a0 −r/a0 2   P1 =  ·e ·  3 · (1 − r/a0 ) · e · r sin θdθdφ dr 3 % &' ( πa0 πa0   =4π 2     4π =  3 · (1 − r/a0 ) · e−2r/a0 · r2 dr πa0  2  3 4 3a3  a =  3 · 2 0 − 0  a0 8 8 2   −1   = 0.25. =  2 

Therefore, the first two electronic final states P0 + P1 comprise already more than 95% of all final states. In addition to the excited states of the 3 He+ ion, there are also continuum states, which are more difficult to compute. The excitation energies of the excited electronic states of the 3 He+ ion are (25)

Z=2 Vn−1 = E(ΨZ=2 n00 ) − E(Ψ100 ) =

m(αZ)2 2

    1 1 1 − 2 = 1 − 2 · 54.4 eV. n n

Thus, the excitation energy to the first excited level is V2 = 40.8 eV. In practice, all tritium sources so far have been using molecular tritium sources, containing the molecule T2 . The wave functions of the tritium molecule are much more complicated, since in addition to two identical electrons they comprise also the description of rotational and vibrational states, which will be excited during the β decay as well. Figure 3 shows a recent numerical calculation of the final states of the T2 molecule.

224

C. Weinheimer

2 const. offset ∼ m ( νe ) 2 := Σ |U ei| m 2( ν ) i i

m ν = 0 eV ∼2 ∗10 −13 m ν = 1 eV

Fig. 4. – Expanded β spectrum around its endpoint E0 for m(νe ) = 0 (dashed line) and for an arbitrarily chosen neutrino mass of 1 eV (solid line). In the case of tritium, the gray-shaded area corresponds to a fraction of 2 · 10−13 of all tritium β decays.

The transition to the electronic ground state of the 3 HeT+ daughter ion is not a single state, but broadened due to rotational-vibrational excitation with a Gaussian standard deviation of σ = 0.42 eV. Secondly the first group of excitated states starts at around Vj = 25 eV. More recent calculations agree to these results [25]. The neutrino mass influences the β spectrum only at the upper end below E0 , where the neutrino is non-relativistic and can exhibit its massive character. The relative influence decreases in proportion to m2 (νe )/ε2 (see fig. 4) leading far below the endpoint to a small constant offset proportional to −m2 (νe ). Figure 4 defines the requirements of a direct neutrino mass experiment which investigates a β spectrum: The task is to resolve the tiny change of the spectral shape due to the neutrino mass in the region just below the endpoint E0 , where the count rate is going to vanish. Therefore, high energy resolution is required combined with large source strength and acceptance as well as low background rate. Now we should firstly discuss what is the best β emitter for such a task. Figure 5 shows the total count rate of a super-allowed β emitter as a function of the endpoint energy. Of course, the total count rate rises strongly with E0 , while the relative fraction in the last 10 eV below E0 decreases. Interestingly, the total count rate in the last 10 eV below E0 , which we can take as our energy region of interest for determining the neutrino mass, is rather stable with regard to E0 . From fig. 5 one might argue that the endpoint energy does not play a significant role in selecting the right β isotope, but we have to consider the fact that we need a certain energy resolution ΔE to determine the neutrino mass. Experimentally it makes a huge difference, whether we have to achieve a certain

Direct determination of neutrino mass from 3 H β-spectrum

225

Fig. 5. – Dependence on the endpoint energy E0 of total count rate (left), relative fraction in the last 10 eV below the endpoint (middle) and total count rate in the last 10 eV of a β emitter (right). These numbers have been calculated for a super-allowed β decay using (16) for m(νe ) = 0 and neglecting possible final states as well as the Fermi function F .

ΔE at a low energy E0 or at a higher one. Secondly, the β electrons of no interest with regard to the neutrino mass could cause experimental problems (e.g. as background or pile-up) and again this arguement favors a low E0 . Therefore, tritium is the standard isotope for this kind of study due to its low endpoint of 18.6 keV, its rather short half-life of 12.3 y, its super-allowed shape of the β spectrum, and its simple electronic structure. Tritium β decay experiments using a tritium source and a separated electron spectrometer have been performed in search for the neutrino mass for more than 50 years. 187 Re is a second isotope suited to determine the neutrino mass. Due to the complicated electronic structure of 187 Re and its primordial half-life of 4.3·1010 y, the advantage of the 7 times lower endpoint energy E0 = 2.47 keV of 187 Re with respect to tritium can only be exploited if the β spectrometer measures the entire released energy, except that of the neutrino. This situation can be realized by using a cryogenic bolometer as the β spectrometer, which at the same time contains the β emitter 187 Re [26]. 3. – Previous tritium neutrino mass experiments The majority of the published direct laboratory results on m(νe ) originates from the investigation of tritium β decay, while only two results from 187 Re have been reported very recently (there are also results from investigations of electron capture [27] and bound state β decay [28], which are about 2 orders of magnitude less stringent on the neutrino mass). In the long history of tritium β decay experiments, about a dozen results have been reported starting with the experiment of Curran in the late forties yielding m2 (νe ) < 1 keV [29]. In the beginning of the eighties a group from the Institute of Theoretical and Experimental Physics (ITEP) at Moscow [30] claimed the discovery of a non-zero neutrino mass of around 30 eV/c2 . The ITEP group used as β source a thin film of tritiated valine combined with a new type of magnetic “Tretyakov” spectrometer. The first results

226

C. Weinheimer

Fig. 6. – Recent results of tritium β decay experiments on the observable m2 (νe ). The experiments at Los Alamos, Z¨ urich, Tokyo, Beijing and Livermore [36-40] used magnetic spectrometers, the tritium experiments at Mainz and Troitsk [41-44] are using electrostatic spectrometers of the MAC-E-Filter type (see text).

testing the ITEP claim came from the experiments at the University of Z¨ urich [31] and the Los Alamos National Laboratory (LANL) [32]. Both groups used similar Tretyakovtype spectrometers, but more advanced tritium sources with respect to the ITEP group. The Z¨ urich group used a solid source of tritium implanted into carbon and later a selfassembling film of tritiated hydrocarbon chains. The LANL group developed a gaseous molecular tritium source avoiding solid-state corrections. Both experiments disproved the ITEP result. The reason for the “mass signal” at ITEP was twofold: the energy loss correction was probably overestimated, and a 3 He-T mass difference measurement [33] confirming the endpoint energy of the ITEP result, turned out only later to be significantly wrong [34, 35]. Also in the nineties tritium β decay experiments yielded controversially discussed results: Figure 6 shows the final results of the experiments at LANL and Z¨ urich together with the results from other more recent measurements with magnetic spectrometers at University of Tokyo, Lawrence Livermore National Laboratory and Beijing. The sensitivity on the neutrino mass have improved a lot but the values for the observable m2 (νe ) populated the unphysical negative m2 (νe ) region. In 1991 and 1994 two new experiments started data taking at Mainz and at Troitsk, which used a new type of electrostatic spectrometer, so-called MAC-E-Filters, which were superior in energy resolution and luminosity with respect to the previous magnetic spectrometers. However, even their early data were confirming the large negative m2 (νe ) values of the LANL and Livermore experiments when being analyzed over the last 500 eV of the β spectrum

Direct determination of neutrino mass from 3 H β-spectrum

227

below the endpoint E0 . But the large negative values of m2 (νe ) disappeared when analyzing only small intervals below the endpoint E0 . This effect, which could only be investigated by the high-luminosity MAC-E-Filters, pointed towards an underestimated or missing energy loss process, seemingly to be present in all experiments. The only common feature of the various experiment seemed to be the calculations of the electronic excitation energies and excitation probabilities of the daughter ions. Different theory groups checked these calculations in detail. The expansion was calculated to one order further and new interesting insight into this problem was obtained, but no significant changes were found [24, 25]. Then the Mainz group found the origin of the missing energy loss process for its experiment. The Mainz experiment used as tritium source a film of molecular tritium quench-condensed onto aluminum or graphite substrates. Although the film was prepared as a homogenous thin film with flat surface, detailed studies showed [45] that the film undergoes a temperature-activated roughening transition into an inhomogeneous film by formation of microcrystals leading to unexpected large inelastic scattering probabilities. The Troitsk experiment on the other hand used a windowless gaseous molecular tritium source, similar to the LANL apparatus. Here, the influence of large-angle scattering of electrons magnetically trapped in the tritium source was not considered in the first analysis. After correcting for this effect the negative values for m2 (νe ) disappeared. The fact that more experimental results of the early nineties populate the region of negative m2 (νe ) values (see fig. 6) can be understood by the following consideration [10]: For ε  m(νe ), eq. (16) can be expanded into (26)

dN ∝ ε2 − m2 (νe )/2 . dE

On the other hand the convolution of a β spectrum (16) with a Gaussian of width σ leads to (27)

dN ∝ ε2 + σ 2 . dE

Therefore, in the presence of a missed experimental broadening with Gaussian width σ one expects a shift of the result on m2 (νe ) of (28)

Δm2 (νe ) ≈ −2 · σ 2 ,

which gives rise to a negative value of m2 (νe ) [10]. . 3 1. MAC-E-Filter. – The significant improvement in the neutrino mass sensitivity by the Troitsk and the Mainz experiments are due to MAC-E-Filters (Magnetic Adiabatic Collimation with an Electrostatic Filter). This new type of spectrometer —based on early work by Kruit [46]— was developed for the application to the tritium β decay at Mainz and Troitsk independently [47, 48]. The MAC-E-Filter combines high luminosity

228

C. Weinheimer

Fig. 7. – Principle of the MAC-E-Filter. Top: experimental setup; bottom: momentum transformation due to adiabatic invariance of the orbital magnetic momentum μ in the inhomogeneous magnetic field.

at low background and a high energy resolution, which are essential features to measure the neutrino mass from the endpoint region of a β decay spectrum. The main features of the MAC-E-Filter are illustrated in fig. 7: two superconducting solenoids are producing a magnetic guiding field. The β electrons, starting from the tritium source in the left solenoid into the forward hemisphere, are guided magnetically on a cyclotron motion along the magnetic field lines into the spectrometer, thus resulting in an accepted solid angle of nearly 2π. On their way into the center of the spectrometer the magnetic field B drops adiabatically by several orders of magnitude keeping the magnetic orbital moment μ invariant (equation given in non-relativistic approximation): (29)

μ=

E⊥ = const. B

Therefore nearly all the cyclotron energy E⊥ is transformed into longitudinal motion (see fig. 7 bottom) giving rise to a broad beam of electrons flying almost parallel to the magnetic field lines. This parallel beam of electrons is energetically analyzed by applying an electrostatic barrier made up by a system of one or more cylindrical electrodes. The relative sharpness of this energy high-pass filter is only given by the ratio of the minimum magnetic

Direct determination of neutrino mass from 3 H β-spectrum

229

Fig. 8. – Transmission function of the KATRIN experiment as a function of the surplus energy E −qU . The KATRIN design settings [60] were used: Bmin = 3·10−4 T, Bmax = 6 T, BS = 3.6 T. The upper horizontal axis illustrates the dependence of the maximum starting angle, which is transmitted at a given surplus energy. Clearly, electrons with larger starting angles reach the transmission condition later, since they still have a significant amount of cyclotron energy in the analysing plane at Bmin .

field Bmin reached at the electrostatic barrier in the so-called analyzing plane and the maximum magnetic field between β electron source and spectrometer Bmax , Bmin ΔE = . E Bmax

(30)

The exact shape of the transmission function can be calculated analytically. For an isotropically emitting source of particles with charge q, it reads

(31)

⎧ 0,  ⎪ ⎪ ⎨ 1− 1− T (E, U ) =  ⎪ ⎪ ⎩ 1− 1−

for E−qU E BS Bmax

,

·

BS Bmin

, for for

E ≤ qU, qU < E < qU + ΔE, E ≥ qU + ΔE.

We assume the electron source to be placed in a magnetic field BS and that the retarding voltage of the spectrometer is U . Figure 8 shows the transmission functions for the settings of the KATRIN experiment (see sect. 4). The β electrons are spiralling around the guiding magnetic field lines in zeroth approximation. Additionally, in non-homogeneous electrical and magnetic fields they feel a small drift u, which reads in first order [47] (c = 1)  (32)

u =

  ×B  (E⊥ + 2E|| )  E  . − (B × ∇⊥ B) B2 e · B3

230

C. Weinheimer

Fig. 9. – The upgraded Mainz setup shown schematically. The outer diameter amounts to 1 m, the distance from source to detector is 6 m.

The two recent tritium β decay experiments at Mainz and at Troitsk use similar MAC-E-Filters with an energy resolution of 4.8 eV (3.5 eV) at Mainz (Troitsk). The spectrometers differ slightly in size: the diameter and length of the Mainz (Troitsk) spectrometer are 1 m (1.5 m) and 4 m (7 m). The major differences between the two setups are the tritium sources: Mainz uses as tritium source a thin film of molecular tritium quench-condensed on a cold graphite substrate, whereas Troitsk has chosen a windowless gaseous molecular tritium source. After the upgrade of the Mainz experiment in 1995-1997 both experiments ran with similar signal and similar background rates. . 3 2. The Mainz neutrino mass experiment. – The Mainz setup was upgraded in 1995-1997 (see fig. 9), including the installation of a new tilted pair of superconducting solenoids between the tritium source and the spectrometer and the use of a new cryostat providing tritium film temperatures of below 2 K. The first measure eliminated sourcecorrelated background and allowed the source strength to be increased significantly. The second measure avoids the roughening transition of the homogeneously condensed tritium films with time [45], which previously gave rise to negative values of m2 (νe ) when the data analysis used large intervals of the β spectrum below the endpoint E0 . The upgrade was completed by the application of HF pulses on one of the electrodes between measurements every 20 s, and a full automation of the apparatus and remote control. This former improvement lowers and stabilizes the background, the latter one allows long-term measurements. Figure 10 shows the endpoint region of the Mainz 1998, 1999 and 2001 data in comparison with the former Mainz 1994 data. An improvement of the signal-to-background ratio by a factor 10 by the upgrade of the Mainz experiment as well as a significant enhancement of the statistical quality of the data by long-term measurements are clearly visible. The main systematic uncertainties of the Mainz experiment are the inelastic scattering of β electrons within the tritium film, the excitation of neighbor molecules due to sudden change of the nuclear charge during β decay, and the self-charging of the tritium film as a consequence of its radioactivity. As a result of detailed investigations in Mainz [49-51, 42] —mostly by dedicated experiments— the systematic corrections

Direct determination of neutrino mass from 3 H β-spectrum

231

Fig. 10. – Averaged count rate of the Mainz 1998/1999 data (filled squares) with fit for m(νe ) = 0 (line) and of the 2001 data (open squares) with fit for m(νe ) = 0 (line) in comparison with previous Mainz data from 1994 (open circles) as a function of the retarding energy near the endpoint E0 and effective endpoint E0,eff (taking into account the width of the response function of the setup and the mean rotation-vibration excitation energy of the electronic ground state of the 3 HeT+ daughter molecule).

became much better understood and their uncertainties were reduced significantly. The high-statistics Mainz data from 1998 to 2001 allowed the first determination of the probability of the neighbor excitation to occur in (5.0 ± 1.6 ± 2.2)% of all β decays [42] in good agreement with the theoretical expectation [52]. The analysis of the last 70 eV below the endpoint of the 1998, 1999 and 2001 data, resulted in [42] (33)

m2 (νe ) = (−0.6 ± 2.2 ± 2.1) eV2 /c4 ,

which corresponds to an upper limit of (34)

m(νe ) < 2.3 eV/c2

(95% C.L.)

This is the lowest model-independent upper limit of the neutrino mass obtained thus far. . 3 3. The Troitsk neutrino mass experiment. – The windowless gaseous tritium source of the Troitsk experiment [44] is essentially a tube of 5 cm diameter filled with T2 resulting in a column density of 1017 molecules/cm2 . The source is connected to the ultrahigh vacuum of the spectrometer by a series a differential pumping stations.

232

C. Weinheimer

From their first measurement in 1994 onwards the Troitsk group has reported the observation of a small, but significant anomaly in its experimental spectra starting a few eV below the β endpoint E0 . This anomaly appears as a sharp step of the count rate [43]. Because of the integrating property of the MAC-E-Filter, this step should correspond to a narrow line in the primary spectrum with a relative intensity of about 10−10 of the total decay rate. In 1998 the Troitsk group reported that the position of this line oscillates with a frequency of 0.5 years between 5 eV and 15 eV below E0 [44]. By 2000 the anomaly did no longer follow the 0.5 year periodicity, but still existed in most data sets. The reason for such an anomaly with these features is not clear. In Mainz a similar behavior has been found only in one run taken under unfavorable conditions [42]. In dedicated measurements at Mainz, synchronously taken with the Troitsk experiment, the anomaly was seen at Troitsk, but not at Mainz. After some experimental inprovements the first two runs of 2001 at Troitsk either gave no indication for an anomaly or only showed a small effect with 2.5 mHz amplitude compared to the previous ones with amplitudes between 2.5 mHz and 13 mHz. These findings as well as the Mainz data clearly support the assumption that the Troitsk anomaly is due to an still unknown experimental artifact. In the presence of this problem, the Troitsk experiment is correcting for this anomaly by fitting an additional line to the β spectrum run by run. Combining the 2001 results with the previous ones since 1994 gives [53] (35)

m2 (νe ) = (−2.3 ± 2.5 ± 2.0) eV2 /c4 ,

from which the Troitsk group deduces an upper limit of (36)

m(νe ) < 2.05 eV/c2

(95% C.L.)

The values of eqs. (35) and (36) do not include the systematic uncertainty which is needed to be taken into account when the timely varying anomalous excess count rate at Troitsk is described run by run by an additional line. 4. – The Karlsruhe tritium neutrino experiment KATRIN The previous Mainz and Troitsk experiments have reached their sensitivity limit on the neutrino mass with 2 eV/c2 . Concerning a further and significant improvement on neutrino mass sensitivity, the following lessons can be learned from these experiments: – The MAC-E-Filter is a superior instrument to measure the endpoint region of the tritium β spectrum with utmost sensitivity. Special care has to be taken of the background rate originating in the spectrometer. – The quench-condensed tritium source of the Mainz experiment is very well understood with small systematic uncertainties with regard to the Mainz sensitivity. All uncertainties could be improved except the self-charging of the tritium film, which

Direct determination of neutrino mass from 3 H β-spectrum

233

causes an energy spread of 20 meV/monolayer of tritium. If this effect cannot be reduced or completely avoided, a significant further improvement is not possible using such a source. – The windowless gaseous tritium source at Troitsk which is based on the pioneer work at Los Alamos is complicated but served as a rather reliable source for a long time. Special care has to be taken to stabilize the source to allow a longterm running and to avoid particle trapping. On the other hand such a windowless gaseous tritium source exhibits the smallest systematic uncertainties and would allow a significant improvement of the sensitivity on the neutrino mass. To improve the luminosity and stability of such a windowless gaseous tritium source for a nextgeneration of tritium β decay experiment, great effort has to be made. However, this seems to be achievable based on the strong expertise in tritium handling and purification, which is available in fusion technology. Preliminary ideas for next-generation experiments on tritium β decay in search for the absolute neutrino mass were presented by the Troitsk [54] and Mainz [50] groups at a meeting in Erice in 1997. More details on the latter have been published by Bonn et al. [55]. With the discovery of neutrino oscillations in 1998 [56] the discussion gained momentum. Motivated by a long record in neutrino physics through the GALLEX and KARMEN experiments [57, 58] and backed by the presence of a dedicated tritium laboratory on site, the Forschungszentrum Karlsruhe decided to get involved in the plans for a new neutrino mass experiment. It was named KATRIN standing for “KArlsruhe TRItium Neutrino experiment”. From a workshop in Bad Liebenzell in 2001 a letter of intent for the KATRIN experiment [59] emerged from close collaboration of group members from the earlier neutrino mass experiments at Los Alamos (now at University of Washington, Seattle and at University of North Carolina, Chapel Hill), Mainz, and Troitsk with Forschungszentrum Karlsruhe. A design report [60] was approved in 2004. Construction of the experiment is under way and expected to be completed in 2011/12. The experiment aims for an improvement of the sensitivity limit by an order of magnitude down to to check the cosmologically relevant neutrino mass range and to distinguish degenerate neutrino mass scenarios from hierarchical ones. Furthermore, Majorana neutrinos sufficiently massive to cause the neutrinoless double β decay rate of 76 Ge which part of the Heidelberg Moscow collaboration claims to have observed [7] would be observable in the KATRIN experiment in a model-independent way. The true challenge becomes clear by drawing attention to the experimental observable whose uncertainties have then to be lowered by two orders of magnitude. Improving tritium β-spectroscopy by a factor of 100 evidently requires brute force, based on proven experimental concepts. It was decided, therefore, to build a MAC-EFilter with a diameter of 10 m, corresponding to a 100 times larger analyzing plane as compared to the pilot instruments at Mainz and Troitsk. Accordingly one gains a factor of 100 in quality factor which we may define as the product of accepted cross-section of the source (“luminosity”) times the resolving power E/ΔE for the emitted β-particles.

234

C. Weinheimer

Fig. 11. – The KATRIN main spectrometer passes through the village of Leopoldshafen on its way from the river Rhine to the Forschungszentrum Karlsruhe on November 25, 2006 (photo: FZ Karlsruhe).

Figure 11 shows the spectrometer tank of KATRIN on its way to Forschungszentrum Karlsruhe, fig. 12 depicts a schematic plan of the whole 70 m long setup. Meanwhile the spectrometer has been set up and has reached its designed outgassing rate in the range of 10−12 mbar l/(s cm2 ). A decay rate of the order of 1011 Bq is aimed for in a source with a diameter of 9 cm. For the reason given above the KATRIN collaboration decided to build a windowless gaseous tritium source (WGTS) in spite of its extraordinary demands in terms of size and cryo-techniques, which would be required to handle the flux of 1019 T2 molecules/s safely. T2 is injected at the midpoint of a 10 m long source tube kept at a temperature of 27 K by a 2-phase liquid neon bath. The integral column density of the source of 5 · 1017 molecules/cm2 has to be stabilized within 0.1%. Owing to background considerations, the T2 flux entering the spectrometer should not exceed 105 T2 molecules/s. This will be achieved by differential pumping sections (DPS), followed by cryo-pumping sections (CPS) which trap residual T2 on argon frost at 4 K [62]. Each system reduces the throughput by 107 , which has been demonstrated for the cryo-pumping section by a dedicated experiment at Forschungszentrum Karlsruhe. The T2 gas collected by the DPS pumps will be purified and recycled. A pre-spectrometer will transmit only the uppermost part of the β spectrum into the main spectrometer in order to reduce the rate of background-producing ionization events therein. The entire pre- and main spectrometer vessels will each be put on their

Direct determination of neutrino mass from 3 H β-spectrum

235

Fig. 12. – Schematic view of the 70 m long KATRIN experiment consisting of calibration and monitor rear system, windowless gaseous T 2 source, differential pumping and cryo-trapping section, small pre-spectrometer and large main spectrometer, segmented PIN-diode detector and separate monitor spectrometer.

respective analyzing potentials, which are shifted within the vacuum tank by about −200 V, however, due to the installation of a background-reducing inner screen grid system (fig. 13). A ratio of the maximum magnetic field in the pinch magnet over the minimum magnetic field in the central analyzing plane of the main spectrometer of 20000 provides an energy resolution of ΔE = 0.93 eV near the tritium endpoint E0 . The residual inhomogeneities of the electric retarding potential and the magnetic fields in the analyzing plane will be corrected by the spatial information from a 148 pixel PIN diode detector. Active and passive shields will minimize the background rate at the detector. Additional post-acceleration will reduce the background rate within the energy window of interest. Special care has to be taken to stabilize and to measure the retarding voltage. Therefore, the spectrometer of the former Mainz neutrino mass experiment will be operated at KATRIN as a high-voltage monitor spectrometer which continuously measures the position of the 83m Kr-K32 conversion electron line at 17.8 keV, in parallel to the retarding energy of the main spectrometer. To that end its energy resolution has been refined to ΔE = 1 eV. The β electrons will be guided from the source through the spectrometer to the detector within a magnetic flux tube of 191 T cm2 , which is provided by a series of superconducting solenoids. This tight transverse confinement by the Lorentz force applies also to the 1011 daughter ions per second, emerging from β decay in the source tube, as well as to the 1012 electron-ion pairs per second produced therein by the β electron-flux through ionization of T2 molecules. The strong magnetic field of 3.5 T within the source is confining this plasma strictly in the transverse direction such that charged particles cannot diffuse to the conducting wall of the source tube for getting neutralized. The question

236

C. Weinheimer

Fig. 13. – Prototype of one of the 248 modules of the double-layer wire electrode system for the KATRIN main spectrometer. Wires with a diameter of 300 μm (200 μm) are used for the outer (inner) layer. The wires are mounted via precision ceramic holders onto a frame consisting of “combs” and C-profiles and keep their relative distance along their length within a few tenths of a mm. Materials are chosen to be non-magnetic and bakable at 350 ◦ C in order to reach the required low outgassing rate of 10−12 mbar l/(s cm2 ) [69].

how the plasma in the source becomes then neutralized or to which potential it might charge up eventually, has been raised and dealt with only recently [61]. The salient point is, however, that the longitudinal mobility is not influenced by the magnetic field. Hence the resulting high longitudinal conductance of the plasma will stabilize the potential along a magnetic field line to that value which this field line meets at the point where it crosses a rear wall. This provides a lever to control the plasma potential. Meanwhile the Troitsk group has performed a first experiment on the problem [63]. They have mixed 83m Kr into their gaseous T2 and searched for a broadening of the LIII 32-conversion line at 30.47 keV which might be due to an inhomogeneous source potential. Their data fit is compatible with a possible broadening of 0.2 eV, which would not affect their results but suggests further investigation at KATRIN. The sensitivity limit of KATRIN has been simulated (see below) on the basis of a background rate of 10−2 cts/s, observed at Mainz and Troitsk under optimal conditions. Whether this small number can also be reached at the so much larger KATRIN instrument —or even be lowered— has yet to be proven. On the one side, the large dimensions of the main spectrometer are helpful, as they improve straight adiabatic motion due to reduced field gradients. On the other hand, the central flux tube faces a 100 times larger electrode surface at the analyzing potential from which secondary electrons might sneak in. Measurements at Mainz demonstrated that a large number of slow electrons at full potential emerge from the surface of the large central electrodes which are hit by

Direct determination of neutrino mass from 3 H β-spectrum

237

Fig. 14. – One of the final double-layer wire electrode modules on the 3-axis measurement table for quality assurance. The fixing of the wires inside the ceramics holders (see inserted smaller photos on the top right) with the connecting wires is checked with a high-resolution camera, whereas wire position and wire tension are monitored by a specially developed 2-dimensional laser sensor [70].

cosmic muons and local radioactivity. But they are born outside the magnetic flux tube which crosses the detector; hence they are guided adiabatically past the detector. This decisive magnetic shielding effect was investigated at Mainz with an external γ-source, as well as by coincidence with traversing cosmic muons; a magnetic shielding factor of around 105 was measured [64]. Furthermore similar checks at Troitsk pointed to 10 times better shielding [65], which probably results from the better adiabaticity conditions of this larger instrument. In case the axial symmetry of the electromagnetic field configuration is broken (e.g. by stray fields) the drift u (32) develops a radial component, which will be all the faster the weaker the guiding field. This drift can transport slow electrons from the surface into the inner sensitive flux tube within which they are accelerated onto the detector. The effect is probably present at Mainz [66]. After finishing tritium measurements in 2001, electrostatic solutions were developed at Mainz, which strengthened shielding of surface electrons by an additional factor of ≈ 10. This was achieved by covering the electrodes with negatively biased grids built from thin wires [67, 68]. Such grids are now under construction for the KATRIN spectrometer (see figs. 13, 14). This measure (in addition to improved adiabaticity) will contribute decisively to keep-

238

C. Weinheimer

Fig. 15. – View into the KATRIN main spectrometer with scaffold installed. This scaffold was built by FZ Karlsruhe experts completely for the clean-room conditions of the KATRIN main spectrometer (residual gas design pressure after out-baking: 10−11 mbar) [71].

ing the background rate from this much larger instrument down to the design level of 10−2 cts/s [60]. The installation of wire electrode modules inside the KATRIN main spectrometer is a very challenging engineering task (see fig. 15). A simulated spectrum covering 3 years of data taking at KATRIN is shown in fig. 16; a spectrum for the typical measurement conditions at Mainz is added for comparison. Due to the gain in the signal-to-background ratio, the region of optimal mass sensitivity around E0 has moved much closer to the endpoint and one already notices at first glance a marked mass effect for m(νe ) = 0.5 eV. One also notices that the typical third-power rise of the integral spectrum below E0 is delayed. This is mainly due to rotational-vibrational excitations of the daughter molecule which centre at 1.72 eV and stretch up to more than 4 eV with a width of σro-vib = 0.42 eV (see fig. 3). This width diminishes the mass sensitivity as compared to an atomic source with a sharp endpoint. At KATRIN this effect will be felt for the first time, but still amounts to only 5.5% sensitivity loss on m2 (νe ), according to a simulation with standard KATRIN-parameters. Figure 17 shows simulations of the statistical uncertainty of the observable and corresponding upper mass limits (without systematic uncertainties) which are expected from the KATRIN experiment after 3 years of data taking at background rates of 10−2 cts/s and 10−3 cts/s, respectively. They are plotted as a function of the width of the spectral interval, as measured with equidistant or optimized distribution of settings for analyzing potential as well as for measuring time. The dependence on the interval length is rather flat, in particular assuming a lower background. For the reference value one expects to reach a total uncertainty Δm2 (νe )stat somewhat below 0.02 eV2 .

Direct determination of neutrino mass from 3 H β-spectrum

239

Fig. 16. – Top: simulated β-spectra (assuming mν = 0 and E0 = 18.575 keV) resulting from 3 years of KATRIN running under KATRIN standard conditions (filled circles) and from phase 2 of the Mainz experiment for comparison (open squares). Middle: difference of data and fit normalized to the statistical uncertainty for m(νe ) fixed in the fit to 0 eV/c2 (filled circles), 0.35 eV/c2 (open circles) and 0.5 eV/c2 (open squares). Bottom: distribution of measuring points, optimized in position and measuring time.

Fortunately, the improved signal-to-noise ratio is very helpful with regard to the systematic uncertainties, as it allows to shorten the spectral interval under investigation below E0 : Some of the systematic uncertaines decrease, others even vanish completely as soon as the measurement interval drops below energy thresholds of inelastic processes, like the first electronic excitation of the (3 HeT)+ -ion at around 25 eV (see fig. 3) and the minimum energy loss of inelastic scattering on T2 molecules of about 10 eV [49]. From fig. 17 it is clear that KATRIN aims at measuring intervals of about 25 eV below E0 , for which the following systematic uncertainties and the corresponding countermeasures play a role:

240

C. Weinheimer

Fig. 17. – Simulations of statistical neutrino mass-squared uncertainty expected at KATRIN after 3 years of running, calculated in dependence on the fit interval under the following conditions. Spectrometer diameter = 7 m as originally proposed [59]: (a); final 10 m design [60]: (b, c, d); background = 10−2 counts/s: (a, b, c); background = 10−3 counts/s: (d); equidistant measuring point distribution: (a, b); measuring point distribution optimized according to local mass sensitivity: (c, d) (reprinted from ref. [60]).

– Uncertainty of the energy-dependent cross-section of inelastic scattering of β electrons on T2 in the windowless gaseous tritium source. Countermeasures: energy loss measurements with an electron gun as done in Troitsk [49] analyzed by special deconvolution methods [72]. – Fluctuations of the T2 column density in the windowless gaseous tritium source. Countermeasures: temperature and pressure control of the tritium source to the 10−3 level, laser Raman spectroscopy to monitor the T2 concentration compared to HT, DT, H2 , D2 and HD [74]. – Spatial inhomogeneity of the transmission function by inhomogeneities of electric retarding potential and the magnetic field in the analyzing plane of the main spectrometer. Countermeasures: spatially resolved measurements with an electron gun or, alternatively, with an 83m Kr conversion electron source. – Stability of retardation voltage [76]. Countermeasures: a) measurement of HV with ppm precision by a HV-divider [73] and a voltage standard; b) applying the retarding voltage also to the monitor spectrometer, which continuously measures 83m Kr conversion electron lines [76-79]. – Electric potential inhomogeneities in the WGTS due to plasma effects.

Direct determination of neutrino mass from 3 H β-spectrum

241

Countermeasures: potential-defining plate at the rear exit of the WGTS; monitoring of the potential within WGTS possible by special runs with 83m Kr/T2 mixtures. Each systematic uncertainty contributes to the uncertainty of m2 (νe ) with less than 0.0075 eV2 /c4 , resulting in a total systematic uncertainty of Δm2 (νe )sys = 0.017 eV2 /c4 . The improvement on the observable m2 (νe ) will be two orders of magnitude compared to previous experiments at Mainz and Troitsk. The total uncertainty will allow a sensitivity on m(νe ) of 0.2 eV/c2 to be reached. If no neutrino mass is observed, this sensitivity corresponds to an upper limit on m(νe ) of 0.2 eV/c2 at 90% C.L, or, otherwise, to evidence for (discovery of) a non-zero neutrino mass value at m(νe ) = 0.3 eV/c2 (0.35 eV/c2 ) with 3σ (5σ) significance. For more details, we refer to the KATRIN Design Report [60]. 5. – Conclusion Among various ways to address the absolute neutrino mass scale, the investigation of the shape of β decay spectra around the endpoint is the only model-independent method. This direct method is complementary to the search for the neutrinoless double β decay and to the information from astrophysics and cosmology. The investigation of the endpoint spectrum of the tritium β decay is still the most sensitive direct method. The tritium β decay experiments at Mainz and Troitsk have ended yielding upper limits of about 2 eV/c2 . The new KATRIN experiment is being set up at the Forschungszentrum Karlsruhe by an international collaboration. To measure the tritium β spectrum near the endpoint with lowest systematic uncertainties and highest count rate, the KATRIN collaboration is setting up a) a windowless gaseous tritium source with a factor 100 more count rate than previous experiments and b) a doublet of two spectrometers of MAC-E-Filter type, which is connected to the windowless gaseous tritium source via a complex tritium elimination and electron transport chain. KATRIN’s large main spectrometer has a 100 times larger cross-section and a 5 times higher energy resolution compared to the previous tritium β spectrometers. The background design value is based on active background reduction methods at the spectrometer (double layer screening wire electrode system) and at the electron detector (active and passive shielding, low activity materials). The systematic uncertainties of KATRIN will be well under control by many calibration and monitoring activities, as well as by virtue of the small energy interval of interest below the endpoint reducing the influence of inelastic processes. KATRIN will enhance the model-independent sensitivity on the neutrino mass further by one order of magnitude down to 0.2 eV. ∗ ∗ ∗ The author would like to thank all colleagues and friends from the KATRIN, Mainz and Troitsk collaborations for fruitful discussions. Among them he would like especially ¨ck and E. Otten; as well as K. Valerius to name J. Bonn, G. Drexlin, F. Gl u for carefully reading and correcting these lecture notes. The work by the author for the KATRIN experiment is supported by the German Bundesministerium f¨ ur Bildung und Forschung, the Deutsche Forschungsgemeinschaft and the University of M¨ unster.

242

C. Weinheimer

REFERENCES [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40] [41] [42] [43]

Fogli G. L. et al., Prog. Part. Nucl. Phys., 57 (2006) 742. Pastor S., this volume, p. 187. ´ G., this volume, p. 269. Senjanovic Strumia A., this volume, p. 21. Komatsu E. et al. (WMAP Collaboration), arXiv:0803.0547 (2008). Hannestad S. et al., J. Cosmol. Astroparticle Phys., 08 (2007) 015. Klapdor-Kleingrothaus H. V., Krivosheina I. V., Dietz A. and Chkvorets O., Phys. Lett. B, 586 (2004) 198. Giuliani A., this volume, p. 141. Amsler C. et al. (Particle Data Group), Phys. Lett. B, 667 (2008) 1 http:// pdg.lbl.gov. Robertson R. G. H. and Knapp D. A., Annu. Rev. Nucl. Sci., 38 (1988) 185. Holzschuh E., Rep. Prog. Phys., 55 (1992) 1035. Wilkerson J. F. and Robertson R. G. H., in Current Aspects Of Neutrino Physics, edited by Caldwell D. O. (Springer, Berlin, Heidelberg) 2001, p. 39. Weinheimer Ch., in Massive Neutrinos, edited by Altarelli G. and Winter K., Springer Tracts in Modern Physics (Springer) 2003, pp. 25-52. Otten E. W. and Weinheimer C., Rep. Prog. Phys., 71 (2008) 086201. Weinheimer C. et al., Phys. Lett. B, 300 (1993) 210. Masood S. S. et al., Phys. Rev. C, 76 (2007) 045501. Ciborowski J. and Rembielinski J., Eur. Phys. J. C, 8 (1999) 157. Repco W. W. and Wu C. E., Phys. Rev. C, 28 (1983) 2433. Gardner S., Bernard V. and Meissner U. G., Phys. Lett. B, 598 (2004) 188. Stephenson G. J. and Goldman T., Phys. Lett. B, 440 (1998) 89. Ignatiev A. Yu. and McKellar B. H. J., Phys. Lett. B, 633 (2006) 89. Severijns N. et al., Rev. Mod. Phys., 78 (2006) 991. Bonn J. et al., arXiv:0704.3039v1 [hep-ph] (2006). Saenz A., Jonsell S. and Froehlich P., Phys. Rev. Lett., 84 (2000) 242. Doss N. and Tennyson J., J. Phys. B, 41 (2008) 125701. Gatti F., this volume, p. 323. Yasumi S. et al., Phys. Lett. B, 334 (1994) 229. Jung M. et al., Phys. Rev. Lett., 69 (1992) 2164. Curran S. C. et al., Philos. Mag., 40 (1949) 53. Lubimov V. A. et al., Phys. Lett. B, 94 (1980) 66; Boris S. et al., Phys. Rev. Lett., 58 (1987) 2019. Fritschi M. et al., Phys. Lett. B, 173 (1986) 485. Wilkerson J. F. et al., Phys. Rev. Lett., 58 (1987) 2023. Lippmaa E. T. et al., Sov. Phys. Dokl., 30 (1985) 393. Van Dyck R. S. et al., Phys. Rev. Lett., 70 (1993) 2888. Nagy Sz. et al., Europhys. Lett., 74 (2006) 404. Robertson R. G. H. et al., Phys. Rev. Lett., 67 (1991) 957. Holzschuh E. et al., Phys. Lett. B, 287 (1992) 381. Kawakami H. et al., Phys. Lett. B, 256 (1991) 105. Ching C. R. et al., Int. J. Mod. Phys. A, 10 (1995) 2841. Stoeffl W. and Decman D. J., Phys. Rev. Lett., 75 (1995) 3237. Weinheimer C. et al., Phys. Lett. B, 460 (1999) 219. Kraus C. et al., hep-ex/0412056, Eur. Phys. J. C, 40 (2005) 447. Belesev A. I. et al., Phys. Lett. B, 350 (1995) 263.

Direct determination of neutrino mass from 3 H β-spectrum

[44] [45] [46] [47] [48] [49] [50] [51] [52] [53] [54] [55] [56] [57] [58] [59] [60]

[61] [62] [63] [64] [65] [66] [67] [68] [69] [70] [71] [72] [73] [74] [75] [76] [77] [78] [79]

243

Lobashev V. M. et al., Phys. Lett. B, 460 (1999) 227. Fleischmann L. et al., Eur. Phys. J. B, 16 (2000) 521. Kruit P. and Read F. H., J. Phys. E, 16 (1983) 313. Picard A. et al., Nucl. Instrum. Methods, Phys. Res. B, 63 (1992) 345. Lobashev V. M., Nucl. Instrum. Methods, Phys. Res. A, 240 (1985) 305. Aseev V. N. et al., Eur. Phys. J. D, 10 (2000) 39. Barth H. et al., Prog. Part. Nucl. Phys., 40 (1998) 353. Bornschein B. et al., J. Low Temp. Phys., 131 (2003) 69. Kolos W. et al., Phys. Rev. A, 37 (1988) 2297. Lobashev V. M., Nucl. Phys. A, 719 (2003) 153c. Lobashev V. M., Prog. Part. Nucl. Phys., 40 (1998) 337. Bonn J. et al., Nucl. Instrum. Methods Phys. Res. A, 421 (1999) 256. Fukuda Y. et al. (Super-Kamiokande Collaboration), Phys. Rev. Lett., 81 (1998) 1562. Anselmann P. et al. (GALLEX Collaboration), Phys. Lett. B, 285 (1992) 386. Armbruster B. et al. (KARMEN Collaboration), Phys. Rev. D, 65 (2002) 112001. Osipowicz A. et al. (KATRIN Collaboration), arXiv:hep-ex/0109033. Angrik J. et al. (KATRIN Collaboration), KATRIN Design Report 2004, Wissenschaftliche Berichte FZ Karlsruhe 7090 http://bibliothek.fzk.de/zb/berichte/FZKA7090.pdf. Nastoyashchii A. F. et al., Fusion Sci. Technol., 48 (2005) 743. Kazachenko O. et al., Nucl. Instrum. Methods Phys. Res. A, 587 (2008) 136. Lobashev V. M., Proceedings of the 11th International Workshop on Neutrino Telescopes, Venice, Italy, edited by Baldo Ceolin M. (Edizioni Papergraf) 2005, pp. 507-517. Schall J. P. et al., to be published. Lobashev V. M., Troitsk, private communication. ¨ck F., to be published. Glu Ostrick B., diploma thesis, University of Mainz, 2002. Flatt B. et al., doctoral thesis, University of Mainz, 2004 and to be published. Weinheimer C., Prog. Part. Nucl. Phys., 57 (2006) 22. Prall M. et al., to be published in IEEE Conference Series. Luo X. et al., Vacuum, 81 (2007) 777. unster, 2008. Wolff I., diploma thesis, University of M¨ ¨ mmler Th., doctoral thesis, University of M¨ Thu unster, 2007. Lewis R. J. et al., Laser Phys. Lett., 1 (2008) 10. Kaspar J. et al., Nucl. Instrum. Methods Phys. Res. A, 527 (2004) 423. Kaspar J., doctoral thesis, Charles University of Prague, 2008. Ostrick B., doctoral thesis, University of M¨ unster, 2008. Venos D. et al., Appl. Radiat. Isot., 63 (2005) 323. Rasulbaev M. et al., Appl. Radiat. Isot., 66 (2008) 1838.

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-245

Precision measurements of the Cosmic Microwave Background P. de Bernardis and S. Masi Dipartimento di Fisica, Sapienza Universit` a di Roma and INFN Sezione di Roma 1 P.le A. Moro 2, 00185 Roma, Italy

Summary. — In this paper we give a tutorial introduction to the Cosmic Microwave Background and its measurements, focusing on the current efforts to obtain the full detailed picture of all its observables: the spectrum, the anisotropy, the polarization.

1. – Introduction We live in an expanding evolving universe, coming from an initial hot and dense phase. Neutrinos played a key role in the early evolution of the universe. Neutrino masses can be efficiently constrained from cosmology, and in particular from precise observations of the Cosmic Microwave Background (CMB) and of other cosmological observables. Moreover, some of the methods developed to measure CMB photons can be modified and used to measure neutrino masses (bolometers/micro-calorimeters). For these reasons we believe that precision measurements of the CMB are of interest in a school devoted to neutrinos. 2. – Modern cosmology and the CMB Cosmology is the description of the Universe at large scales, and of its evolution. The current Cosmological Model is the Hot Big Bang model, based on the Cosmological c Societ`  a Italiana di Fisica

245

246

P. de Bernardis and S. Masi

Principle, on general relativity, on particle, nuclear, atomic physics. The observational evidences are: 1) The expansion of the Universe, 2) The measured abundance of light elements, 3) The Cosmic Microwave Background. If we believe that we do not occupy a special position in the Universe, i.e. that the Universe at large scales is the same everywhere, and that the correct description of gravity is general relativity, then we get the Friedmann equation, describing the evolution of the Friedmann-Robertson-Walker metric (see Pastor’s paper in these proceedings) ⎡ ⎤ 2 dχ (1) ds2 = c2 dt2 + a(t)2 ⎣  + (χdθ)2 + (χ sin θdφ)2 ⎦ , 1 − χ2 where a(t) is the scale factor, describing the common variation with time of the physical lengths in the Universe, and normalized to be unity today (a(t0 ) = 1). Under this metric, the Friedmann equation can be derived from Einstein’s equations (2)

   2 ΩM 0 (1 − Ω0 ) a˙ 2 ΩR0 = H0 + 3 + + ΩΛ . a a4 a a2

˙ 0 )/a(t0 ); Ωi0 are the density parameters for the H0 is the Hubble constant, H0 = a(t different energy-density components of the universe today (3)

Ωi0 =

ρi0 8πGρi0 = . ρc0 3H02

Here i = R, M, Λ for radiation, matter and cosmological constant respectively, and Ω0 = ΩM 0 + ΩR0 + ΩΛ . The solution for the scale factor a(t) depends on the different kinds of energy density relevant at the considered epoch. The first fundamental result of this equation is that the universe is not static: a = a(t). From observations, we know that the Universe expands isotropically today: a(t ˙ 0 ) > 0. In an expanding Universe the wavelengths of photons expand in the same way as all other lengths: this is the cosmological redshift, a direct consequence of general relativity. Consider a source at distance R(t) = a(t)χ1 (comoving coordinate χ1 ). Photons emitted from the source propagate radially towards us along the coordinate χ, occupying sequentially all coordinates between χ1 and 0. From the FRW metric, since ds = 0 for photons and the propagation is radial, we get cdt dχ = . a(t) 1 − χ2

(4)

Consider a first crest of the EM wave emitted at time t1 and received at time t0 ; next crest is emitted at t1 + λ1 /c and received at t0 + λ0 /c. Since χ1 is constant, we have that  (5)

t0

c t1

dt = a(t)



0

χ1





dχ 1−

χ2

t0 +λ0 /c

=c t1 +λ1 /c

dt . a(t)

Precision measurements of the Cosmic Microwave Background

247

The equality between the two integrals over time can be rewritten as  (6)

t0 +λ0 /c

c t0

dt =c a(t)



t1 +λ1 /c t1

dt . a(t)

The times λ0 /c and λ1 /c are both H0−1 , the typical variation time of a(t). So we can consider a(t) as constant in the integrals, and we get λ1 λ0 = . a(t0 ) a(t1 )

(7)

The wavelengths of photons elongate in the same way as all other cosmological distances, following the same scale factor a(t). This phenomenon is called cosmological redshift, in our expanding universe. Light coming from distant galaxies is shifted towards longer wavelengths, in a way approximately proportional to distance: the farther the source, the longer is the travel time of photons, the larger is the growth of the scale factor between emission “em” and detection “det”, the larger the elongation of the wavelength. This is the Hubble law, measured since ∼ 1930 for distant galaxies, and valid for Δλ/λ = (λdet − λem )/λem 1: (8)

c

Δλ = H0 D, λ

where D is the distance of the galaxy. We define the redshift z from the relationship (9)

z=

Δλ λdet − λem , = λem λ

or (10)

1+z =

λdet adet = . λem aem

The Hubble law, valid for z 1 is rewritten as (11)

cz = H0 D.

As evident from the previous equations, the cosmological redshift has nothing to do with the Doppler effect, and has enormous observational consequences. Measurements using standard candles (Cepheids, SN1a, . . . ) to estimate the distance of galaxies, have now established that H0 = (75 ± 8) km/s/Mpc and that the expansion of the universe is indeed approximately isotropic. If the Universe is expanding, it was denser and hotter in the past. In the Early Universe, the temperature was high enough that nuclear reactions produced light elements starting from a plasma of particles (the primeval fireball). The observed primordial abundance of light elements can be produced only if an abundant background of photons

248

P. de Bernardis and S. Masi

is present (∼ 109 γ/b). This background is observed today as the Cosmic Microwave Background. According to modern cosmology the CMB was generated in the very early universe, less than 4 μs after the Big Bang, from a small matter-antimatter asymmetry. The CMB was then thermalized in the primeval fireball (in the first 380000 years after the big bang) by repeated scattering against free electrons. When the temperature dropped below 3000 K, electrons and protons combined into neutral hydrogen atoms (recombination), radiation decoupled from matter, and the universe became transparent. The CMB was then diluted and redshifted to microwave frequencies (zCMB = 1100) in the subsequent 14 Gy of expansion of the Universe. The result is a very isotropic blackbody with T = 2.725 K, as observed with extreme accuracy by the COBE-FIRAS experiment [1]. A long-standing need of observational cosmology is Dark Matter, i.e. a form of mass which interacts gravitationally but does not interact electromagnetically. The presence of dark matter is required at different scales in the Universe, from the rotation curves of galaxies to the dispersion of galaxy velocities in clusters, to the formation of structures in the Universe, to the details of the anisotropy of the Cosmic Microwave Background. It is widely believed that the large-scale structure of the Universe observed today (see, e.g., [4]) derives from the growth of initial density seeds, already visible as small anisotropies in the maps of the Cosmic Microwave Background. This scenario works only if dark matter is already clumped at the epoch of CMB decoupling, gravitationally inducing anisotropy in the Cosmic Microwave Background. There are three physical processes converting the density perturbations present at recombination into observable CMB temperature fluctuations ΔT /T . They are: photon density fluctuations δγ , which can be related to the matter density fluctuations Δρ once a specific class of perturbations is specified; the gravitational redshift of photons scattered in an over-density or an under-density with gravitational potential difference φr ; the Doppler effect produced by the proper motion with velocity v of the electrons scattering the CMB photons. In formulas (12)

ΔT 1 1 φr vr (n ) ≈ δγr + − n , T 4 3 c2 c

where n is the line of sight vector and the subscript r labels quantities at recombination. Our description of fluctuations with respect to the FRW isotropic and homogeneous metric is totally statistical. So we are not able to forecast the map ΔT /T (θ, φ), but we are able to predict its statistical properties. If the fluctuations are random and Gaussian, all the information encoded in the image is contained in the angular power spectrum of the map, detailing the contributions of the different angular scales to the fluctuations in the map. In other words, the power spectrum of the image of the CMB details the relative abundance of the spots with different angular scales. If we expand the temperature of the CMB in spherical harmonics (13)

 ΔT = a,m Ym (θ, φ), T

Precision measurements of the Cosmic Microwave Background

249

the power spectrum of the CMB is defined as (14)

c = a2,m ,

with no dependence on m since there are not preferred directions in the image. Since we have only a statistical description of the observable, the precision with which the theory can be compared to measurement is limited both by experimental errors and by the statistical uncertainty in the theory itself. Each observable has an associated cosmic and sampling variance, which depends on how many independent samples can be observed in the sky. In the case of the c ’s, their distribution is a χ2 with 2 + 1 degrees of freedom, which means that low multipoles have a larger intrinsic variance than high multipoles (see, e.g., [7]). Detailed models and codes are available to compute the angular power spectrum of the CMB image given a cosmological model for the generation of density fluctuations in the Universe, and a set of parameters describing the background cosmology (see, e.g., [8, 9]). The power spectrum of CMB anisotropy is now measured quite well (see, e.g., [10-19]); an adiabatic inflationary model with cold dark matter and a cosmological constant fits extremely well the measured data (see, e.g., [20-31, 14, 32-36]). Due to the phenomenon of free streaming, neutrinos cannot be responsible for the spectrum of perturbations implied by CMB anisotropy measurements: cold dark matter is much more consistent. However, massive neutrinos can be a minor component of the dark matter in the universe, and detailed observations of the c can constrain their properties (see, e.g., [37-39]). 3. – CMB observables How can we measure the CMB anisotropy with the needed detail? The spectrum of the CMB was measured with high accuracy by COBE-FIRAS: a Martin-Puplett FourierTransform Spectrometer with bolometric detectors, placed in a 400 km orbit. This nullinstrument compared the specific sky brightness to the brightness of an internal cryogenic blackbody reference. The output was precisely nulled (within detector noise) for Tref = 2.725 K. This implies that the brightness of the empty sky is a blackbody at the same temperature, and that the early Universe was in thermal equilibrium at high temperature. The brightness of a 2.725 K blackbody is relatively large (compared to the typical noise of mm-wave detectors). However, it should be stressed that everything at room temperature emits microwaves in the same frequency range: the instrument itself, the surrounding environment, the Earth atmosphere. A room temperature blackbody produces orders of magnitude more power than the CMB. The main difficulty in the measurement of the brightness of the CMB is thus the extremely efficient rejection of local radiation required. Low emissivity, reflective surfaces must be used to shield the instrument, which needs to be cooled to cryogenic temperatures. Also, to avoid a very wide dynamic range, a cryogenic reference should be used in the comparison. All this justifies the design of the COBE-FIRAS instrument [1]. The FIRAS one can be considered a definitive

250

P. de Bernardis and S. Masi

measurement of the spectrum of the CMB in the mm range: the deviations from a pure blackbody are less than 0.01% in the peak region, low enough to be fully convincing about the thermal nature of the CMB. However, there are regions of the spectrum where small deviations from a pure blackbody could be expected. The ARCADE experiment [2], for example, focused on the low-frequency end of the spectrum, looking for cm-wave deviations. Processes like reionization due to the first stars, and particle decays in the early Universe, would heat the diffuse matter, which in turn would cool, injecting the excess heat in the CMB (see, e.g., [3]). Sub-percent deviations of the CMB spectrum in the cm range could still be undetected. At a much lower level we expect the CMB to be anisotropic and weakly polarized. The wavelength spectrum of the anisotropy and of the polarization is a modified blackbody (15)

ΔB = B(ν, TCMB )

xex ΔT , −1 T

ex

peaking at 220 GHz. However, since ΔT /T 1 (eq. (12)), the amplitude of the anisotropy signal is very small, and differential instruments have been developed to measure it. Also, a real-world instrument will be sensitive to a limited range of angular scales, depending on its angular resolution (FWHM), on the size of the observed region θ, and on the beam-switch amplitude α if it is a differential instrument. This translates into a range of multipoles in eq. (13) contributing to√the measured signal. For example an instrument with a Gaussian beam (FWHM = 2σ 2 ln 2) and covering the whole sky will respond to multipole  through the beam function B = exp[−( + 1/2)σ 2 ] as plotted in fig. 1, where we compare it to the “standard” power spectrum of CMB anisotropy and EE polarization. This means that to see the “acoustic peaks” due to oscillations of the photon-baryon fluid before recombination, an angular resolution of the instrument better than 1◦ is needed. The other problem evident from fig. 2 is that CMB anisotropy is extremely weak; as a rule of thumb the r.m.s. anisotropy is in the order of 30–100 μK. The polarization signal generated by scalar (density) perturbations at recombination is of the order of a few μK. The polarization signal generated by tensor perturbations during the inflation phase (if inflation really happened) depends on the energy scale of inflation, but is even weaker, in the range of 100 nK or lower (see, e.g., [5, 6]). Measuring the weak anisotropy of the CMB at the 1% level seemed science fiction 20 years ago. Now it is reality, and even the scalar polarization signal is currently being measured. This gives us confidence that the weaker B-mode polarization measurements can be measured in the future. To do this, however, observation methods need to be significantly improved. 4. – CMB observation techniques Observing the CMB is not an easy task. The spectrum of the CMB, a 2.725 K blackbody, is very weak with respect to the emission of the local environment. For this reason, only a space mission like COBE-FIRAS has been able to measure it precisely. The anisotropy and polarization of the CMB offer a more difficult challenge. Their level

Precision measurements of the Cosmic Microwave Background

251

Fig. 1. – Top: angular power spectrum for CMB anisotropy (T T ) and for EE polarization. The latter has been amplified 20 times to make it visible in the same plot of T T . The angular scale γ corresponding to multipole  is approximately γ(◦ ) = 180/. Bottom: filter functions of absolute instruments with different angular resolutions. A FWHM smaller than 1◦ is needed to be sensitive to the “acoustic peaks” due to photon-baryon oscillations in the early universe. The curves are labeled with the beam FWHM. Differential instruments will not be sensitive to multipoles  < 180/α(◦ ), where α is the angular separation of the beam switch; experiments scanning a limited sky region with angular size θ cannot be sensitive to multipoles with  < 180/θ(◦ ).

is  10−5 of the absolute intensity: extremely sensitive detectors, excellent sites, and differential methods are needed to measure it. In the following we give some insight on each of these issues. . 4 1. CMB observation sites. – The Earth atmosphere represents a formidable microwave absorber and emitter in the mm range, due to the presence of water vapor, oxygen and ozone molecules and their rotational transitions. It is also a turbulent medium, featuring time-varying anisotropy in its parameters. A few “windows” feature lower opacity and emission in the mm range. These are located at ν  50 GHz; 70 GHz  ν  110 GHz; 125 GHz  ν  175 GHz; 190 GHz  ν  300 GHz; 320 GHz  ν  360 GHz and 390 GHz  ν  420 GHz. The atmospheric emissivity in the windows can be as low as 0.01, improving in high mountain cold and dry locations. The problem of extracting

252

P. de Bernardis and S. Masi

Fig. 2. – Specific brightness of the CMB and of its anisotropy, compared to the brightness of the atmosphere at a mountain site and on a stratospheric balloon.

CMB signals from ground-based observations is illustrated in fig. 2, where we compare the brightness of a 250 K greybody (with emissivities of 1, 0.1, 0.01), the brightness of a good mountain site (0.5 mm precipitable water vapor, 4000 m o.s.l.), the atmospheric brightness at 41 km of altitude (stratospheric balloon) to the spectrum of the CMB and of its anisotropy. It is evident that CMB anisotropy measurements can be carried out only if atmospheric emission is very isotropic and stable: stability is even more important than the absolute value of the emission. The advantage of a balloon platform is also evident: balloon-borne missions can access a much wider frequency range, and have a better chance to observe spectral features in the CMB, if present. All this explains the huge effort by CMB experimentalists, mounting their instrument in high, cold and dry mountain sites (like White Mountain in California, Testa Grigia in the Alps, Tenerife, Chajnantor in Chile (5100 m), Dome C and South Pole in Antarctica, to quote some of the best locations). Even more challenging is the use of stratospheric balloons, which balances the huge advantage of a lower atmospheric background with a shorter duration of the mission and a more complex pointing of the telescope. Historically, coherent detectors operating at low frequencies have been used mostly from ground-based locations, while broad-band sensitive bolometers have been used on stratospheric balloon platforms.

Precision measurements of the Cosmic Microwave Background

253

Of course the best way to avoid atmospheric emission is to carry the instrument above the atmosphere. The extremely successful WMAP mission of NASA has been operated at 1.5 million km of altitude, in the Lagrangian point L2 of the Earth-Sun system. The forthcoming Planck mission of ESA will also operate from the same advantage point. . 4 2. Detectors. – The peak brightness of the CMB is at a wavelength of 2 mm. This wavelength range has been for a long time shorter than the shortest wavelength efficiently measurable with coherent radiometers, and longer than the longest wavelength accessible with far IR photoconductors. Only the development of sensitive microwave amplifiers based on high electron mobility transistors, on one side, and of cryogenic spider-web bolometers, on the other side, has recently allowed experimentalists to perform detailed measurements of the CMB. Today we have three kinds of mm-wave detectors for CMB studies: – Coherent detectors, where the incoming radiation field is converted into current by an antenna, and the current is amplified by suitable ultra-fast amplifiers, or downconverted beating with a local oscillator, and then amplified in a radio-frequency system (see, e.g., [40]). – Thermal bolometric detectors (see, e.g., [41]), where the integrated effect of many CMB photons heats a radiation absorber, and the resulting temperature increase is measured by an ultra-sensitive thermistor, either a current-biased semiconductor (see, e.g., [42, 43]) or a voltage-biased superconductor (see, e.g., [44, 45]). – Direct detectors, where CMB photons break Cooper pairs in a superconducting film (KIDs, see, e.g., [46]) and the resulting change in the kinetic impedance of the film is detected. Noise in bolometers has Johnson, phonon and photon origin (see, e.g., [47]). Bolometric detectors used in space conditions are already limited by the quantum noise of the CMB itself (like in the HFI instrument of the Planck mission [48]). For this reason, it would be useless for CMB measurements to reduce the noise equivalent power of the detectors. Progress in the field can be obtained only by increasing the mapping speed of the instruments, by means of large arrays of detectors, to be accommodated in telescopes with large corrected focal planes. In CMB photon-noise–limited conditions, the CMB anisotropy signal is given by (16)

ΔB =

ΔT AΩ T



x2

(x)B(ν, TCMB ) x1

xex dx, ex − 1

where AΩ is the throughput of the instrument, x is the adimensional frequency x = hν/kT , (x) is the spectral response of the instrument, including the effects of the detectors, of the filters, of the atmosphere. In the same conditions the variance of the

254

P. de Bernardis and S. Masi

Fig. 3. – Signal-to-noise ratio for CMB anisotropy measurements limited by CMB photon noise. A case with ΔT /T ∼ 10−5 is considered. Center frequency, bandwidth and throughput are specified in the labels of the lines.

measured brightness after an integration time T is given by  (17)

σ 2 (ΔB) =

4k 5 T 5 AΩ c2 h3



x2

(x) x1

 x4 (ex − 1 + (x)) 1 . dx (ex − 1)2 T

From these two equations it is possible to compute the signal-to-noise ratio ΔB/σ(ΔB) for CMB anisotropy measurements, as a function of integration time. This is shown in fig. 3. It is evident that, in order to reach the few μK level necessary for precise anisotropy measurements, long integration times are needed for each observed pixel. The situation is even worse for CMB polarization measurements, where the expected signal is much lower. Since a large number of pixels must be observed to fight cosmic variance, the only solution is the use of large format arrays, so that the mapping speed of the measurement is boosted. In this respect, coherent detectors have progressed with the introduction of MMIC radiometers (see, e.g., [49]), while fully litographed TES bolometers have been replicated in large arrays (see, e.g., [50, 51]) and are already working in the focal plane of large telescopes (see, e.g., [52-54]). Both these techniques involve massive electronics for the amplifiers themselves in the first case, and for the multiplexing readout in the second

Precision measurements of the Cosmic Microwave Background

255

case. In this respect, although less developed, KIDs promise a large simplification in the readout system. Moreover, lumped-elements KIDs are being developed, which will further simplify the absorption of microwaves in the array [55]. . 4 3. Optics. – CMB anisotropy measurements require large microwave telescopes to achieve sufficient angular resolution. In the case of an off-axis telescope, the angular response is approximated by the Airy function (18)

2  dI 2J1 (akθ) (θ) = I0 , dΩ akθ

where a is the radius of the input aperture (normally the primary mirror of the telescope), k = 1/λ, θ is the off-axis angle of the incoming radiation whose amplitude is I0 , and J1 is the Bessel function of order 1. From the equation above we see that at 2 mm of wavelength (150 GHz), the diameter of the aperture of the telescope required to obtain a 10 FWHM beam (needed to study the features in the power spectrum, see fig. 1) is of the order of D  1.22λ/θ ∼ 0.8 m. Moreover, the equation above shows that there are important sidelobes in the angular response of the telescope. This means that the rejection of ground spillover is an important issue. In addition to what comes from the main beam, pointed to the sky to measure the CMB, the detector will receive power from all the surrounding sources, weighted by the angular response of eq. (18), as follows:  (19)

W =A

B(θ, φ) 4π

dI (θ, φ)dΩ, dΩ

where B(θ, φ) is the brightness from direction θ, φ. Beyond the main beam (θ  λ/D) the envelope of the angular response in eq. (18) scales as θ−3 . For a ground-based experiment, where the ground emission fills about 2π srad of the environment surrounding the instrument, the “nuisance” signal of ground emission can be comparable to or even larger than the CMB signal from the main beam. This can be estimated as follows:    dI dI (20) W =A (θ, φ)dΩ + (θ, φ)dΩ , B(θ, φ) B(θ, φ) dΩ dΩ M S where M stands for main lobe and S stands for side lobes. Equation (20) can be approximated as       dI dI (21) W A Bsky (θ, φ) ΩM + Bground (θ, φ) ΩS = A[IM + IS ], dΩ M dΩ S where M,S represent the averages of the angular response over the main lobe ( 1) and over the sidelobes ( 1). The ratio IM /IS depends on the main lobe FWHM and on the dI average response in the sidelobes  dΩ S . In the case of a 2.725 K sky emission and of a dI 250 K ground emission, for example, in order to have IS  IM we need  dΩ S 4×10−5

256

P. de Bernardis and S. Masi

Fig. 4. – Picture of the BOOMERanG telescope, where the Sun shield and the ground shield surrounding the off-axis telescope are evident. The primary mirror is shown in the top left inset, while in the bottom left inset we plot a schematics of the off-axis optical scheme.

dI for a 10◦ FWHM experiment, and  dΩ S 1×10−8 for a 10 FWHM experiment. Hence the necessity of additional shields surrounding the telescope, to increase the number of diffractions that radiation from the ground must undergo before reaching the detectors. As an example we show in fig. 4 a picture of the BOOMERanG balloon-borne experiment, where the ground and Sun shields are evident. The situation is even worse in the case of anisotropy measurements, where the interesting signal is of a few μK. Here a differential instrument is needed, which helps in reducing the sidelobes. The last resource is to send the instrument far from the Earth, so that the solid angle occupied by the ground emission is 2π. This is the case for the WMAP and Planck space missions devoted to CMB anisotropy measurements. They both operate from the Lagrange point L2 of the Sun-Earth system, where the solid angle occupied by the Earth is only 2 × 10−4 srad, with an improvement of a factor ∼ 30000 with respect to ground-based or balloon-borne experiments. The telescope and shields configuration is optimized using numerical methods (see, e.g., [56]), normally based on the geometrical theory of diffraction [57] to speed up the computations.

Precision measurements of the Cosmic Microwave Background

257

The measurement of small signals embedded in a large common mode signal requires efficient modulation techniques. This is the case of anisotropy and polarization measurements. CMB anisotropy has been measured in the past using beam switching techniques, introducing a movable element in the optical system to alternate on the detectors the target and a neighbor reference region (see, e.g., [58]). To first order, the CMB emission, the instrument and telescope emission and the atmospheric emission are the same in the target and in the reference regions. Using a synchronous demodulator (a lock-in amplifier) the small anisotropy signal is efficiently extracted from an overwhelming common mode. This technique, however, has a very slow mapping speed. With the availability of lower noise detectors, the beam-switch technique has been gradually replaced with the fast scan technique, where the entire telescope scans the sky, and only the AC component of the signal is sampled and measured. In this way each pixel of the sky is referenced to the average surrounding emission, so that the common mode signal is rejected. Scanning telescopes have been BOOMERanG [59, 60], Archeops [61], WMAP [62, 63], and will be ˙ so that each Planck [64]. In these instruments the telescope scans the sky at a speed φ, multipole is modulated by the sky scan at a different frequency. Assuming a scan at constant zenith angle Θ, the temperature fluctuations of the CMB along the scan can be  expressed as a Fourier series T (Θ, φ) = m αm eimφ . The m-th component of the CMB ∗ signal (which has a mean square amplitude Γm = αm αm ) will produce in the detector a ˙ signal at the electrical frequency f = φm/2π. So a frequency analysis of the detector signal can be performed to get m-space spectroscopy of the CMB anisotropy. Moreover, the 1-D m-space spectrum Γm is related in a simple way [65] to the 2-D -space power spec∞ 2 trum c of the CMB: Γm = =|m| c B2 Pm (Θ). This relationship is valid for scans along full circles; shorter scans on circle sections have a lower -space resolution. All the spherical harmonics components of the CMB with  > m contribute to the detector signal at ˙ frequency mφ/2π. If min is the lowest spherical harmonic of interest, the experimentalist will set up the scan in such a way that noise in the system is confined at frequencies lower ˙ than fmin = min φ/2π. This condition is stricter for the HEMT-based receivers, which feature higher 1/f noise knee. On the other hand, if the highest spherical harmonics of interest is max (which depends on the beam size of the experiment), the scan speed should ˙ be adjusted so that the frequency fmax = max φ/2π is lower than the high-frequency cutoff of the experiment. This condition is quite strict for bolometric receivers, which feature  10 ms thermal time constants. In practice, with a scanning speed of ∼ 1 rpm = 6◦ /s, even with a 50 ms time constant the maximum multipole accessible is max ∼ 2400: this figure is appropriate for the slowest bolometers in the forthcoming Planck HFI. In the case of polarization measurements, the small linear polarization degree must be extracted from the larger temperature anisotropy by means of a polarization modulator. Most of the detections of CMB polarization to date have been made using coherent detectors at frequencies  100 GHz [66-72]. In these instruments the detector is intrinsically sensitive to one polarization of the incoming signal, and two orthogonal polarizations can be switched on the detector by means of a ferrite modulator in a circular waveguide, either in a direct or in a correlation receiver. Other instruments, instead, have used thermal detectors [73-78], using either polarization sensitive bolometers [79] or a rotating

258

P. de Bernardis and S. Masi

waveplate modulator [80]. In the first case, the signal from two different bolometers, each sensitive to one of the two orthogonal polarizations, is compared, while the telescope scans the sky. This approach requires a good matching of the characteristics of the two detectors. In fact, selected thermistors are mounted on two independent orthogonal wire grids, which are placed inside the same groove of a corrugated waveguide. This approach offers the same mapping speed of anisotropy measurements, but is prone to significant cross-polarization and poor common mode rejection. These have to be properly characterized and calibrated (see, e.g., [73]). This is the methodology selected for the HFI instrument on Planck, after validation on the BOOMERanG-03 balloon flight. The other approach modulates on the same bolometer the two orthogonal polarizations of the incoming radiation, by means of a rotating waveplate. The method is a dynamic implementation of the original measurement method by Stokes, which analyzes the polarization of the incoming radiation by means of a waveplate followed by a polarizer. With a half-wave plate a modulated signal at 4 times the rotation frequency is produced. Suitable materials for efficient waveplates at mm wavelengths are quartz or sapphire, and using a stack of waveplates a wide bandwidth can be covered with the same modulator [81, 82]; moreover, metal-mesh waveplates are also being developed [83]. The main problem with this approach is the necessity of a uniform waveplate, with its optical axis perfectly aligned to the spin axis. Moreover, the waveplate must spin at cryogenic temperature, without introducing vibrations and microphonics in the detectors. The mapping speed of this method is limited by the necessity of integrating on each sky pixel for several rotations of the waveplate. To solve this problem, fast spinning levitating waveplates are being developed [84]: this technology is required for space-borne missions devoted to CMB polarization currently under study. 5. – CMB anisotropy: current status and open issues Precision cosmology is becoming a reality, and this is largely due to the measurements of CMB anisotropy carried out in the last 10 years. The emerging scenario, however, has opened three enigmas: Inflation, Dark Matter, Dark Energy. In the following we show how forthcoming measurements of the CMB can shed light on these issues. The all-sky maps produced by COBE have been confirmed and improved by WMAP: the large-scale structure of the last scattering surface is thus now well measured. The power spectrum at large angular scales (multipoles lower than 20) is well consistent with a Sachs-Wolfe plateau, with one noticeable exception: the quadrupole component is somewhat low. This has been confirmed by the WMAP 3 years data. However, the detailed likelihood function of the quadrupole is non-trivial, and the probability that this is a chance result is not negligible (see, e.g., [85]). In addition, there is some degree of alignment of the lowest multipoles [86, 87], and there is an evident galactic North-South anomaly in the CMB map of WMAP: the distribution is smoother in the North than in the South (see, e.g., [88-90]). These deviations are all at most at 3-σ level. However, they have triggered a lively debate, and several explanations have been attempted (see, e.g., [91] and references therein).

Precision measurements of the Cosmic Microwave Background

259

At intermediate angular scales there is evidence for localized non-Gaussian spots in the maps (see, e.g., [92, 93]). The “cold-spot” evident in the southern sky CMB image of WMAP seems to be also devoid of radio-sources [94, 95], thus suggesting a postrecombination origin, but also non-trivial homogeneity properties of our Universe or the presence of defects [96]. All this seems enough to call for an independent measurement of CMB anisotropy at large angular scales, with a wider frequency coverage to better monitor the foregrounds, and with the highest possible sensitivity, to make it easier to detect instrumental systematics. The Planck mission of the European Space Agency, covering the frequency range 30–850 GHz with an angular resolution of 30 –5 and with unprecedented sensitivity (ΔT /T ∼ 2 × 10−6 ) will assess all these issues. Planck promises a high control of systematics, due to the redundancy of the detectors, to the scanning strategy and to the location, in the Lagrange point L2 of the Sun-Earth system. The launch will be in 2009. The payload module consists of two instruments and one telescope. The Low-Frequency Instrument (LFI) uses HEMT amplifiers, while the High Frequency Instrument (HFI) uses cryogenic bolometers. The telescope is an off-axis Gregorian with a 1.50 × 1.89 m ellipsoid primary. The two instruments have been described in [97, 98], and the science case is described in detail in [99]. To date, there is no full-sky map of the mm-wave sky available at the frequencies covered by HFI! HFI is a unique tool to measure the full sky and to separate the different components contributing to diffuse emission. Photon noise of the CMB itself will be the major limitation to the sensitivity of the CMB channels in HFI. Higher-frequency channels will measure galactic foregrounds. The two instruments have been calibrated, and their performance is consistent with or exceeds the specifications. So we can expect a precisely calibrated instrument, operating in the best possible space environment, producing by 2010 maps covering the full wavelength range and angular resolution of primary CMB anisotropy. At small angular scales, the third peak and the damping tail of the angular power spectrum of the CMB are not measured as well as multipoles  < 500. There is evidence for excess anisotropy at multipoles  > 2000 [100, 101, 17]. Is this due to unresolved clusters of galaxies, via the Sunyaev-Zeldovich effect? Planck will assess these issues very well. Surveys of Sunyaev-Zeldovich effect in a large number of clusters of galaxies can provide fundamental cosmological information. Planck will contribute with a shallow survey of many thousand clusters; very powerful machines, based on larger telescopes and larger arrays of bolometric detectors (see, e.g., [52]) will provide huge data sets, allowing an independent measurement of the Hubble constant, and investigation of Dark Energy via cluster counts (see, e.g., [102]). 6. – Testing inflation There are basically two CMB observables related to inflation: anisotropy and polarization. The general slope of the power spectrum of CMB anisotropy is related to the spectral index of the power spectrum of primordial density perturbations. In the inflationary

260

P. de Bernardis and S. Masi

paradigm, primordial density perturbations derive from quantum fluctuations present in the pre-inflation era, and their power spectrum can be computed quite accurately (see, e.g., [103]). A power law with a spectral index ns  1 is expected. The power spectrum of CMB anisotropy is very sensitive to this parameter, when measured on a wide multipoles range to break degeneracies with other parameters. Current CMB measurements constrain ns to be 0.958 ± 0.016 (WMAP only [35]) or 0.947 ± 0.015 (WMAP plus other anisotropy experiments [35]), fully consistent with the prediction of inflation. Currently we have a 2-σ detection of ns < 1 from WMAP. It has been shown [99] that the power spectrum measurements of Planck will be so precise that a spectral index around 0.99 will be immediately detected, improving the current indication to the level of a definitive measurement. . 6 1. CMB polarization measurements. – CMB photons are Thomson-scattered by electrons at recombination. Linear polarization in the scattered radiation is obtained if there is a quadrupole anisotropy in the incoming, unpolarized photons [104]. This can be produced in two ways. The first, unavoidable source of quadrupole anisotropy of the photon field is the density fluctuation field present at recombination. Density fluctuations induce peculiar velocities in the primeval plasma. For this reason a given electron receives redshifted or blueshifted radiation from the surrounding electrons. Where there is a velocity gradient, a quadrupole anisotropy in the radiation is generated, and the scattered radiation is polarized. So the measurement of the polarization of the CMB probes the velocity field present at recombination. This effect, due to scalar fluctuations, produces a non-rotational polarization field (called E-modes of CMB polarization). The E-mode polarization spectrum (and its correlation with the anisotropy, T E) can be computed very accurately from the density fluctuations inferred by the measured anisotropy spectra. A signal of the order of a few μK r.m.s. is expected for an experiment with angular resolution better than 1◦ . The power spectrum of this signal has maxima where there are minima in the anisotropy power spectrum, just because in a density oscillation there is maximum velocity when the density is equal to the average, while there is zero velocity when the density fluctuation is maximum. The second source of quadrupole anisotropy at recombination is the presence of long-wavelength gravitational waves. If, as expected in the inflationary scenario, a stochastic background of gravitational waves is generated in the very early Universe, then we should be able to see an additional component of the polarization field. The amplitude of this component is very small (100 nK or lower, depending on the energy scale of inflation), but this has also a curl component (Bmode). Using proper analysis methods, the B-mode inflationary component can thus be disentangled from the dominant E-mode, opening a unique window to probe the very early Universe and the physics of extremely high energies (around 1016 GeV) (see, e.g., [105]). In addition, polarization measurements will provide essential information on the reionization process. Considerable effort is being spent by CMB experimentalists to prepare high-accuracy and -sensitivity experiments to detect the rotational component of CMB polarization.

Precision measurements of the Cosmic Microwave Background

261

There are three big issues to be solved for this measurement: – Detector noise: the signal we are looking for is in the 1–100 nK range. Successful polarization surveys to date have reported measurements of signals of the order of 2 μK r.m.s. Since cryogenic bolometers are already close to be limited by photon noise of the CMB itself, the 100× improvement in sensitivity can only be obtained increasing the number of detectors, so that the mapping speed is improved. The likelihood to detect the primordial gravitational waves for different levels of noise has been estimated in several papers (see, e.g., [106]). However, the real difficulty is to solve simultaneously the other issues listed below. – Systematic effects: the signal to be detected is smaller than detector noise that it is very difficult to detect low-level systematics. Current polarization experiments have managed to keep the systematic effects below about 0.1 μK. Here we want to improve this by a factor around 100. The only way to improve here is to experiment. New polarization modulators and optical components must be characterized with unprecedented accuracy. Enough to keep the experimentalists busy for years with laboratory developments and ground-based and balloon-borne experiments. – Polarized foregrounds: our Galaxy emits polarized radiation: elongated interstellar grains, aligned by the Galactic magnetic field, produce thermal emission with a few percent polarization degree [107]; radiation emitted by the electrons of the interstellar medium spiraling in the Galactic magnetic field produces highly polarized synchrotron radiation. A first survey of this emission has been carried out by the WMAP satellite [71]. The level of total polarized emission is up to 100 times larger than the goal polarization signal from primordial gravitational waves. It is thus necessary to characterize the polarized foreground at the 1% level. The EBEX balloon-borne instrument [108] aims at detecting the B-modes by means of a high resolution (< 8 ) telescope and large-format arrays of bolometers working at 150, 250, 350, 450 GHz. The polarization is modulated by an achromatic rotating half-wave plate: a technique pioneered by the MAXIPOL experiment [80]. The instrument is to be flown on a long-duration balloon in Antarctica. SPIDER [109] is devoted to large-scale measurements of CMB polarization, obtained with cryogenic bolometers covering the spectral range from 80 to 270 GHz. A large fraction of the sky is observed during an ultra-long duration balloon flight. The instrument is a precursor of the EPIC CMB Polarization satellite, studied in the framework of the NASA Beyond Einstein program [110]. On the European side, in the framework of the Cosmic Vision ESA program, the BPol satellite has been proposed [111, 112]. This is based on a set of refractive telescopes (one per band, from 45 to 350 GHz), each with its own wave-plate polarization modulator and its bolometric detector array. Although this experiment was not selected for the first round of Cosmic Vision 2015-2025 missions, the community of B-Pol is still extremely active in developing the needed technology and test it in pathfinder observations: detectors

262

P. de Bernardis and S. Masi

and modulators, for example, will be tested with the ground-based ClOVER [113] and BRAIN [114] experiments, operating with sub-degree resolution, and with the balloon B-B-Pol, operating at large angular scales. These missions will allow us to validate the involved technologies, and, most important, to detect systematic effects related to the measurement, and identify mitigation strategies. In the case of the large-scale polarization mission B-B-Pol (funded by ASI), the idea is to scan the sky with a balloon-borne telescope spinning in azimuth (like Archeops) during a circumpolar flight in the polar night. The payload design strategy is based on the use of sensitive (and many, a few hundred) detectors directly fed by corrugated feedhorns. The focal plane of the telescope is kept small to avoid off-axis positions: to accommodate all the detectors we prefer to multiply the number of telescopes. A separate cryogenic polarization modulator (rotating waveplate) is used for each telescope, so that it can be optimized for relatively narrow frequency bands. 7. – High-resolution CMB observations Our knowledge of the distribution of visible matter in the Universe has improved significantly, thanks to the 3D galaxy surveys like 2DF and SDSS. Galaxy filaments form a sort of “cosmic web” with clusters and voids. From X-rays images of the clusters we have evidence that the potential wells of clusters of galaxies are full of hot (around 10 keV), ionized and diluted gas, which is bright in the X-rays. Can CMB observations help us in understanding the formation and evolution of structures? . 7 1. Sunyaev-Zeldovich effect. – The photons of the Cosmic Microwave Background can interact with the hot gas, receiving a small boost in energy from the electrons in the gas (by inverse Compton): this is the so called Sunyaev-Zeldovich (S-Z) effect. A first-order calculation of the Inverse Compton Effect for CMB photons against charged particles in the hot gas of clusters can be done as follows: the cluster optical depth is τ nσ, where  is a few Mpc, n < 10−3 cm−3 and σ = 6.65 × 10−25 cm2 . So τ  0.01: there is a 1% likelihood that a CMB photon crossing the cluster is scattered by an electron of the hot gas. Since Ee  Eγ , the electron transfers part of his energy to the photon. To first order, the energy gain of the photon and the resulting CMB temperature anisotropy are (22)

Δν kTe Δν ΔT

τ

10−4 .

0.01 → 2 ν me c T ν

This is not a small signal: maps of the CMB with sensitivity of 10−5 of the background per pixel are now routinely obtained by CMB anisotropy experiments. Since all photons get a positive boost in energy and the number of photons is conserved, there is a shift of the spectrum of the CMB anisotropy in the direction of the cluster, which means a decrement of the brightness at frequencies below 217 GHz, where the CMB anisotropy spectrum is increasing, and an increment at frequencies above 217 GHz. This spectrum is very peculiar and can be measured by comparing the signal from the cluster to the

Precision measurements of the Cosmic Microwave Background

263

Fig. 5. – The differential spectrum of the Sunyaev-Zeldovich effect (S-Z) in a cluster of galaxies, for different electron temperatures. The S-Z is compared to the spectra of competing effects: primordial CMB anisotropy (CMB) and local emission from synchrotron (S), free-free (F) and interstellar dust (D). Due to the peculiar positive-negative spectrum, the S-Z effect can be easily separated by local effects if a multiband instrument (like OLIMPO) or a spectrometer (like SAGACE) are used. The bands explored by the SAGACE spectrometer are also shown as dashed regions.

signal from a reference region outside the cluster. In fig. 5 we plot the typical spectrum of the S-Z effect. The S-Z effect is one of the three main sources of anisotropy in the microwave sky at high galactic latitudes and millimetre wavelengths. The primary anisotropy of the CMB, and the anisotropy of the Extragalactic Far Infrared Background (FIRB) are the other main contributors. The “cosmological window” where these components are dominant extends roughly from 90 to 600 GHz: at lower frequencies interstellar emission of spinning dust grains, free-free and synchrotron dominate over the cosmological background; at higher frequencies the clumpy foreground from cirrus dust dominates the sky brightness even at high galactic latitudes. The intensity of the S-Z effect is proportional to the density of the intergalactic electrons (n), while the X-ray brightness of the same cluster is proportional to n2 . So

264

P. de Bernardis and S. Masi

the S-Z measurements are sensitive to the intracluster gas in the peripheral regions of the cluster, while X-ray measurements are not. Moreover, combining measurements of the two quantities it is possible to derive the angular diameter distance of the clusters of galaxies [115-117]. Observations of many clusters would allow to build an Hubble diagram, and from this to measure the Hubble constant. These measurements are being carried out (see, e.g., [118]), but the error in the determination of H0 is still quite large. To improve these measurements, we need to collect a larger sample of clusters (and forthcoming experiments like SPT [52] and ACT [119] will do a wonderful job in this respect), and also to improve our knowledge of the details of the S-Z effect (cooling flows, inhomogeneities, relativistic corrections and so on): a survey of nearby clusters with excellent inter-channel calibration and wide frequency coverage will be instrumental in this. The S-Z effect depends on the optical depth, but it does not depend on the distance of the clusters (it is like an opacity effect). So we can see clusters that are too faint to be visible in the optical or in the X-rays bands. The number of clusters seen at different distances is a strong function of the Dark Energy density: clusters can in principle be used as probes of the history of Dark Energy [120]. Observing selected clusters where dark matter is separated from baryons it is possible to study the S-Z effect generated by annihilation products of the Dark Matter, thus testing the nature of Dark Matter [121]. This requires ∼ arcmin resolution to resolve the clouds of dark and baryonic matter. The best frequency to operate is around 220 GHz, where the baryonic S-Z signal is nearly null, and only the DM signal and the kinetic S-Z are present. This high frequency represents a challenge for ground-based telescopes. OLIMPO [122], a 2.6 m stratospheric balloon-borne telescope, will carry out its survey in four frequency bands centered at 140, 220, 410 and 540 GHz, in order to be optimally sensitive to the S-Z effect and to efficiently reject competing sources of emission. A satellite version of this telescope has been recently proposed to the Italian Space Agency. The payload, named SAGACE (Spectroscopic Active Galaxies And Clusters Explorer) is able to perform spectral measurements in the range 100 to 760 GHz, using an imaging FTS in the focus of an OLIMPO-like telescope. Four medium size arrays of bolometers improve the mapping speed of the instrument, which can produce maps of diffuse mm emission with a resolution of ∼ 1 . The result will be a catalog of spectra of a few thousand AGNs and Clusters. The high S/N of the measurement allows a very detailed study of the thermal, non-thermal and kinematic S-Z effect, the Hubble diagram, the study of TCMB (z) and the identification of the physical mechanisms of emission in AGNs. In addition, the high-frequency band (720–260 GHz) will provide tomography of early galaxies using the C + line in the “redshift desert”, thus complementing optical surveys of galaxies. . 7 2. Wavelength spectrum of CMB anisotropy. – The CMB is differentially absorbed/scattered by atoms. In particular, it is believed that, during reionization, the first metals are produced by population-III stars, enriching the IGM. In principle, a tomography of the abundance of particular metals can be carried out by precisely calibrated, high-resolution, multi-band CMB anisotropy experiments [123]. This kind of

Precision measurements of the Cosmic Microwave Background

265

observations requires very high angular resolution, very accurate spectroscopy, and the absence of atmospheric contamination of the measurements. A large space telescope mission coupled to FTS analyzers or other forms of advanced spectrometers is probably the only way to carry out such demanding observations (SAGACE could be a perfect pathfinder for this mission). In turn, these observations can provide essential information on reionization, complementary to other probes like Ly-α emitters, 21 cm and IR surveys, CMB polarization. . 7 3. CMB anisotropy and large-scale structure. – The path of the photons, from the last scattering surface to the observer, traverses the large-scale structure of the Universe: these density inhomogeneities produce mainly two effects. Gravitational lensing by intervening mass distorts the anisotropy and the polarization of the CMB. Photons are deflected typically by a few arcmin, with a coherence scale of a few degrees [124]. The main effect is a smoothing of the acoustic peaks of anisotropy and polarization power spectra, and the production of B-mode polarization at high multipoles. The former will be detected by the high-accuracy anisotropy measurement of Planck. The latter will be measured by current polarization experiments like QUAD [77] and ClOVER [113]. These measurements have the potential to measure the growth of structure and the properties of dark matter, including massive neutrinos [125]. And, of course, are needed to remove this contaminant in searches of primordial B-modes. Gravitational redshift produced by large-scale structures also produces CMB anisotropy, via the Integrated Sachs-Wolfe (ISW) effect [126, 127], observable at large angular scales because at small scales the effect is averaged out on the line of sight through many structures. Since density perturbations stop their growth when dark energy starts to dominate the expansion, the ISW is very sensitive to dark energy and its equation of state. However, being a large-scale effect, cosmic variance prevents an accurate measurement. A possible solution is the correlation of the ISW with lensing maps of the CMB: this requires extremely accurate anisotropy and polarization measurements. 8. – Conclusions The outstanding enigmas of current cosmology (Inflation, Dark Matter, Dark Energy) can be tested with ambitious CMB experiments. The technology and methodology is now mature for precise measurements, which are carried out by large international collaborations. These activities require significant resources, but promise fundamental results for our knowledge of the Universe and of fundamental physics. REFERENCES [1] [2] [3] [4]

Mather J. et al., Astrophys. J., 512 (1999) 511. Fixsen J. et al., Astrophys. J., 612 (2004) 86. Burigana C. et al., Astron. Astrophys., 303 (1995) 323. Padmanabhan T., Structure Formation in the Universe (Cambridge University Press, Cambridge, UK) 1993, ISBN 0-521-41448-2.

266

P. de Bernardis and S. Masi

Copeland E. J. et al., Phys. Rev. Lett., 71 (1993) 219. Turner M. S., Phys. Rev. Lett., 71 (1993) 3502. White M. et al., Astrophys. J., 418 (1993) 535. Hu W. and Dodelson S., Annu. Rev. Astron. Astrophys., 40 (2002) 171. Lewis A. et al., Astrophys. J., 538 (2000) 473, see also http://camb.info. de Bernardis P. et al., Nature, 404 (2000) 955. Lee A. T. et al., Astrophys. J. Lett., 561 (2001) L1. de Bernardis P. et al., Astrophys. J., 564 (2002) 559. Halverson N. W., Astrophys. J., 568 (2002) 38. Ruhl W. J. et al., Astrophys. J., 599 (2003) 786. Grainge K. et al., Mon. Not. R. Astron. Soc., 341 (2003) L23. Jones W. J. et al., Astrophys. J., 647 (2006) 823. Kuo C. L. et al., Astrophys. J., 664 (2007) 687. Hinshaw G. et al., Astrophys. J. Suppl. Ser., 148 (2003) 135. Hinshaw G. et al., Astrophys. J. Suppl. Ser., 170 (2007) 288. de Bernardis P. et al., Astrophys. J. Lett., 433 (1994) L1. Bond J. R. et al., Phys. Rev. D, 57 (1998) 2117. Bond J. R. et al., Astrophys. J., 533 (2000) 19. Dodelson S. and Knox L., Phys. Rev. Lett., 84 (2000) 3523. Tegmark M. and Zaldarriaga M., Astrophys. J., 544 (2000) 30. Tegmark M. and Zaldarriaga M., Phys. Rev. Lett., 85 (2000) 2240. Bridle S. L. et al., Mon. Not. R. Astron. Soc., 321 (2001) 333. Douspis M. et al., Astron. Astrophys., 368 (2001) 1. Lange A. E. et al., Phys. Rev. D, 63 (2001) 042001. Jaffe A. H. et al., Phys. Rev. Lett., 86 (2001) 3475. Lewis A. and Bridle S., Phys. Rev. D, 66 (2002) 103511. Netterfield C. B. et al., Astrophys. J., 571 (2002) 604. Spergel D. N. et al., Astrophys. J. Suppl., 148 (2003) 175. Bennett C. et al., Astrophys. J. Suppl., 148 (2003) 1. Tegmark M. et al., Phys. Rev. D, 69 (2004) 103501. Spergel D. N. et al., Astrophys. J. Suppl., 170 (2007) 377. Komatsu E. et al., Astrophys. J. Suppl., 180 (2009) 330. De Bernardis F. et al., Phys. Rev. D, 78 (2008) 083535. De Bernardis F. et al., J. Cosmol. Astroparticle Phys., 06 (2008) 13. Fogli G. L. et al., Phys. Rev. D, 78 (2008) 033010. Rohlfs K. and Wilson T. L., Tools of Radio Astronomy (Springer) 2004. Richards P., J. Appl. Phys., 76 (1994) 781. Mauskopf P. D. et al., Appl. Opt., 36 (1997) 4. Jones B. et al., Proc. SPIE, 4855 (1997) 227, astro-ph/0209132. Lee S. F. et al., Appl. Opt., 37 (1998) 3391. Gildemeister J. M. et al., Appl. Phys. Lett., 74 (1999) 868. Day P. K. et al., Nature, 425 (2003) 817. Mather J., Appl. Opt., 21 (1982) 1125. Lamarre J. M. et al., New Astron. Rev., 47 (2003) 11. Lawrence C. R. et al., Millimeter-wave MMIC cameras and the QUIET experiment, in Millimeter and Submillimeter Detectors for Astronomy II, edited by Zmuidzinas J., Holland W. S. and Withington S., Proc. SPIE, 5498 (2004) 220. [50] Kreysa E. et al., Bolometer Arrays for mm/submm Astronomy, in Experimental Cosmology at Millimetre Wavelengths, edited by De Petris M. and Gervasi M. AIP Conf. Proc., 616 (2002) 262.

[5] [6] [7] [8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29] [30] [31] [32] [33] [34] [35] [36] [37] [38] [39] [40] [41] [42] [43] [44] [45] [46] [47] [48] [49]

Precision measurements of the Cosmic Microwave Background

[51] [52] [53] [54] [55] [56] [57] [58] [59] [60] [61] [62] [63] [64] [65] [66] [67] [68] [69] [70] [71] [72] [73] [74] [75] [76] [77] [78] [79] [80] [81] [82] [83] [84] [85] [86] [87] [88] [89] [90] [91] [92] [93] [94] [95] [96] [97] [98] [99] [100]

Mehl J. et al., J. Low Temp. Phys., 151 (2008) 697. Ruhl J. et al., Proc. SPIE, 5498 (2004) 11. Staniszewski Z. et al., submitted to Astrophys. J., astro-ph/0810.1578. Niemack M. D. et al., to be published in J. Low Temp. Phys.. Doyle S. et al., J. Low Temp. Phys., 151 (2008) 530. See www.ticra.com. Keller J. B., J. Opt. Soc. Am., 52 (1962) 116. Mainella G. et al., Appl. Opt., 35 (1996) 2246. Piacentini F. et al., Astrophys. J. Suppl., 138 (2002) 315. Crill B. P. et al., Astrophys. J. Suppl., 148 (2003) 527. Benoit A. et al., Astroparticle Physics, 17 (2001) 101. Page L. et al., Astrophys. J., 585 (2003) 566. Hill R. S. et al., Astrophys. J. Suppl., 180 (2009) 246. Lamarre J. M. et al., New Astron. Rev., 47 (2003) 1017. Delabrouille J. et al., Mon. Not. R. Astron. Soc., 298 (1998) 445. Kovac J. M. et al., Nature, 420 (2002) 772. Barkats D. et al., Astrophys. J. Lett., 619 (2005) 127. Barkats D. et al., Astrophys. J. Suppl., 159 (2005) 1. Readhead A. C. S. et al., Science, 306 (2004) 836. Kogut A. et al., Astrophys. J. Suppl., 148 (2003) 161. Page L. et al., Astrophys. J. Suppl., 170 (2007) 335. Bischoff C. et al., Astrophys. J., 684 (2008) 771. Masi S. et al., Astron. Astrophys., 458 (2006) 687. Montroy T. E. et al., Astrophys. J., 647 (2006) 813. Piacentini F. et al., Astrophys. J., 647 (2006) 833. Wu J. H. P. et al., Astrophys. J., 665 (2007) 55. Ade P. A. R. et al., Astrophys. J., 674 (2008) 22. Pryke C. et al., Astrophys. J., 692 (2009) 1247. Jones B. et al., Proc. SPIE, 4855 (2003) 227, astro-ph/0209132. Johnson B. R. et al., Astrophys. J., 665 (2007) 42. Pisano G. et al., Appl. Opt., 45 (2008) 6982. Savini G. et al., Appl. Opt., 45 (2006) 8907. Pisano G. et al., Appl. Opt., 45 (2006) 6982. Hanany S. et al., IEEE Trans. Appl. Supercond., 13 (2003) 2128. Efstathiou G., Mon. Not. R. Astron. Soc., 348 (2004) 885. De Oliveira-Costa A. et al., Phys. Rev. D, 69 (2004) 063516. Eriksen H. K. et al., Astrophys. J., 612 (2004) 633. Eriksen H. K. et al., Astrophys. J., 605 (2004) 14. Hansen F. et al., Mon. Not. R. Astron. Soc., 354 (2004) 641. Eriksen H. K. et al., Astrophys. J., 660 (2007) L81. Inoue K. T. and Silk J., Astrophys. J., 648 (2006) 23. Vielva P. et al., Astrophys. J., 609 (2004) 22. Cruz M. et al., Mon. Not. R. Astron. Soc., 356 (2005) 29. Rudnick L. et al., Astrophys. J., 671 (2007) 40. Mc Ewen J. D. et al., Mon. Not. R. Astron. Soc., 384 (2008) 1289. Cruz M. et al., Science, 318 (2007) 1612. Lamarre J. M. et al., New Astron. Rev., 47 (2003) 1017. Valenziano L. et al., New Astron. Rev., 51 (2007) 287. Planck: The Scientific Programme, ESA-SCI(2005)1. Pearson T. J. et al., Astrophys. J., 591 (2003) 556.

267

268 [101] [102] [103] [104] [105] [106] [107] [108] [109] [110] [111] [112] [113] [114] [115] [116] [117] [118] [119] [120] [121] [122] [123] [124] [125] [126] [127]

P. de Bernardis and S. Masi

Kuo C. L. et al., Astrophys. J., 600 (2004) 32. Carlstrom J. E. et al., Ann. Rev. Astron. Astrophys., 40 (2003) 643. Mukhanov V., Sov. Phys. JETP, 67 (1988) 1297. Rees M., Astrophys. J. Lett., 53 (1968) L1. Dodelson S., Modern Cosmology: Anisotropies and Inhomogeneities in the Universe (Academic Press) 2003. Pagano L. et al., astro-ph/0707.2560 (2007). Ponthieu N. et al., Astron. Astrophys., 444 (2005) 327. Oxley P. et al., Proc. SPIE Opt. Eng., 5543 (2004) 320. MacTavish C. et al., Proceedings of Science, 71 (2006). Bock J. et al., astro-ph/0604101. www.b-pol.org. de Bernardis P. et al., Exp. Astron., 23 (2009) 5. Taylor A. C., New Astron. Rev., 50 (2006) 993. Polenta G. et al., New Astron. Rev., 51 (2007) 256. Gunn J. E. et al., Observational Cosmology, 1 Geneva Obs., Sauverny (1978) p. 3. Silk J. and White S., Astrophys. J. Lett., 226 (1978) L103. Cavaliere A. et al., Astron. Astrophys., 75 (1979) 322. Bonamente M. et al., Astrophys. J., 647 (2006) 25B. Fowler J. W. et al., Appl. Opt., 46 (2007) 3444. Nunes N. J. et al., Astron. Astrophys., 450 (2006) 899. Colafrancesco S. et al., Astron. Astrophys. Lett., 467 (2007) L1. Masi S. et al., Mem. S. A. It., 74 (2003) 96. Hernandez-Monteagudo C. et al., Astrophys. J., 653 (2006) 1. Blanchard A. and Schneider J., Astron. Astrophys., 184 (1987) 1. Hu W., Phys. Rev. D., 65 (2003) 023003. Sachs R. K. and Wolfe A. M., Astrophys. J., 147 (1967) 73. Kofman L. A. and Starobinskij A. A., Sov. Astron., 11 (1985) 27.

DOI 10.3254/978-1-60750-038-4-269

Theory of neutrino masses and mixings ´ G. Senjanovic ICTP, Strada Costiera 11, 34014 Trieste, Italy

Summary. — The tiny neutrino masses and the associated large lepton mixings provide an interesting puzzle and a likely window to the physics beyond the standard model. This is certainly true if neutrinos are Majorana particles, since unlike in the Dirac case, the standard model is not a complete theory. The Majorana case leads to lepton number violation manifested through a neutrinoless double-beta decay and same-sign dileptons possibly produced at colliders such as LHC. I discuss in these lectures possible theories of neutrino mass whose predictions are dictated by their structure only and this points strongly to grand unification. I cover in detail both SU (5) and SO(10) grand unified theories, and study the predictions of their minimal versions. I argue that the theory allows for a (moderate) optimism of probing the origin of neutrino mass in near future.

1. – Foreword The theory of neutrino masses and mixings is a rich subject, with a continuos flow of papers as you are reading these lecture notes. There is no way I could do justice to this vast field in such a short time and space and so I chose to concentrate on what my taste dictated. In order to be as complete and as pedagogical as possible on the issues chosen to be discussed, I have completely omitted a popular field of horizontal symmetries which are used in order to make statements on neutrino masses and mixings, and I apologize to the workers in the field. My decision is prompted by my lack of belief in this approach which to me amounts often to a change of language. c Societ`  a Italiana di Fisica

269

270

´ G. Senjanovic

Instead of accepting the values of these parameters, one typically choses some textures of fermion mass matrices (this is done by the use of symmetries, often discrete ones) which then leads to definite values of masses and/or mixings. The problem that I have with this approach is that this is like saying that the proton is stable because of baryon number symmetry or that the photon is massless because of gauge invariance. The symmetries we assume need not to be exact, and the departures from these symmetries will give departures from the values that follow consequently. It does not make sense to me to say that proton and neutron should have the same mass because of SU (2) isospin invariance, and here I am sure that the reader will agree with me. The small mass difference between the proton and the neutron only says that the isospin symmetry is quite good, albeit approximate symmetry. In searching for the origin of neutrino mass, I have opted here to theories whose inner structure leads to neutrino mass and whose predictions depend only on the same inner structure. Two such examples, the very ones that lead originally to the understanding of the smallness of neutrino mass through the so-called see-saw mechanism, are provided by left-right symmetric theories and the SO(10) grand unified theory. They provide the core of my lectures, and I have included one of the Appendices (D) on the group theory of SO(2N ) to in order to facilitate the reader’s job. Grand unified theories are particularly interesting since they typically fix their own scale. For this reason, I make an exception and discuss in detail also an SU (5) grand unified theory, although in its minimal form it was tailor fit for massless neutrinos, just as the minimal standard model. However, a minimal extension needed to account for neutrino masses and mixings leads to exciting predictions of new particles and interactions likely to be tested at LHC. Furthermore, an understanding of SO(10) becomes much easier after one masters a simple, minimal SU (5) theory, which will always remain as a laboratory of the theory of grand unification and thus a large portion of these notes is devoted to it, including a short Appendix C. The readers familiar with SU (5) can go directly to the last subsection relevant for neutrino mass. Since my lectures are far from being complete, I suggest here to complement them with these two pedagogical expos´es on the subject of neutrino masses and mixings. At the end of the lectures, I include some references for further reading. 1) Mohapatra, Pal [1]. An excellent book, with a detailed analysis of Majorana neutrinos, left-right symmetry, see-saw mechanism and SO(10) grand unification, which provides the core of my lectures. 2) Strumia, Vissani review [2]. Highly recommended especially for the phenomenology of neutrino masses and mixings. Extremely well written, continuously updated, concise, clear and surprisingly complete study of neutrino oscillations and related topics. 2. – Introduction Today we know for fact that at least two neutrinos are massive and by analogy with quarks we need the leptonic mixing matrix (see the lectures by Strumia in these Proceedings).

271

Theory of neutrino masses and mixings

We start by reviewing what the Standard Model (SM) says about neutrino masses and mixings. . 2 1. Standard Model review . – The minimal Standard Model (MSM) is an SU (3) × SU (2) × U (1) gauge theory with the following fermionic assignment [3]:   u ; d   ν ; L ≡ e

qL ≡

(1)

(uc )L , (dc )L , (ec )L ,

where we have omitted the color index for quarks and we work here with left-handed anti-fermions instead of right-handed fermions (see Appendix A, formula (A.11))) T (ψ C )L ≡ C ψ¯R .

(2)

Actually, we will sometimes work with right-handed fermions too (as in sect. 4 on L-R symmetry), and it is important to be familiar and at ease with both notations. The maximal parity violation in the usual charged weak interactions is characterized by the maximal asymmetry between left and right: only left-handed fermions interact with W ± gauge bosons. On top of that, the quark-lepton symmetry is broken by the minimality assumption: NO right-handed neutrinos. Hence a clear prediction: neutrinos are massless. In order to see that, recall that fermionic masses in the MSM stem from the Yukawa interactions with a Higgs doublet Φ T T LY = yu qlT Ciσ2 ΦucL + yd qL CΦ∗ dcL + yl lL CΦ∗ ecL + h.c.,

(3)

where the generation index is suppressed for simplicity. An equivalent expression involves right-handed particles instead of left-handed anti-particles LY = yu q¯l iσ2 Φ∗ uR + yd q¯L ΦdR + yl ¯lL ΦeR + h.c.

(4)

From the charge formula Q = T3 + Y /2,

(5)

The usual charges are reproduced with (6)

Yq =

1 , 3

Y = −1,

YuR =

4 , 3

2 YdR = − , 3

YeR = −2,

YΦ = 1.

Notice the physical interpretation for the hypercharge of the left-handed particles (7)

YL = B − L,

whereas YR has no physical interpretation and needs to be memorized.

272

´ G. Senjanovic

The B-L symmetry of the MSM is selected out: it is an anomaly free combination of accidental global symmetries B and L. In other words, B-L can be gauged. We will come back often to this important and suggestive fact. The minimality of (1), the broken symmetry between quarks and leptons is thus responsible for the only failure of this, otherwise extremely successful, theory. As it is, the MSM must be augmented in order to account for neutrino mass. If you insist, though, on the MSM degrees of freedom in (1), the Yukawa interactions that could lead to neutrino mass must clearly be higher dimensional LY (d = 5) = yν

(8)

(TL Ciσ2 Φ)(φT iσ2 L ) , M

where the new scale M signifies some new physics. Exercise: Show that there are only three possible d = 5, SU (2) × U (1) invariant operators of type (8). Show then that they are all equivalent. When the Higgs doublet gets a nonvanishing vacuum expectation value (vev) (9)

  0 , Φ = v

the charged fermions get the usual Dirac mass (10)

mf f¯ f ≡ mf (f¯L fR + f¯R fL ),

with mf = yf v. In the same manner, from (8) the neutrino gets a Majorana mass (11)

mν νLT CνL ,

with (12)

mν = yν

v2 . M

If M  θ, neutrinos are automatically lighter than the charged fermions; however if M v (or even M v), small mν may result from yν 1. Since this is an effective theory, we can say nothing about mν . In short, the absence of new light degrees of freedom indicates Majorana neutrino masses and the violation of the lepton number at the new scale M . From (8) and (11), one has ΔL = 2 which allows for the neutrinoless double-beta decay ββ 0 as shown in fig. 1 (13)

n + n → p + p + e + e¯.

273

Theory of neutrino masses and mixings

n

p W

e

xm n

e

W p

Fig. 1. – Neutrinoless double-β decay through a Majorana mass mM which breaks a neutrino fermionic line.

It is often argued that ββ 0 probes mM , however, the situation is more complex. Namely, the MSM with neutrino Majorana mass is not a complete theory —it must be completed through a d = 5 operator (8) and a new physics at M . We will see that the predictions for ββ 0 depend on the completion, to which we now turn to. The effective operator (8) is useful in discussing the qualitative nature of neutrino mass, but if we wish to probe the origin of neutrino masses we need a renormalizable theory beyond the MSM. There are three different possibilities of completing the MSM which all lead to the d = 5 operator upon integrating out the new physics; these are three different see-saw mechanisms. 3. – The see-saw mechanism We discuss here different realizations of the see-saw mechanism, in order of their popularity which coincides with the historic development. The idea is a renormalizable completion of the MSM that will lead to small neutrino mass. The end result must be a d = 5 operator discussed above, since that is dictated by the MSM gauge symmetry, as long as new physics is at a scale above MW . Fortunately, there are only three different possibilities and therefore we can and will discuss all of them in what follows. . 3 1. Right-handed neutrinos: type-I see-saw . – The most suggestive completion of the MSM is the introduction of νR (per family of fermions), a gauge singlet chiral fermion. This leads to new renormalizable Yukawa couplings (written here for one generation case only) (14)

ΔL = yD ¯L σ2 Φ∗ νR +

MR T ν CνR + h.c. 2 R

Introduce (15)

ν ≡ νL + C ν¯LT , T N ≡ νR + C ν¯R ,

274

´ G. Senjanovic

N X

YD

N YD

Fig. 2. – Diagrammatic representation of the type-I see-saw.

which gives the mass matrix for ν and N (see Appendix B)  (16)

0 mTD

 mD . MR

If MR mD , neutrinos would be predominantly Dirac particles. For MR mD , we have a messy combination of Majorana and Dirac, whereas for mD MR we would have a predominantly Majorana case (this case is rather interesting, since the gauge invariant scale MR is expected to be above MW : MR > MW ). In this case the approximate eigenstates are N with mass MN ≡ MR and ν with a tiny mass (17)

Mν = −mTD

1 mD . MN

This is the original see-saw formula [7] today called type I. As we know from (8), with heavy νR , neutrino mass must be of the type (11), confirmed here. Exercise: Prove explicitly (16) in the case of two generations. Hint: work with mD diagonal. It is clear from (16) that the number of νR ’s determines the number of massive light neutrinos: for each νR , only one νL gets a mass. In other words, we need at least two νR ’s in order to account for both solar and atmospheric neutrino mass differences. It is suggestive, though, to have a νR per family, in which case an accidental anomaly free global symmetry of the MSM can be gauged. A neutrino per generation is needed to cancel the U (1)3B-L anomaly. The diagrammatic representation of the see-saw in fig. 2 may be even clearer; it is easy to see that the heavy neutrino propagator gives the see-saw result. . 3 2. Y = 2, SU (2)L triplet Higgs: type-II see-saw. – Instead of νR , a Y = 2 triplet  L · σ can play the same role [8]. From the new Yukawas ΔL ≡ Δ (18)

ij T i CΔL j + h.c., ΔL(Δ) = yΔ

275

Theory of neutrino masses and mixings

Y Fig. 3. – Diagrammatic representation of the type-II see-saw.

where i, j = 1, . . . , N counts the generations, neutrinos get a mass when ΔL gets a vev (19)

Mν = yΔ Δ.

The vev Δ results form the cubic scalar interaction (20)

2 Tr Δ†L ΔL + . . . , ΔV = μΦT σ2 Δ∗L Φ + MΔ

with (21)

Δ

μv 2 2 , MΔ

where one expects μ of order MΔ . If MΔ  v, neutrinos are naturally light. Notice that (19) and (21) reproduce again the formula (11) as it must be: for large scales of new physics, neutrino mass must come from d = 5 operator in (8). Again, the diagrammatic representation may be even clearer, see fig. 3. . 3 3. Y = 0, SU (2)L triplet fermion: type-III see-saw. – The Yukawa interaction in (14) for new singlet fermions carries on straightforwardly to SU (2) triplets too, written now in the Majorana notation (where for simplicity the generation index is suppressed and also an index counting the number of triplet —recall that at least two are needed in order to provide two massive light neutrinos) (22)

ΔL(TF ) = yT T Cσ2σ · TF Φ + MT TFT C TF .

In exactly the same manner as before in Type I, one gets a type-III see-saw for MT  v, (23)

Mν = −yTT

1 yT v 2 MT

Again, as in the Type-I case, one would need at least two such triplets to account for the solar and atmospheric neutrino oscillations (or a triplet and a singlet). And, as before, (23) simply reproduces (11) for large MT , and SU (2) × U (1) symmetry dictates.

276

´ G. Senjanovic

It can easily be shown that these three types of see-saw exhaust all the possibilities of reproducing (8) and (11). Exercise: Show that the three possible different operators of the type (8) correspond to the three different types of see-saw. Since (8) and (11) describe effectively neutrino Majorana masses in the MSM, the question is wether we gain anything by going to the renormalizable see-saw scenarios. If the new scales MR , MΔ and MT are huge and not accessible to experiment, then arguably (16), or (19) and (21), or (23), are the (8) or (11). In a sense, they are only a change of language, but not a useful language. We have traded the couplings yν between physical, observable particles, to the unknown yD (or yΔ or yT ) couplings and the unknown masses of the heavy particles that we integrate out. The issue, in any case, is not so much to explain the smallness of the neutrino mass, but to relate it to some other, new, physical phenomenon. After all, small fermion masses are controlled by small Yukawa couplings. This is reminiscent of the Fermi theory of weak interactions. At low energies E

MW , the concept of a massive gauge boson W was not useful and for many years one kept working on the Fermi theory instead. For otherwise, one would be trading the interactions between light physical states for the unknown coupling with W and unknown MW . There are two cases when one is better off talking of W , though: 1) When one can reach the energy E MW and thus make W experimentally accessible. 2) Even when E MW , but one has a dynamical theory of W interactions as in the MSM. The SU (2) × U (1) gauge symmetry of MSM made clear predictions at low energies by correlating charged and neutral current processes. Ideally, we would like both 1 and 2. By complete analogy, we need then either MR , MΔ or MT close to MW in order to be accessible at LHC, or we need a theory of new interactions. The nice example for the latter is Grand Unification: through q- symmetry it, in principle, correlates quark and lepton masses and mixings. A particularly appealing GUT is SO(10), since it unifies a family of fermions and has L-R symmetry as a finite gauge transformation in the form of Dirac’s charge conjugation. I will be discussing it at length later; for the moment suffice it to say that it predicts both Type-I and Type-II see-saw, but in minimal predictive versions their scale is very large, much above MW —and hopeless to detect directly. In summary, the main message of this chapter should be that the Majorana neutrino mass is rather suggestive from the theoretical point of view. As such, it provides a window to new physics at scale M of (8). The crucial prediction of this picture is the ΔL = 2 lepton number violation in processes such as ββ 0 . However, ββ 0 depends in general on the new physics at scale M , and it is desirable to have a direct probe of lepton number violation. In 1983, Keung and myself [36] suggested ΔL = 2 production of same-sign

Theory of neutrino masses and mixings

277

dileptons at colliders, accompanied by jets, as a direct probe of the origin of neutrino mass. We will discuss lepton number violation at length in sect. 7. What happens if the neutrino has a pure Dirac mass? In this case, mν = yD v and the smallness of mν simply requires the smallness of yD . The smallness of mν remains a puzzle controlled by small yD , as much as the smallness of me is controlled by a small electron Yukawa coupling. The MSM with Dirac couplings is a complete theory and needs no theory beyond it. The diversity of fermion masses and mixings encourages many workers in the field to look for flavor symmetries at high energies, precisely since the MSM is complete one has no sense of direction and the possibilities are infinite. The danger here is to be caught in semantics rather in physics, for one often trades the known masses and mixings of the physical states for the unmeasurable properties of the new heavy particles and/or textures of mass matrices that often cannot be probed. This is a generic problem of large-scale theories ad in order to verify them we would need to correlate the neutrino masses and mixings with some new physics. A nice example is proton decay in GUTs, to which we will come later. 4. – Left-right symmetry and neutrino mass This section is devoted to the left-right symmetric extension of the standard model and the issue of the origin of the breaking of parity. This theory played an important historic role in leading automatically to nonzero neutrino masses and the see-saw mechanism. There are two different possible left-right symmetries: parity and charge conjugation. The latter is the finite gauge transformation in SO(10), and is thus rather suggestive. Still, parity is normally identified with L-R symmetry, so I discuss next parity. The write-up here is rather simple and pedagogical, without too many technicalities. . 4 1. Parity as L-R symmetry. – Parity is the fundamental symmetry between left and right and its breaking, I believe, should be understood. In the standard model P is broken explicitly and clearly, in order to break P spontaneously, we must enlarge the gauge group. The minimal model is based on the gauge group [9-12] GLR = SU (2)L × SU (2)R × U (1)Y  with the quarks and leptons completely symmetric under L ↔ R (24)

    u u P ←→ QR = , QL = d L d R     ν ν P ←→ R = . L = e L e R

Notice that the requirement of left-right symmetry leads to the existence of the righthanded neutrino and now the neutrino mass becomes a dynamical issue, related to the pattern of symmetry breaking. In the Standard Model, where νR is absent, mν = 0; here

278

´ G. Senjanovic

instead we shall need to explain why neutrinos are so much lighter than the corresponding charged leptons. In this theory, the formula for the electromagnetic charge becomes Qem = I3L + I3R +

(25)

B−L . 2

This is in sharp contrast with the Standard Model, where the hypercharge Y was completely devoid of any physical meaning. So L-R symmetry is deeply connected with B-L symmetry; the existence of right-handed neutrinos implied by L-R symmetry is necessary in order to cancel anomalies when gauging B-L. Namely, the B-L symmetry is a global anomaly free symmetry of the SM, but without νR the gauged version would have (B-L)3 anomaly. Our primary task is to break L-R symmetry, i.e. to account for the fact that MWR  MWL , WR and WL denoting right-handed and left-handed gauge bosons, respectively. In order to do so, we need a set of left-handed and right-handed Higgs scalars whose quantum numbers we will specify later. Imagine for the moment two scalars ϕL and ϕR with P

ϕL ←→ ϕR .

(26)

Assume no terms linear in the fields (since ϕL and ϕR should carry quantum numbers under SU (2)L and SU (2)R ), we can write down the left-right symmetric potential (27)

V =−

μ2 2 λ λ (ϕL + ϕ2R ) + (ϕ4L + ϕ4R ) + ϕ2L ϕ2R , 2 4 2

where λ > 0 in order for V to be bounded from below, and we choose μ2 > 0 in order to achieve symmetry breaking in the usual manner. We rewrite the potential as (28)

V =−

μ2 2 λ λ − λ 2 2 (ϕL + ϕ2R ) + (ϕ2L + ϕ2R )2 + ϕL ϕR , 2 4 2

which tells us that the pattern of symmetry breaking depends crucially on the sign of λ − λ, since the first two terms do not depend on the direction of symmetry breaking (of course μ2 > 0 guarantees that ϕL  = ϕR  = 0 is a maximum and not a minimum of the potential). Exercise: Show that if 1) λ − λ > 0, in order to minimize V , we have either ϕL  = 0, ϕR  = 0, or vice versa. Due to the symmetry of V both solutions are equally probable. 2) λ − λ < 0, we need ϕL  = 0 = ϕR  and L-R symmetry implies ϕL  = ϕR . Obviously we choose 1), which implies that P is broken in nature [11, 12].

279

Theory of neutrino masses and mixings

. 4 2. Left-Right symmetry and massive neutrinos. – What fields should we choose for the role of ϕL and ϕR ? From the neutrino mass point of view, the ideal candidates should be triplets, i.e. ΔL (¯ 3L , 1R , 2),

(29)

ΔR (¯1L , 3R , 2),

where the quantum numbers denote SU (2)L , SU (2)R and B-L transformation properties. Simply speaking, ΔL and ΔR are SU (2)L and SU (2)R triplets, respectively, with B-L numbers equal to two. Writing ΔL,R = ΔiL,R τi /2 (τi being the Pauli matrices) as is usual for the adjoint representations, we find Yukawa couplings LΔ = hΔ (TL C iτ2 ΔL L + L → R) + h.c.

(30)

To check the invariance of (30) under the Lorentz group and the gauge symmetry SU (2)L × SU (2)R × U (1)B-L , recall that T – ψL CψL is a Lorentz invariant quantity for a chiral Weyl spinor ψL (and similarly for ψR ).

– under the gauge symmetry SU (2)L (31)

L −→ UL L ,

ΔL −→ UL ΔL UL† ULT (iτ2 ) = (iτ2 )UL†

and similarly for SU (2)R – the B-L number of the ΔL,R fields is two. This proves the invariance of (30) under all the relevant symmetries. Now, from their definition, the fields ΔL,R have the following decomposition under the charge eigenstates: √ Δ+ / 2 = Δ0 

(32)

ΔL,R



Δ++√ −Δ+ / 2

, L,R

where we use the fact that Tr ΔL,R = 0 and the charge is computed from Q = I3L + I3R + (B-L)/2. Notice an interesting consequence of doubly charged physical Higgs scalars in this theory. From the general analysis of the spontaneous L-R symmetry breaking, we know that for a range of parameters of the potential the minimum of the theory can be chosen as 

(33)

ΔL  = 0,

0 ΔR  = vR

 0 . 0

280

´ G. Senjanovic

From (30), we the obtain the mass for the right-handed neutrino νR (34)

† T ∗ Lm = hΔ vR (νR C νR + νR C † νR ).

Thus the right-handed neutrino gets a large mass MR = hΔ vR , which corresponds to the scale of breaking of parity. At the same time, the original gauge symmetry is broken down to the Standard Model one (35)

ΔR 

SU (2)L × SU (2)R × U (1)B-L −→ SU (2)L × U (1)Y .

This can be checked by computing the gauge boson mass matrix. By defining the right-handed charged gauge boson (36)

WR± =

A1R ∓ iA2R √ , 2

we get (37)

2 2 2 MW = gR vR , R

(38)

2 2 MZ2 R = 2(g 2 + gB-L ) vR ,

where (39)

ZR =

gB-L A3R + gR AB-L  2 g 2 + gB-L

is the new massive neutral gauge field, and gR and gB-L gauge couplings correspond to SU (2)R and B-L 2 , respectively. Thus the scale of parity breaking is related to the mass of the right-handed charged gauge bosons WR± . The predominant V -A nature of the weak interactions puts a lower limit on MWR , but the limit depends on the details of the model. In general the left and right mixings between quarks (and leptons too) are not correlated and the MWR can be quite low. If the L and R mixings are the same (or approximately the same) as in some minimal versions of the theory, the best limit comes from the KL − KS mass difference (40)

MWR > 2 TeV.

To complete the theory, one needs a Higgs bidoublet which contains the SM Higgs, so that one can give masses to quarks and leptons. In the process we get the Dirac neutrino mass between νL and νR and in turn we end up with the type-I see-saw mechanism for light neutrino masses.

281

Theory of neutrino masses and mixings

Type-I see-saw. From the Dirac Yukawas (41)

L = hΦ L Φ R + h.c.,

after the symmetry breaking the neutrino Dirac mass term is mD = hΦ Φ. The neutrino mass terms become (42)

mD L R + MR TR CR + h.c.

and the neutrino mass matrix takes clearly the see-saw form. The important point here is that the mass of νR is determined by the scale of parity breaking and the smallness of the neutrino mass is a reflection of the predominant V -A structure of the weak interaction and provides a probe of parity restoration at high energies E > MWR . Type-II see-saw. The gauge symmetry of the Left-Right model allows also for the following term in the potential that we have ignored before for simplicity: (43)

ΔV = αΔ†L ΦΔR Φ† ,

which implies that ΔL  cannot vanish. Exercise: Show that (44)

ΔL  α

2 MW M2 ΔR 

α W , MΔ L MR

which leads to type-II see-saw. The predictions for neutrino mass depend crucially on MWR , but the L-R symmetric model by itself cannot give us its value. This is cured in SO(10) grand unified theory, where we will see that this scale is very large which fits perfectly with observed neutrino masses. . 4 3. Charge conjugation as L-R symmetry. – Since charge conjugation (see Appendix A) (45)

T (ψ C )L ≡ C ψ¯R

is also a transformation between left and right, one can as well use C as a L-R symmetry of this theory. In the limit of CP invariance, these symmetries are equivalent; the difference lies only in the tiny breaking of CP . The above discussion goes almost unchanged and we leave it as an exercise for a reader to go through. Exercise: Rewrite the above left-right symmetric theory, both gauge and Yukawa couplings with L-R symmetry as C instead of P .

282

´ G. Senjanovic

We will see that in SO(10) this symmetry introduced here ad hoc is an automatic finite gauge transformation. It would be natural to go directly to SO(10) now, but it will be helpful to master first the minimal grand unified theory based on SU (5) symmetry, the minimal gauge group that embed the SM symmetry. In order to be as pedagogical as possible, I have included Appendices C and D on SU (N ) and SO(2N ) groups, respectively. In particular, Appendix D deals with the spinorial representations of SO(2N ), a possibly new topic for most of the readers. There are a number of exercises that should help you know whether you have a mastery of the necessary group theory. 5. – SU (5): A prototype GUT The minimal group that can unify the Standard Model (SM) is SU (5), a group of rank four. It is actually the minimal group that can unify the SU (2)L and SU (3)c of the SM, the U (1) comes for free. It is natural that we should try to put the electro-weak doublet Φ and the new color triplet hα in the 5-dimensional fundamental representation ⎫ ⎛ r⎞ h ⎬ ⎜ hg ⎟ SU (3)c ⎜ b⎟ ⎭ ⎟ , (46) 5H = Φ = ⎜ h ⎜ ⎟ " ⎝φ+ ⎠ SU (2)L φ0 where in the obvious notation the SU (3)c symmetry is acting on the first 3 components and the SU (2)L on the last two. . 5 1. Structure. . 5 1.1. Fermions. We have 15 Weyl fields in each generation and it is natural to try to put them in a 15-dimensional symmetric representation of SU (5). Now (47)

5 ⊗ 5 = 15s + 10as

Since 5 = (3c , 1L ) + (1c , 2L ) (in an obvious notation), since (3c ⊗ 3c )s = 6c , and since quarks come only in color triplets, we must abandon the idea of 15S . It is not anomaly free anyway, it could not have worked. What about 5 and 10as ? The quantum numbers of 5 from (46) imply uniquely ⎛

(48)

(recall that (f C )R ≡ C f¯L ).

⎞ dr ⎜ dg ⎟ ⎜ b ⎟ ⎟ 5F ≡ ψ = ⎜ ⎜ d ⎟ ⎝ e+ ⎠ −ν C R

283

Theory of neutrino masses and mixings

Now, from ψ −→ U ψ under SU (5), the 10-dimensional representation χ must transform as χ −→ U χ U T .

(49)

This is enough to give the quantum numbers of the particles in 10 ⎡

(50)

0 ⎢−uC 1 ⎢ Cb χ= √ ⎢ ug 2⎢ ⎣ ur dr

uC b 0 −uC r ug dg

−uC g uC r 0 ub db

−ur −ug −ub 0 −e+

⎤ −dr −dg ⎥ ⎥ −db ⎥ ⎥ . + ⎦ e 0

L +

e Notice that in (48), a minus sign convention for the ν C field is to ensure that ( −ν C )R e and ( ν )L transform identically, and in (50) the signs are the property of χ being antisymmetric. We will work in the future with 10F and ¯5F (instead of 5F ). We can see furthermore that a unified theory such as SU (5) explains charge quantization, i.e. it relates quark and lepton charges. From (48)

(51)

1 1 Q(dC ) = − Q(e) = 3 3

and then from (50) we see that Q(u) = Q(d) + 1 = 2/3. . 5 1.2. Interactions. The interactions of fermions with gauge bosons are (52)

¯ μ Dμ ψ − i Tr χγ Lf = iψγ ¯ μ Dμ χ,

where (53)

Dμ χ = ∂μ χ − ig(Aμ χ + χATμ ).

There are of course the old QCD and SU (2)L × U (1) interactions with gs = gW = g, and sin2 θW = 3/8, the couplings at the unification scale where full SU (5) is operative. Furthermore, there are new X and Y bosons who carry both color and flavor with charges 4/3 and 1/3, respectively. Their interactions are (54)

 g ¯α  ¯ μ + μ + ¯ L(X, Y ) = √ X ¯cγ μ dαR γ eR + dαL γ eL + αβγ u L γμ uβL 2   g C + √ Y¯μα −d¯αR γ μ νR +u ¯αL γ μ e+ ¯cγ L γμ dβL + h.c. L + αβγ u 2

As expected, due to the nontrivial color and flavor characteristics of the quarks, the X and Y couple to the quark-quark and quark-lepton states. It is clear that B and L are violated, although for some magic reason B-L is conserved (more about it later). This

284

´ G. Senjanovic

leads to the decay of the proton. By analogy with the usual weak decay n → p + e + ν¯, μ → e + ν¯e + νμ the proton decay rate can be estimated as Γp

(55)

g4 5 4 mp . MX

From (τp )exp > 1033 y we get MX > 1015.5 GeV; later we will show that we can actually compute MX . . 5 2. Symmetry breaking. – The first stage of symmetry breaking down to the SM is achieved by the adjoint Higgs Σ = 24H . Assume, only for the sake of simplicity, the discrete symmetry Σ → −Σ. Then the most general renormalizable potential for Σ is given by (56)

V (Σ) = −

μ2 1 1 Tr Σ2 + a (Tr Σ2 )2 + b Tr Σ4 . 2 4 2

Now, since Σ is a Hermitian matrix, it can be diagonalized by an SU (5) rotation. Assume now that it is in the same direction as the hypercharge: Σ ∝ Y = vX diag(1, 1, 1, −3/2, −3/2). 2 From (56) you get then μ2 = 21 (15a+7b) vX , which, for μ2 > 0, implies (15a+7b) > 0. In order to check that this is a local minimum, we must show that all the second derivatives are positive. Since Σ has exactly the same form as the gauge boson matrix, we can write    ⎛ ⎞ ¯X ¯Y Σ Σ Σ8 + 35 − 32 1c Σ0 ⎜ ⎟   ⎜ ⎟ 1 (57) Σ = Σ + ⎜ ⎟, ΣX Σ3 + 35 Σ0 Σ+ 2 ⎝ ⎠   ΣY Σ− − 21 Σ3 + 35 Σ0 where Σ8 are the analogs of gluons, ΣX and ΣY the analogs of X and Y , Σ3 , Σ+ , Σ− and Σ0 the analogs of W 3 , W + , W − and B, respectively. The masses of the particle masses in Σ are (58)

5 2 bv , 4 X 2 m2 (Σ3 ) = m2 (Σ± ) = 5b vX , 15a + 7b 2 vX , m2 (Σ0 ) = 2 m2 (ΣX ) = m2 (ΣY ) = 0. m2 (Σ8 ) =

Thus for 15a + 7b > 0, b > 0 the extremum is a local minimum of the theory. Notice that ΣX and ΣY are would-be Goldstone bosons of the theory; they get “eaten” by the X and Y gauge fields, i.e. they become their longitudinal components.

285

Theory of neutrino masses and mixings

Finally, one can show that the vev of Σ is actually a global minimum. In fact, other extrema can be shown to be at best saddle points. Exercise: HARD. Prove that the above minimum is in fact global. Thus SU (5) can be successfully broken down to the standard model, since as we said Y commutes with both the SU (3)c and SU (2)L × U (1)Y generators. This will be even more evident from the study of the gauge bosons mass matrix. Since Σ is in the adjoint representation, Dμ Σ = ∂μ Σ − ig[Aμ , Σ], and one has (59)

1 25 2 2  ¯ a μ ¯ a μ  (Dμ Σ)† (Dμ Σ) = g vX Xμ Xa + Yμ Ya , 2 8

where a, as usual, is the color index, a = r, g, b. As expected, the gluons and the electro-weak gauge bosons remain massless, but X and Y get equal masses (60)

2 m2X = m2Y ≡ MX =

25 2 2 g vX , 8

as a consequence of both SU (3)c and SU (2)L remaining unbroken. The original SU (5) symmetry is broken down to SU (3)c × SU (2)L × U (1)Y . The rest of the breaking is completed by a 5-dimensional Higgs multiplet Φ5 which contains the Standard Model doublet. Let us study this in some detail including the full SU (5) invariant potential. We can write (61)

1 1 μ2Σ Tr Σ2 + a(Tr Σ2 )2 + b Tr Σ4 2 4 2 μ2Φ † λ † 2 − Φ Φ + (Φ Φ) 2 4 +αΦ† Φ Tr Σ2 − βΦ† Σ2 Φ,

V (Σ, Φ) = −

with a > 0, λ > 0, 15a + 7b > 0 and β > 0. Since both SU (3)c and SU (2)L are unbroken at this point, we can always rotate Φ into the form ΦT  = (vc , 0, 0, 0, vW ). It is only 2 2 the β term that is sensitive to the direction of Φ and it gives −βvX (vc2 +9/4vW ), which, for β > 0, forms the solution vW = 0, vc = 0 in order to minimize the energy. It is an easy exercise to compute the mass of the colored triplet scalar ha in Φ, it is 2 m2h = 52 βvX , which justifies the choice β > 0. It is also easy to show that (62)

2 = MW

  2 g2 8MX 9 μ2Φ + β) . (−15α + 4λ 25g 2 2

But MX > 1015 GeV, which implies an extraordinary fine tuning in the above equation of at least 26 orders of magnitude. The number on the right-hand side of (62) is naturally

286

´ G. Senjanovic

2 of order MX > 1030 GeV2 ; instead it ends up being (100 GeV)2 . This is known as the hierarchy problem. In the next subsection we will see that the colored triplet ha mediates proton decay and thus it must be very heavy: mh > 1012 GeV, implying that β cannot be taken arbitrarily small. On the other hand, its partner η weighs < 1 TeV, and this aspect of the hierarchy problem is known as the doublet-triplet splitting problem. Before we close this subsection, let us say a few words more on the hierarchy problem. The problem is that the mass term for the Higgs scalars cannot be made small (or zero) by any symmetry, unlike the case of fermions. There the limit mf = 0 corresponds to the chiral symmetry f → γ5 f , and thus the higher-order corrections must also vanish if mf = 0 at the tree level. In other words, the higher-order corrections are necessarily proportional to mf (tree), and so only logarithmically divergent. In the case of scalars the divergence is quadratic and thus in the context of grand unified theories (GUTs) such as SU (5) the natural value for MW is of order MX .

. 5 3. Yukawa couplings and fermion mass relations. – In the Standard Model the lefthanded fermions are doublets and the right-handed fermions are singlets, and so their chiral property is more than manifest. In SU (5) the V -A structure of a family of fermions is left-intact and here also there are no direct mass terms for fermions. In the minimal SU (5) theory the fermion masses originate through the Yukawa couplings of fermions with the light Higgs Φ (63)

1 LY = fd ψ¯R χ Φ† + fu χT C χ Φ + h.c., 2

where C is the Dirac conjugation matrix, and fu is clearly a symmetric matrix. The symbolic notation of (63) should read in the SU (5) notation as (64)

ψ¯R χ Φ† = ψ¯R i χij Φ†j , χT C χ Φ = ijklm (χT )ij C χkl Φm .

With ΦT = (0 0 0 0 vW ), we get for fermionic masses (65)

+ c T Lm = fd vW (d¯R dL + e¯+ R eL ) − fu vW (u )L C uL + h.c. ¯ + e¯e) − fu vW u = −[fd vW (dd ¯u].

In other words, just as in the Standard Model mf = hf vW , furthermore charged lepton and down-quark masses are equal. Exercise: Explain why this happens. Unfortunately, this works bad even for the third family, since at MX one finds mb = 0.6mτ . This means that one must include higher-dimensional operators in the Yukawa

287

Theory of neutrino masses and mixings

sector, up to now neglected. Alternatively, you can include other Higgs representations that can contribute to the fermionic masses; for example, you can add 45H . Now, besides the usual Yukawa structure of the Higgs doublet in the SM, one has new interactions of the color triplet hα . From (63) and (64) it is easy to compute its couplings to fermions T ij kl α Lh = fd ψ¯R i χi α h+ α + fu ijklα (χ ) Cχ h ,

(66) which gives (67)

  αβγ c @ α ?  + + ¯α c h . Lh = fd αβγ u ¯cL β dγR + u ¯α u ¯R β dγL + u ¯α L eR + dL νR + fu  R eL

Notice that the structure of the above couplings (not the strength, though) is dictated by the SU (3)C × SU (2)L × U (1)Y gauge invariance only. This becomes clearer if we write u¯cL dR = uTR CdR and u¯cR dL = uTL CdL . It is clear that the interactions of H break B and L, just like those of X and Y . Notice, though, that B-L is again conserved. In complete analogy with the situation encountered before for the X and Y bosons, we have the possible exchanges of hα which leads to the proton decay. Of course, the amplitude is proportional to small Yukawa couplings and the corresponding limit on its mass is somewhat less strict: mh ≥ 1012 GeV. . 5 3.1. Generations and their mixings. We know that in the standard model the neutral current interactions are flavor diagonal and that the charged current processes lead to flavor mixing and CP violation. How is this feature incorporated in the SU (5) theory and what about new superweak interactions of the X and Y bosons? The analysis is straightforward and it proceeds along the same lines as in the SU (2)L ×U (1)Y theory [5]. I should stress that the predictions we will obtain are of course not realistic since in this minimal theory neutrinos are massless and the down quark and charged lepton mass relations come out wrong. The minimal model discussed here should be viewed only as a prototype of the what predictive theory should be like. We diagonalize as usual fermion mass matrices by bi-unitary transformations (68)

† ULf Mf URf = Df ,

where Df is diagonal, with its elements being real, positive numbers. Furthermore, since Mu is symmetric (69)

∗ URu = ULu K ∗,

where

(70)

⎛ iφu e ⎜ K=⎜ ⎝

⎞ eiφe iφt

e

⎟ ⎟ ⎠ ...

288

´ G. Senjanovic

is the matrix of phases needed to ensure that the elements of Du are real and positive. The above statements are equivalent to the redefinition of our original fermionic fields in the Lagrangian † fL,R → UL,R fL,R ,

(71) +

d e with UL,R = UL,R . Since, on the other hand, the neutrinos are massless, we can rotate c d c them any way we wish and so we chose νR → UR νR . Thus we can write for the 5d d dimensional representation ψR → UR ψR , which means that UR disappears since it is just an overall factor. Suppressing the color index, we can write

⎡

ULu Kuc

(72)

χ→⎣

−ULu u

−ULd d

⎡

−ULd e+ UCKM Kuc

= ULd ⎣

−UCKM u

⎤ ⎦ L

−d −e

⎤ ⎦ ,

+ L

† where UCKM = ULd ULu . Again ULd is just an overall factor and so it will disappear. We are left with the Cabibbo-Kobayashi-Maskawa unitary matrix and the phase matrix K only. Thus the leptonic interactions are flavor conserving (since neutrinos are massless), and the weak quark interactions involve UCKM only, as it must be. Finally, the X and Y boson interactions involve no new flavor mixings besides UCKM , however there will be new phases hidden in K. In the physical basis we get

(73)

 g ¯ ¯ μ + ¯ μ + L(X, Y ) = √ X ¯cL γ μ K ∗ uL μ dR γ eR + dL γ eL + u 2  g † † c + √ Y¯μ −d¯R γ μ νR +u ¯L γ μ UCKM e+ ¯cL γ μ UCKM dL + h.c. L +u 2

From U11 ∝ cos θc , U12 ∝ sin θc we would expect (74)

Γ(p → π 0 μ+ ) ∝ sin2 θc . Γ(p → π 0 e+ )

Of course, this minimal SU (5) model is not realistic, for down and strange quark masses are not equal to their leptonic counterparts at the unification scale. It is only an illustration how proton decay partial rates are connected to the fermion masses and mixings. The true test can only be possible in a completely realistic theory of fermion masses and mixings (for a review and references, see [6]). In any case, the minimal SU (5) theory fails to explain neutrino masses; it is custom fit for massless neutrinos. While nonminimal models can lead to nonvanishing neutrino masses, by itself, SU (5) just like the standard model cannot relate neutrino masses to

Theory of neutrino masses and mixings

289

charged fermion masses nor relate quark and lepton mixing angles. This is treated beautifully in the SO(10) theory which requires the existence of right-handed neutrinos and leads to small, nonvanishing neutrino masses through the see-saw mechanism. The main ingredients are the left-right and quark-lepton symmetry inbuilt in SO(10) automatically. However, SU (5) offers an interesting possibility of neutrino Yukawa couplings of being probed at LHC and before moving to SO(10) in sect. 6 we will discuss a simple and predictive SU (5) theory with an adjoint fermionic representation added to the minimal model discussed above. We will show that the theory is completely realistic and testable at colliders. . 5 4. Low-energy predictions. . 5 4.1. Ordinary SU (5). As is well known, the couplings run logarithmically with energy. We have (75)

1 1 1 MX = bG ln − αG (MW ) αU 2π MW

for the gauge group G; MX is the energy where we imagine the unification to take place, and αU is the value of the unified coupling at MX . One has a generic formula for the running coefficient (76)

bG =

2 1 11 TGB − TF − TH , 3 3 3

where the Casimir TR for the representation R is defined by TR δij = Tr Ti Tj

(77)

and Ti are the Hermitian traceless generators of the group in question. For the fundamental representation of SU (N ) the convention is the one of SU (2): Tfund = 12 , which implies for the adjoint representation (relevant for gauge bosons) in SU (N ): Ta dj = TGB = N . This gives for the SU (3)C , SU (2)L and U (1), respectively (78)

33 4 − ng , 3 3 22 4 1 − ng − nH , b2 = 3 3 6 3 4 1 b1 = bY = − ng − nH , 5 3 10 b3 =

where Ng is the number of generations, nH is the number of Higgs doublets (nH = 1 in the minimal standard model). We are now fully armed to check the evolution of these couplings above MW . From above (79)

1 1 b j − bi MX − = ln . αi (MW ) αj (MW ) 2π MW

290

´ G. Senjanovic

In the above we have used α1 (MX ) = α2 (MX ) = α3 (MX ) = αU . sin2 θW α2 = cos2 θW αY and αY = 3/5α1 , we get easily (80)

From αem =

1 22 + nH MX 1 − = ln , α2 (MW ) α3 (MW ) 12π MW 3 110 − nH MX αem (MW ) ln . sin2 θW (MW ) = − 8 48π MW

Notice the prediction sin2 θW = 38 at MX which we discussed before. Now, for nH = 1 1 and by taking a α3 (MW ) 0.12, α2 (MW ) 30 , we find MX 1016 GeV, but sin2 θW (MW ) 0.2.

(81)

The minimal SU (5) theory thus fails to meet the experiment. . 5 4.2. Supersymmetric SU (5). Supersymmetry, i.e. symmetry between bosons and fermions, guarantees the cancellation of quadratic divergences for the Higgs mass and thus can make MW insensitive to MX . That is, we do not know why MW /MX is small, but it is not a problem, since it will stay small in perturbation theory as long as the scale of supersymmetry breaking is small, ΛSS MW . The point is that the Higgs mass term is invariant under the internal symmetries and thus is normally not protected from high scales as manifested by quadratic divergences. The fermion masses, on the other hand, are protected by chiral symmetry and thus insensitive to large scales as manifested by “small” logarithmic divergences. In supersymmetry scalars and fermions are not distinguishable and thus Higgs mass is under control too. Then for every particle of the standard model there is a supersymmetric partner of the opposite statistics: fermions (quarks, leptons) s = 1/2

⇐⇒

sfermions (squarks, sleptons) s=0

gauge bosons (W ± , Z, γ, gluons) s=1

⇐⇒

gauginos (Wino, Zino, photino, gluinos) s = 1/2

Higgs scalar s=0

⇐⇒

Higgsino s = 1/2

It is easy to see that the formulas for the running of the gauge couplings will be affected by the presence of the new particles. From (76) we get  (82)

bSS G

=

11 2 − 3 3



 TGB −

2 1 + 3 3



 TF −

1 2 + 3 3

 TH ,

291

Theory of neutrino masses and mixings

or (83)

bG = 3TGB − TF − TH ,

where the added contributions in (82) are due to the superpartners. From (83) we get for the individual gauge couplings (84)

bSS 3 = 9 − 2ng , 1 bSS 2 = 6 − 2ng − nH , 2 3 nH , bSS 1 = −2ng − 10

where nH is again the number of Higgs doublets. In exactly the same way as before, assuming the unification of couplings at MX , we find (85)

1 6 + nH MX 1 − = ln , α2 (MW ) α3 (MW ) 4π MW 3 30 − nH MX αem (MW ) ln . sin2 θW (MW ) = − 8 16π MW

In the minimal supersymmetric standard model (MSSM) nH = 2, and we find (86)

MX 1016 GeV

and (87)

sin2 θW (MW ) =

7 αem (MW ) 1 +

0.23. 5 15 α3 (MW )

MSSM agrees perfectly well with the experiment and with the above value for MX we predict the proton lifetime (88)

τp 1036 y

which is above the experimental bound (89)

(τp )exp ≥ 6 · 1033 y.

Now, if we are to take supersymmetry seriously, all the way up to the scale MX , we expect ˜ Y˜ , associated with the superheavy bosons X and Y of SU (5); of course new gauginos X, ˜ α from 5 of SU (5). The exchange of the heavy Higgsinos and also heavy Higgsinos h

292

´ G. Senjanovic

leads to proton decay, suppressed only linearly by the GUT scale. More precisely, the exchange of heavy Higgsinos gives the effective operator of the type (90)

1 ˜ Q, ˜ QLQ MX

˜ stands for squarks. In turn the where Q and L stand for quarks and leptons and Q squarks are changed into quarks through the exchange of gauginos and one obtains an operator of the form QQQL of the proton decay. While it depends on the Yukawa sector and the sfermion masses and mixings, and thus not easy to predict precisely, proton lifetime is typically very close (or below) the experimental limit. . 5 5. SU (5) and neutrino mass. – The minimal theory of Georgi and Glashow fails in two crucial ways: a) it predicts massless neutrinos, b) gauge couplings do not unify. We need a minimal extension that cures both problems. It does not suffice to add right-handed neutrinos for they are gauge singlets and do not contribute to the running of gauge couplings and thus cannot help the unification. In other words, type-I see-saw fails in minimal SU (5). One could try type II, which requires a 15-dimensional Higgs representation, but instead I wish to discuss here a particularly simple and predictive theory [13], since it only requires adding the adjoint fermions 24F to the existing minimal model with three generations of quarks and leptons, and 24H and 5H Higgs fields. This automatically leads to the hybrid scenario of both type-I and type-III see-saw, since 24F has also a SM singlet fermion, i.e. the right-handed neutrino. This should be clear to the alert student. After all, the 24F is completely analogous to the 24H or even better the adjoint gauge boson representation, which we studied at length. The fermionic triplet simply corresponds to the SU (2) gauge boson triplet, whereas the singlet corresponds to the U (1) gauge boson. This singlet can be interpreted as a right-handed neutrino, for it is a SM neutral particle with Yukawa couplings to the light neutrinos. The triplet fermion on the other hand has the quantum numbers of the winos, the supersymmetric partners of the SU (2) charged and neutral gauge bosons. The main prediction of this theory is the lightness of the fermionic triplet. For a conventional value of MGU T ≈ 1016 GeV, the unification constraints strongly suggest its mass below TeV, relevant for the future colliders such as LHC. The triplet fermion decays predominantly into W (or Z) and leptons, with lifetimes shorter that about 10−12 s. Equally important, the decays of the triplet are dictated by the same Yukawa couplings that lead to neutrino masses and thus one has an example of predicted low-energy see-saw directly testable at colliders and likely already at LHC. The minimal implementation of the type-III see-saw in nonsupersymmetric SU (5) requires a fermionic adjoint 24F in addition to the usual field content 24H , 5H and three generations of fermionic 10F and 5F . The consistency of the charged fermion masses requires higher-dimensional operators in the usual Yukawa sector [14]. One must add

Theory of neutrino masses and mixings

293

the new Yukawa interactions (91)

5iF 24F 5H LY ν = y0i ¯  1 ¯i  i i i + 5 F y1 24F 24H + y2 24H 24F + y3 Tr (24F 24H ) 5H + h.c. Λ

After the SU (5) breaking, one obtains the following physical relevant Yukawa interactions for neutrino with the triplet TF ≡ TF · σ and singlet SF fermions (together with mass terms for TF and SF : (92)

  mS mT S F SF + TF TF + h.c., LY ν = Li yTi TF + ySi SF H + 2 2

where yTi , ySi are two different linear combinations of y0i and yai vGU T /Λ (a = 1, 2, 3), Li are the lepton doublets and H is the Higgs doublet. It is clear from the above formula that, besides the new appearance of the triplet fermion, the singlet fermion in 24F acts precisely as the right-handed neutrino; it should not come out as a surprise, as it has the right SM quantum numbers. After the SU (2) × U (1) symmetry breaking (H = v ≈ 174 GeV), one obtains in the usual manner the light neutrino mass matrix upon integrating out SF and TF   ySi ySj yTi yTj ij 2 , + (93) mν = v mT mS with mT ≤ 1 TeV (see below) and mS undetermined. From the above formula, one important prediction emerges immediately: only two light neutrinos get mass, while the third one remains massless. This is understood readily. First, the Yukawas here are vectors, and for example the vector coupling corresponding to the triplet can be rotated in the, say, 3rd direction. Thus only one light neutrino effectively coupled to the triplet, i.e. only one neutrino gets the mass through this coupling. Obviously, the same could have been said about the singlet and thus only two massive light neutrinos. This is of course independent of the nature of the heavy states, and the number of light massive neutrinos is in direct proportion to the number of heavy fermions, be they singlets or triplets. The mass of the fermionic triplet is found by performing the renormalization group analysis as before. From [13] one has (94)

(95)

    exp 30π α1−1 − α2−1 (MZ ) = 20  84   F 4 B 5    m 3 m3 MGU T MGU T MGU T , MZ MZ5 mT mF (3,2)     exp 20π α1−1 − α3−1 (MZ ) = 20  86   F 4 B 5  −1  m 8 m8 MGU T MGU T MGU T , MZ MZ5 mT mF (3,2)

294

´ G. Senjanovic

where mF,B , mF,B , mF 3 8 (3,2) and mT are the masses of weak triplets, color octets (only fermionic) leptoquarks and (only bosonic) color triplets, respectively. We discussed at length the well-known problem in the standard model of the low meeting scale of α1 and α2 . It is clear that the SU (2) triplet fermions are ideal from this point of view since they slow down the running of α2 , while leaving α1 intact (other particles have nonvanishing hypercharge and thus make α1 grow faster as to meet α2 even before). They should clearly be as light as possible while the color triplet as heavy B as possible. In order to illustrate the point, take mF 3 = m3 = MZ and mT = MGU T . −1 −1 −1 This gives (α1 (MZ ) = 59, α2 (MZ ) = 29.57, α3 (MZ ) = 8.55) MGU T ≈ 1015.5 GeV. Increasing the triplet masses mF,B reduces MGU T dangerously, making proton decay 3 too fast. Finally, one can ask, where must the octets be. Since the triplets slowed down the running of α2 , the meting point of α2 and α3 would become too large, unless α3 gets slowed down too. Thus the octets must lie much below MGU T , but since they contribute to the running more than the triplets, they should be also much above the weak scale, and one gets m8 = 107 –108 GeV For a more detailed discussion of unification constraints and especially the phenomenology of the triplet relevant for LHC, see [15]. The bottom line is a prediction of the light weak fermion triplet (96)

mT < TeV.

Its decays proceed via its Yukawa couplings yT and thus probe the neutrino mass. One can parametrize yT through the lepton mixing matrix. In normal hierarchy (NH) i.e. mν1 = 0,     √ vyTi∗ = i mT Ui2 mν2 cos z ± Ui3 mν3 sin z ,

(97)

while in inverted hierarchy (IH) i.e. mν3 = 0,     √ vyTi∗ = i mT Ui1 mν1 cos z ± Ui2 mν2 sin z ,

(98)

where, z is a complex parameter. You can readily show that in NH the neutrino masses are (99)

mν1 = 0,

mν2 =

 Δm2S ,

mν3 =

 Δm2A + Δm2S ,

while in the IH case (100)

mν1 =



Δm2A − Δm2S ,

mν2 =

 Δm2A ,

mν3 = 0.

295

Theory of neutrino masses and mixings

The predominant decay modes of the triplets [15] are T → W (Z)+ light lepton whose strength is dictated by the neutral Dirac Yukawa couplings. (101) (102)

 2   m2Z m2Z mT  k 2 Γ(T → y 1− 2 1+2 2 , = 32π T m mT   T    2  m2W m2W mT   k 2 − − 1− 2 1+2 2 , yT Γ(T → W νk ) = 16π mT mT −

Ze− k)

k

(103)

(104)

k

0 − + Γ(T 0 → W + e− k ) = Γ(T → W ek )  2   m2W m2W mT  k 2 y 1− 2 1+2 2 , = 32π T m mT   T 2   2    k 2 m2Z mZ mT 0   1+2 2 , 1− 2 yT Γ(T → Zνk ) = 32π mT mT k

k

where we averaged over initial polarizations and summed over final ones. From (103) one sees that the decays of T 0 , just as those of right-handed neutrinos, violate lepton number. In a machine such as LHC one would typically produce a pair T + T 0 (or T − T 0 ), whose decays then allow for interesting ΔL = 2 signatures of same-sign dileptons and 4 jets. This fairly SM background-free signature is characteristic of any theory with right-handed neutrinos as discussed in [36]. The main point here is that these triplets are really predicted to be light, unlike in the case of right-handed neutrinos. We discuss this further in sect. 7 on lepton number violation. 6. – SO(10): family unified The minimal gauge group that unifies the gauge interactions of the standard model was seen in the previous subsection to be based on SU (5) and studied at length. It is tailor fit for massless neutrinos just as the SM, for in the minimal version of the theory neutrinos get neither Dirac nor Majorana mass terms. Furthermore, the ordinary, nonsupersymmetric theory fails to unify gauge couplings. We found that the simple extension with the adjoint fermion representation provides a minimal and remarkably predictive theory with light fermionic triplet expected at LHC and whose decay rates probe the Dirac Yukawa couplings of neutrinos. We have a theory that works and furthermore gives serious hope for an old dream of verifying see-saw mechanism at colliders. So why should one ever wish to go beyond SU (5)? We can think of at least two reasons. First, if one is to worry about the Higgs mass naturalness, one may wish to include supersymmetry. While SU (5) with the low-energy supersymmetry has a rather appealing feature of providing automatically (as predicted many years ago) a gauge coupling unification, it is not an interesting theory of fermion masses and mixings. First of all, it offers no explanation for the smallness of R-parity violation in nature, and at the same time it requires a certain amount of arbitrary and unpredicted R-parity violation in order to provide neutrino masses. One can also include the type-II see-saw into the theory through the

296

´ G. Senjanovic

15H supermultiplet, and even attribute to it a mediation of supersymmetry breaking, but one ends up without any direct low-energy probes or interesting quark-lepton mass and mixings relations. This is where SO(10) fits ideally, for it also unifies matter besides the interactions. It works nicely without supersymmetry too, for it provides a natural unification of gauge couplings through the intermediate scale of L-R symmetry breaking. The general case SO(2N ) is presented in Appendix D. The one important representation of SO(10) is a 16-dimensional spinor, which can be decomposed under SU (5) as 16 = 10+ ¯ 5+1. It unifies a family of fermions with an addition of a right-handed neutrino per family. This minimal grand unified theory that unifies matter on top of interactions suggests naturally small neutrino masses through the see-saw mechanism. Furthermore, it relates neutrino masses and mixings to the ones of charged fermions, and is predictive in its minimal version. In this section I discuss some salient features in this theory while focusing on its minimal realizations. The crucial representation is a self-dual five-index anti-symmetric one responsible for right-handed neutrino masses and is a must, whether being elementary or composed at the loop level or through the higher-dimensional operators. A number of different minimal realizations of SO(10) depends on this construction, and what follows summarizes a few of them. There are a number of features that make SO(10) special: 1) A family of fermions is unified in a 16-dimensional spinorial representation; this in turn predicts the existence of right-handed neutrinos. 2) L-R symmetry is a finite gauge transformation in the form of charge conjugation. This is a consequence of both left-handed fermions fL and its charged-conjugated T counterparts (f c )L ≡ Cf R residing in the same representation 16F . 3) In the supersymmetric version, matter parity M = (−1)3(B-L) , equivalent to the R-parity R = M (−1)2S , is a gauge transformation [16], a part of the center Z4 of SO(10). It simply reads 16 → −16, 10 → 10. Its fate depends then on the pattern of symmetry breaking (or the choice of Higgs fields); it turns out that in the renormalizable version of the theory R-parity remains exact at all energies [17, 18]. The lightest supersymmetric partner (LSP) is then stable and is a natural candidate for the dark matter of the universe. 4) Its other maximal subgroup, besides SU (5) × U (1), is SO(4) × SO(6) = SU (2)L × SU (2)R × SU (4)c symmetry of Pati and Salam. It explains immediately the somewhat mysterious relations md = me (or md = 1/3me ) of SU (5). 5) The unification of gauge couplings can be achieved with or without supersymmetry. 6) The minimal renormalizable version (with no higher-dimensional 1/MP l terms) offers a simple and deep connection between b−τ unification and a large atmospheric mixing angle in the context of the type-II see-saw [19]. In order to understand some of these results, and in order to address the issue of construction of the theory, we turn now to the Yukawa sector.

297

Theory of neutrino masses and mixings

. 6 1. Yukawa sector . – Fermions belong to the spinor representation 16F [4]. From 16 × 16 = 10 + 120 + 126,

(105)

the most general Yukawa sector in general contains 10H , 120H and 126H , respectively the fundamental vector representation, the three-index antisymmetric representation and the five-index antisymmetric and anti-self-dual representation. This can be seen by analogy with the Yukawa couplings of SO(6) (see Appendix D), Ly = y10 ΨT BΓi ΨΦi + y120 ΨT BΓi Γj Γk ΨΦ[ijk]

(106)

+y126 ΨT BΓi Γj Γk Γl Γm ΨΦ− [ijklm] . 126H is necessarily complex, supersymmetric or not; 10H and 126H Yukawa matrices are symmetric in generation space, while the 120H one is antisymmetric. Understanding fermion masses is easier in the Pati-Salam language of one of the two maximal subgroups of SO(10), GP S = SU (4)c × SU (2)L × SU (2)R (the other being SU (5) × U (1)). Let us decompose the relevant representations under GP S 16 = (4, 2, 1) + (¯ 4, 1, 2),

(107)

10 = (1, 2, 2) + (6, 1, 1), 120 = (1, 2, 2) + (6, 3, 1) + (6, 1, 3) + (15, 2, 2) + (10, 1, 1) + (10, 1, 1), 126 = (10, 3, 1) + (10, 1, 3) + (15, 2, 2) + (6, 1, 1). I illustrate the decomposition of a spinor representation 16 = Ψ+ (see Appendix D) (108)

Ψ+ ≡ |1 . . . 5 ;

1 . . . 5 = +1.

It contains (109)

1 2 3 = +1;

4 5 = +1

1 2 3 = −1;

4 5 = −1.

and (110)

The first one is 4 of SU (4)C , doublet of SU (2)L and the latter ¯4 of 4 of SU (4)C , doublet of SU (2)R , as can be read off readily from the sections on SO(4) and SO(6) of Appendix D. Exercise: Try to arrive at the rest of the above decomposition using the material in Appendix D. Clearly, the see-saw mechanism, whether type I or II, requires 126: it contains both (10, 1, 3) whose vev gives a mass to νR (type I), and (10, 3, 1), which contains a color

298

´ G. Senjanovic

singlet, B-L = 2 field ΔL , that can give directly a small mass to νL (type II). A reader familiar with the SU (5) language sees this immediately from the decomposition under this group (111)

126 = 1 + 5 + 15 + 45 + 50.

The 1 of SU (5) belongs to the (10, 1, 3) of GP S and gives a mass for νR , while 15 corresponds to the (10, 3, 1) and gives the direct mass to νL . Of course, 126H can be a fundamental field, or a composite of two 16H fields, or can even be induced as a two-loop effective representation built out of a 10H and two gauge 45-dimensional representations. In what follows I shall discuss carefully all three possibilities. Normally the light Higgs is chosen to be the smallest one, 10H . Since 10H  = (1, 2, 2)P S is a SU (4)c singlet, md = me follows immediately, independently of the number of 10H you wish to have. Thus we must add either 120H or 126H or both in order to correct the bad mass relations. Both of these fields contain (15, 2, 2)P S , and its vev gives the relation me = −3md . As 126H is needed anyway for the see-saw, it is natural to take this first. The crucial point here is that in general (1, 2, 2) and (15, 2, 2) mix through (10, 1, 3) [20] and thus the light Higgs is a mixture if the two. In other words, (15, 2, 2) in 126H is in general nonvanishing(1 ). It is rather appealing that 10H and 126H may be sufficient for all the fermion masses, with only two sets of symmetric Yukawa coupling matrices. . 6 2. An instructive failure. – Before proceeding, let me emphasize the crucial point of the necessity of 120H or 126H in the charged fermion sector on an instructive failure: a simple and beautiful model by Witten [21]. The model is nonsupersymmetric and the SUSY lovers may place the blame for the failure here. It uses 16H  in order to break B-L, and the “light” Higgs is 10H . Witten noticed an ingenious and simple way of generating an effective mass for the right-handed neutrino, through a two-loop effect which gives (112)

MνR yup

 α 2 π

MGU T ,

where one takes all the large mass scales, together with 16H , of the order MGU T . Since 10H  = (1, 2, 2)P S  preserves quark-lepton symmetry, it is easy to see that (113)

Mν ∝ Mu , Me = Md , Mu ∝ Md ,

(1 ) In supersymmetry this is not automatic, but depends on the Higgs superfields needed to break SO(10) at MGU T .

299

Theory of neutrino masses and mixings

so that Vlepton = Vquark = 1. The model fails badly. The original motivation of Witten was a desire to know the scale of MνR and increase Mν , at that time neutrino masses were expected to be larger. But the real achievement of this simple, elegant, minimal SO(10) theory is the predictivity of the structure of MνR and thus Mν . It is an example of a good, albeit wrong theory: it fails because it predicts. What is the moral behind the failure? Not easy to answer. The main problem, in my opinion, was to ignore the fact that with only 10H already charged fermion masses fail. One needs to enlarge the Higgs sector, by adding for example a 120H ; the theory still leads to interesting predictions while possible completely realistic. . 6 3. Non-supersymmetric SO(10). – In the last two decades, and especially after its success with gauge coupling unification, grand unification by and large got tied up with low-energy supersymmetry. This is certainly well motivated, since supersymmetry is the only mechanism in field theory which controls the gauge hierarchy. In SO(10), gauge coupling unification needs no supersymmetry whatsoever. It only says that there must be intermediate scales [22], such as Pati-Salam SU (4)c × SU (2)L × SU (2)R or Left-Right SU (3)c × SU (2)L × SU (2)R × U (1)B-L symmetry, between MW and MGU T . An oasis or two in the desert is always welcome. Thus if we accept the fine-tuning, as we seem to be forced in the case of the cosmological constant, we can as well study the ordinary, nonsupersymmetric version of the theory. In this context the idea of the cosmic attractors [23] as the solution to the gauge hierarchy becomes extremely appealing. It needs no supersymmetry whatsoever, and enhances the motivation for ordinary grand unified theories. In what follows I discuss some essential features of a possible minimal such theory with 126H as a necessary ingredient for see-saw. Let us start by analyzing the case with an extra 10H field [35]. The most general Yukawa interaction is (114)

  LY = 16F 10H Y10 + 126H Y126 16F + h.c.,

where Y10 and Y126 are symmetric matrices in the generation space. With this one obtains relations for the Dirac fermion masses (115)

M D = M1 + M0 , ME = −3M1 + M0 ,

MU = c1 M1 + c0 M0 , MνD = −3c1 M1 + c0 M0 ,

where we have defined (116)

M1 = 2, 2, 15d126 Y126 ,

M0 = 2, 2, 1d10 Y10

and (117)

c0 =

2, 2, 1u10 , 2, 2, 1d10

c1 =

2, 2, 15u126 . 2, 2, 15d126

300

´ G. Senjanovic

In the physically sensible approximation θq = Vcb = 0, these relations imply c0 =

(118)

mc (mτ − mb ) − mt (mμ − ms ) mt ≈ . ms mτ − m μ mb mb

Exercise: Derive this formula. Notice that this means that 10H cannot be real, since in that case one would have |2, 2, 1u10 | = |2, 2, 1d10 |, implying mt /mb of order one. It is necessary to complexify 10H , just as in a supersymmetric theory. If, taking advantage of this fact one decides to impose a Peccei-Quinn symmetry, thus providing a dark matter candidate, the Yukawa sector in nonsupersymmetric and supersymmetric models is similar. In this case, this model has the interesting feature of automatic connection between b − τ unification and large atmospheric mixing angle in the type-II see-saw. From MνL ∝ Y126 , one has MνL ∝ MD − ME , as shown in [19, 24]. This fact has inspired the careful study of the analogous supersymmetric version where mτ mb at the GUT scale works rather well [29]. In the nonsupersymmetric theory, b − τ unification fails badly, mτ ∼ 2mb [30]. The realistic theory will require a type-I see-saw, or an admixture of both possibilities. Suppose now that we choose instead 120H [35]. Since Y120 is antisymmetric, this means only 3 new complex couplings on top of Y126 . On gets in this case (119)

MD = M1 + M2 ,

MU = c1 M1 + c2 M2 ,

ME = −3M1 + c3 M2 ,

MνD = −3c1 M1 + c4 M2 ,

where M1 and c1 are defined in (116), (117), and (120)

  M2 = Y120 2, 2, 1d120 + 2, 2, 15d120 ,

c2 =

2, 2, 1u120 + 2, 2, 15u120 , 2, 2, 1d120 + 2, 2, 15d120

2, 2, 1d120 − 32, 2, 15d120 , 2, 2, 1d120 + 2, 2, 15d120

c4 =

2, 2, 1u120 − 32, 2, 15u120 . 2, 2, 1d120 + 2, 2, 15d120

c3 =

It is easy to see that again there is a need to complexify the Higgs fields, by arguments similar to the case of 10H . In order to obtain algebraic expressions, from which a clearer physical meaning can be extracted, one can restrict the analysis to the second and third generations. Later, numerical studies could include the effects of the first generation as a perturbation. In the basis where M1 is diagonal, real and non-negative, for the two-generation case one gets  (121)

M1 ∝

sin2 θ 0

0 cos2 θ



301

Theory of neutrino masses and mixings

and the most general charged fermion matrix can be written as  Mf = μf

(122)

 sin2 θ i(sin θ cos θ + f ) , −i(sin θ cos θ + f ) cos2 θ

where f = D, U, E stands for charged fermions and f vanishes for negligible second-generation masses. In other words |f | ∝ mf2 /mf3 . Furthermore the real parameter μf sets the third generation mass scale. By calculating up to leading order in |f |, we have the following interesting predictions [35]: 1) Type-I and type-II see-saw lead to the same structure I II ∝ MN ∝ M1 , MN

(123)

so that in the selected basis the neutrino mass matrix is diagonal. We see that the angle θ has to be identified with the leptonic (atmospheric) mixing angle θA up to terms of the order of |E | ≈ mμ /mτ . For the neutrino masses we obtain from (121) (124)

cos 2θA m23 − m22 + O(||). = 2 2 m3 + m 2 1 − sin2 2θA /2

Exercise: Derive this formula. This equation points to an intriguing correlation: the degeneracy of neutrino masses is measured by the maximality of the atmospheric mixing angle. 2) The ratio of tau and bottom mass at the GUT scale is given by mτ = 3 + O(||). mb

(125)

This is not correct in principle, the extrapolation in standard model gives mτ ≈ 2mb . However, several effects modify this conclusion, such as, for example, the inclusion of the first generation or the running of Yukawa couplings. We would in any case expect that mb comes out as small as possible. 3) The quark mixing is found to be (126)

|Vcb | = | cos 2θA (D − U )| + O(|2 |).

This equation demonstrates the successful coexistence of small and large mixing angles. In order for it to work quantitatively, | cos 2θA | should be as large as possible, i.e. θA should be as far as possible from the maximal value 45◦ . To make a definite numerical statement, again, the effects from the first generation and the loops have to be included.

302

´ G. Senjanovic

. 6 4. Supersymmetric case. – In supersymmetry 10H is necessarily complex and the bidoublet (1, 2, 2) in 10H contains the two Higgs doublets of the MSSM, with the vevs v u and v d in general different: tan β ≡ v u /v d = 1 in general. In order to study the physics of SO(10), we need to know what the theory is, i.e. its Higgs content. There are two orthogonal approaches to the issue, as we discuss now. Small representations. The idea: take the smallest Higgs fields (least number of fields, not of representations) that can break SO(10) down to the MSSM and give realistic fermion masses and mixings. The following fields are both necessary and sufficient (127)

45H , 16H + 16H , 10H .

It all looks simple and easy to deal with, but the superpotential becomes extremely complicated. First, at the renormalizable level it is too simple. The pure Higgs and the Yukawa superpotential at the renormalizable level take the form (128)

WH = m45 452H + m16 16H 16H + λ1 16H Γ2 16H 45H +m10 102H + λ2 16H Γ16F 10H + λ3 16H Γ16H 10H ,

(129)

Wy = y10 16F Γ16F 10H ,

where Γ stands for the Clifford algebra matrices of SO(10), Γ1 . . . Γ10 , and the products of Γ’s are written in a symbolic notation (both internal and Lorentz charge conjugation are omitted). Clearly, both WH and Wy are insufficient. The fermion mass matrices would be completely unrealistic and the vevs 45H , 6H , 16H  would all point in the SU (5) direction. Thus, one adds non-renormalizable operators (130) ΔWH =

(131) ΔWy =

1  2 2 (45H ) + 454H + (16H 16H )2 + (16H Γ2 16H )2 + (16H Γ4 16H )2 MP l +(16H Γ16H )2 + (16H Γ5 16H )2 + {16H → 16H }  +16H Γ4 16H 452H + 16H Γ3 16H 45H 10H + {16H → 16H } , 1  16F Γ16F 16H Γ16H + {16H → 16H } MP l  +16F Γ3 16F 45H 10H + 16F Γ5 16F 16H Γ5 16H ,

where I take for simplicity all the couplings to be unity; there are simply too many of them. The large number of Yukawa couplings means very little predictivity. The way out is to add flavor symmetries and to play the texture game and thus reduce the number of couplings. This in a sense goes beyond grand unification and appeals to new physics at MP l and/or new symmetries. To me, maybe the least appealing aspect of this approach is the loss of R (matter) parity due to 16H and 16H ; it must be postulated by hand as much as in the MSSM.

Theory of neutrino masses and mixings

303

On the positive side, it is an asymptotically free theory and one can work in the perturbative regime all the way up to MP l . While this sounds nice, I am not sure what it means in practice. It would be crucial if you were able to make high precision determination of MGU T or mT , the mass of colored triplets responsible for d = 5 proton decay. The trouble is that the lack of knowledge of the superpotential couplings is sufficient even in the minimal SU (5) theory to prevent this task; in SO(10) it gets even worse. 2 Maybe more relevant is the fact that in this scenario MR MGU T /MP l 13 14 10 –10 GeV, which fits nicely with the neutrino masses via see-saw. Furthermore, see-saw can be considered “clean”, of the pure type I, since the type-II effect is suppressed by 1/MP l . Most important, the mb mτ relation from (129) is maintained due to small 1/MP l effects relevant only for the first two generations. Large representations. The nonrenormalizable operators in reality mean invoking new physics beyond grand unification. This may be necessary, but still, one should be more ambitious and try to use the renormalizable theory only. This means large representations necessarily: at least 126H is needed in order to give the mass to νR (in supersymmetry, one must add 126H ). The consequence is the loss of asymptotic freedom above MGU T , the coupling constants grow large at the scale ΛF 10MGU T . Once we accept large representations, we should minimize their number. The minimal theory contains, on top of 10H , 126H and 126H , also 210H [31-34] with the decomposition (132)

210H = (1, 1, 1)− + (15, 1, 1)+ + (15, 1, 3) + (15, 3, 1) +(6, 2, 2) + (10, 2, 2) + (10, 2, 2),

where the −(+) subscript denotes the properties of the color singlets under charge conjugation. The Higgs superpotential is remarkably simple, (133)

WH = m210 (210H )2 + m126 126H 126H + m10 (10H )2 + λ(210H )3 +η126H 126H 210H + α10H 126H 210H + α10H 126H 210H

and the Yukawa one even simpler (134)

WY = y10 16F Γ16F 10H + y126 16F Γ5 16F 126H .

Remarkably enough, this may be sufficient, without any higher-dimensional operators; however, the situation is not completely clear. There is a small number of parameters: 3 + 6 × 2 = 15 real Yukawa couplings, and 11 real parameters in the Higgs sector. In this sense the theory can be considered as the minimal supersymmetric GUT in general [34]. As usual, I am not counting the parameters associated with the SUSY breaking terms.

304

´ G. Senjanovic

The nicest feature of this program (and the best justification for the use of large representations) is the following. Besides the (10, 1, 3) which gives masses to the νR ’s, also the (15, 2, 2) in 126H gets a vev [32, 20]. Approximately (135)

15, 2, 2126

MP S 1, 2, 2, MGU T

with MP S = 15, 2, 2 being the scale of SU (4)c symmetry breaking. In SUSY, MP S ≤ MGU T and thus one can have correct mass relations for the charged fermions. What is lost, though, is the b − τ unification, i.e. with (15, 2, 2)126 = 0, mb = mτ at MGU T becomes an accident. However, in the case of type-II see-saw, there is a profound connection between b−τ unification and a large atmospheric mixing angle. The fermionic mass matrices are obtained from (134) u u Mu = v10 y10 + v126 y126 , d d Md = v10 y10 + v126 y126 , d d Me = v10 y10 − 3v126 y126 ,

(136)

u u MνD = v10 y10 − 3v126 y126 ,

(137)

MνR = y126 (10, 1, 3),

(138)

MνL = y126 (10, 3, 1),

2 where (10, 3, 1) MW /MGU T provides a direct (type II) see-saw mass for light neutrinos. The form in (136) is readily understandable, if you notice that (1, 2, 2) is a SU (4)c singlet with mq = m , and (15, 2, 2) is a SU (4)c adjoint, with m = −3mq . The vevs of the bidoublets are denoted by v u and v d as usual. Now, suppose that type II dominates, or Mν ∝ y126 ∝ Me − Md , so that

Mν ∝ Me − M d .

(139)

Let us now look at the 2nd and 3rd generations first. In the basis of diagonal Me , and for the small mixing de  (140)

Mν ∝

m μ − ms de

 de , m τ − mb

obviously, large atmospheric mixing can only be obtained for mb mτ [19]. Exercise: Prove that the above neutrino mass matrix requires b − τ unification in order to lead to a large mixing angle. Use the fact that the second-generation masses are small in comparison with the third-generation ones. Of course, there was no reason whatsoever to assume type-II see-saw. Actually, we should reverse the argument: the experimental fact of mb mτ at MGU T , and large

305

Theory of neutrino masses and mixings

θatm seem to favor the type-II see-saw. It can be shown, in the same approximation of 2-3 generations, that type I cannot dominate: it gives a small θatm [24]. This gives hope to disentangle the nature of the see-saw in this theory. As a check, it can be shown that the two types of see-saw are really inequivalent [24]. I wish to stress an important feature of this programme. Since 126 (126) is invariant under matter parity, R parity remains exact at all energies and thus the lightest supersymmetric particle is stable and a natural candidate for the dark matter. Mass scales. In SO(10) we have in principle more than one scale above MW (and ΛSU SY ): the GUT scale, the Pati-Salam scale where SU (4)c is broken, the L-R scale where parity (charge conjugation) is broken, the scales of the breaking of SU (2)R and U (1)B-L . Of course, these may be one and the same scale, as expected with low-energy supersymmetry. This solution is certainly there, since the gauge couplings of the MSSM unify successfully and encourage the single step breaking of SO(10). Is there any room for intermediate mass scales in SUSY SO(10)? It is certainly appealing to have an intermediate see-saw mass scale MR , between 1012 and 1015 GeV or so. In the nonrenormalizable case, with 16H and 16H , this is precisely what happens: 2 13 14 MR cMGU T /MP l c(10 –10 ) GeV. In the renormalizable case, with 126H and 126H , one needs to perform a renormalization group study using unification constraints. While this is in principle possible, in practice it is hard due to the large number of fields. The stage has recently been set, for all the particle masses were computed [25,26], and the preliminary studies show that the situation may be under control [27]. It is interesting that the existence of intermediate mass scales lowers the GUT scale [25, 28], allowing for a possibly observable d = 6 proton decay. Notice that a complete study is basically impossible. In order to perform the running, you need to know particle masses precisely. Now, suppose you stick to the principle of minimal fine tuning. As an example, you fine-tune the mass of the W and Z in the SM, then you know that the Higgs mass and the fermion masses are at the same scale √ (141)

mH =

λ mW , g

mf =

yf mW , g

where λ is a φ4 coupling, and yf an appropriate fermionic Yukawa coupling. Of course, you know the fermion masses in the SM model, and you know mH mW . In an analogous manner, at some large scale mG a group G is broken and there are usually a number of states that lie at mG , with masses (142)

mi = αi mG ,

where αi is an approximate dimensionless coupling. Most renormalization group studies typically argue that αi O(1) is natural, and rely on that heavily. In the SM, you could then take mH mW , mf mW ; while reasonable for the Higgs, it is nonsense for the fermions (except for the top quark).

306

´ G. Senjanovic

In supersymmetry all the couplings are of Yukawa type, i.e. self-renormalizable, and thus taking αi O(1) may be as wrong as taking all yf O(1). While a possibly reasonable approach when trying to get a qualitative idea of a theory, it is clearly unacceptable when a high-precision study of MGU T is called for. 4 Proton decay. As you know, d = 6 proton decay gives τp (d = 6) ∝ MGU T , while (d = 5) 2 gives τp (d = 5) ∝ MGU T . In view of the discussion above, the high-precision determination of τp appears almost impossible in SO(10) (and even in SU (5)). You may wonder if our renormalizable theory makes sense at all. After all, we are ignoring the higher-dimensional operators of order MGU T /MP l 10−2 –10−3 . If they are present with the coefficients of order one, we can forget almost everything we said about the predictions, especially in the Yukawa sector. However, we actually know that the presence of 1/MP l operators is not automatic (at least not with the coefficients of order 1). Operators of the type (in symbolic notation)

O5p =

(143)

c 164 MP l F

are allowed by SO(10) and they give (144)

O5p =

c [(QQQL) + (Qc Qc Qc Lc )] . MP l

These are the well-known d = 5 proton decay operators, and for c O(1) they give τp 1023 y. Agreement with experiment requires (145)

c ≤ 10−6 .

Exercise: Hard. Prove the above result. Use the fact that the supersymmetric oper˜Q ˜ and then use the ator of the type QQQL corresponds to an effective interaction QLQ ˜ ˜ interactions with gauginos to transform QQ into QQ in order to create a proton decay operator QQQL. It happens at the one-loop level. Could this be a signal that 1/MP l operators are small in general? Alternatively, you need to understand why just this one is to be so small. It is appealing to assume that this may be generic; if so, neglecting 1/MP l contributions in the study of fermion masses and mixings is fully justified. 7. – Majorana neutrinos: lepton number violation and the origin of neutrino mass Majorana neutrino mass implies ΔL = 2 processes: 1) neutrinoless double-β decay, 2) same-sign dilepton par production at colliders [36].

307

Theory of neutrino masses and mixings

p

n WR

e

x mN

n

WR

e p

Fig. 4. – Neutrinoless double-β decay through WR and N .

. 7 1. Neutrinoless double-β decay. – This is the usual text-book example of ΔL = 2 and is often considered a probe of Majorana mν . However, the Majorana case needs a completion of the SM and ββ 0 depends in general on the completion. A simple and clear example is provided by L-R symmetric theories with low MR scale in which case there are new contributions to ββ 0 . The dominant one is due to the WR exchange and right-handed neutrinos N , as shown in fig. 4. It gives   1 1 (146) (ββ 0 )RR ∝ 4 ee, M W R MN to be compared with the usual WL contribution (147)

(ββ 0 )LL ∝

1 (mν )ee , 4 MW p2 L

where we assume gL gR and p is the momentum exchange p 100 MeV. We have 4    1 MWL p2 (ββ 0 )RR (148) ee.

(ββ 0 )LL MW R (mν )ee MN For MR in the few TeV region and MN TeV, the (RR) contribution tends to dominate over the (LL) one, and clearly right-handed neutrinos should not be too light. Since mν → 0 when yD → 0, you can imagine a situation when neutrino mass is arbitrarily small, but (ββ 0 )RR = 0 due to the N exchange. Srictly speaking, ββ 0 is not a measure of light neutrino masses and it will be hard to disentangle the origin of the see-saw through this process. In particular, we would need to know whether it is due to exchange of ν’s or heavy particles needed to complete the SM in order to have mν = 0 (such as NR ).

308

´ G. Senjanovic

j j

WR N

d

uŦ

WR

l

l Fig. 5. – Production of lepton-number–violating same-sign dileptons at colliders through WR and N .

It is thus crucial to have a direct measure of lepton number violation which can probe the source of neutrino Majorana mass. This is provided by the same-sign dilepton production at colliders as we discuss below. . 7 2. Lepton number violation at colliders. – We have just seen that ββ 0 is obscured by various contributions which are not easy to disentangle. We need some direct tests of the origin of ΔL = 2, i.e. the see-saw mechanism. This comes about from possible direct production of the right-handed neutrinos through a WR production. The crucial point here is the Majorana nature of N : once produced it should decay equally often into leptons and antileptons. This led us [36] to suggest a direct production of the same-sign dileptons at colliders as a manifestation of ΔL = 2. The most promising channel is  + 2 jets as seen form fig. 5. One can also imagine a production of N through its couplings to WL (proportional to yD ), but this is a long shot. It would require large yD and large cancellations among them in order to have small mν . This could be achieved in principle by fine-tuning, but is not the see-saw mechanism. The crucial characteristics: 1) no missing energy which helps to fight the background, 2) by measuring energies and momenta of the final states, one can reconstruct both the mas of Wr and of the right-handed neutrino, 3) the process can be amplified by the WR resonance.

309

Theory of neutrino masses and mixings

Ŧ

l

Y ++

Ŧ

l

Z

ŦŦ

Y l l Fig. 6. – Production of a pair of double-charged Higgs scalars and subsequent decay into pairs of same-sign dileptons.

The main background comes from b¯b + jets, but can be fought against with the usual cuts of large pt for leptons and jets. Also important is tt¯ + jets, which is less present but more resistent to large pT cuts. Careful and complete studies were performed with encouraging results: one can easily discover WR at the LHC up to MWR 3–4 TeV and mN 100 GeV–TeV. In the L-R symmetric theories one also predicts type-II see-saw as discussed before. Type II can also exist by itself in which case it can lead to rather interesting signatures at the colliders if the scale of the SU (2)L triplet Δ is light enough. In particular, it can lead to the production of doubly charged scalars that decay into same-sign dilepton pairs as in fig. 6. Notice that Δ++ and Δ−− decay through the Yukawas yΔ , these decays thus probe the neutrino mass matrix (149)

Mν = yΔ Δ.

One can derive the sum rules for the flavor structure of fig. 6. Of course, this is valid only when these decays dominate over the decays with W bosons through Δ. The relative strength of Δ−− →  and Δ−− → W − W − depends on yΔ . From (150)

Γ(Δ−− → )

2 yΔ MΔ 8π

and (151)

Γ(Δ−− → W − W − )

g 2 Δ2 8πMΔ

310

´ G. Senjanovic

YT TŦ

l

Z j

WŦ j T

0

W+

YT

j l j

Fig. 7. – The same-sign dilepton signature of type-III seesaw through the production of the charged and neutral components of a fermion triplet TF .

for MΔ  MW , one gets (152)

B(Δ−− → ) ≡

2 2 yΔ Γ(Δ−− → ) MΔ

. Γ(Δ−− → W − W − ) g 2 Δ2

Thus B(Δ−− → ) ≥ 1 requires that the vev of Δ be small and yΔ large. Ideally, observing both decays would establish the SU (2) gauge triplet property of Δ and could measure the form of the neutrino mass matrix. The widely separated dilepton pairs in the case of B(Δ−− → ) ≥ 1 provide a clean manifestation of the type-II see-saw mechanism and allow for the discovery of Δ++ with MΔ ≤ 800 GeV. In short, both type I and II could lead to exciting ΔL = 2 signatures at LHC, if WR and N and/or Δ are light enough. But, as will be discussed later, in predictive grand unified theories such as minimal SO(10), they are expected to be rather heavy, out of reach for LHC. One can ask the same question in the case of type-III see-saw. As we said, one would need at least the fermionic triplets in order to have at least two massive neutrinos, one could have a hybrid situation of type-I and type-III see-saw, with a heavy fermionic singlet (N ) and triplet (T ). This case is particularly interesting, since it emerges naturally in the SU (5) grand unified theory. Again, the process of interest for LHC is a production of same-sign dileptons (but now with 4 jets) as in fig. 7. The main point here is that in the minimal SU (5) theory augmented by an adjoint fermionic representation 24F the fermion triplet TF is predicted to lie below TeV, and thus the above process is a realistic possibility at colliders such as LHC.

Theory of neutrino masses and mixings

311

8. – Summary and outlook The smallness of neutrino mass is an intriguing fact that gives hope of being a window into a new physics beyond the standard model. This crucially depends on the nature of neutrino mass, i.e. whether it is Dirac or Majorana. In the former case, the standard model is a complete theory and although the smallness of neutrino mass is attributed to the smallness of Dirac Yukawa couplings. True, this is not explained, but strictly speaking there may be no new physics, the same way that there may be no new physics behind the smallness of electron mass. In the limit of small Yukawas one has more symmetry, and thus small Yukawas are technically natural, protected from high-energy physics. The Dirac case thus gives no clue where to look for a new physics. Of course, one can always search for horizontal symmetries as the explanation of small Yukawas, but here there is the danger of only changing the language. The Majorana case, on the other hand, provides a clear window into new physics for the MSM with Majorana neutrino mass is not a complete theory. At the same time, this case implies a violation of lepton number through a neutrinoless double-beta decay as is well known and the possible production of the same-sign dileptons, less known but becoming a new hot field in itself. The completion of the MSM that produces small neutrino Majorana mass results in the celebrated see-saw mechanism which comes in three different varieties. In order to be predictive, though, the see-saw mechanism needs a theory behind, for otherwise it is simply a linguistic variation on the effective d = 5 operator that we saw necessarily describe neutrino mass after the new states are integrated out. One important theory which leads to both type-I and -II see-saw is based on L-R symmetry, and has been a principal source of neutrino mass and see-saw. If the scale of L-R symmetry breaking were to be in the TeV region, one would have a possibility of seeing both the parity restoration and the origin of the neutrino mass through the production of a right-handed charged boson and right-handed neutrinos. Similarly, one could in principle produce the scalar triplet responsible for the type-II see-saw. The scale of L-R breaking can be predicted only in grand unification and in simple, predictive models it is quite large, far above the TeV scale of colliders. Still, one may be able to connect the values of neutrino masses and mixings with the predictions for the branching ratios of proton decay an thus have a check on the theory, albeit indirect. On the other hand, the type-III see-saw finds its natural realization in SU (5) grand unified theory, when the minimal model of Georgi and Glashow is augmented by an adjoint fermion representation. This allows for the unification of gauge couplings and provides a hybrid type-I and -III see-saw. One predicts one massless neutrino and more important a light weak triplet fermion, with a mass below TeV. The decays of the triplet probe neutrino masses and mixings through the lepton number violating production of same-sign dileptons accompanied by four jets. The hope of finding the origin of neutrino mass becomes feasible at colliders such as LHC. In summary, I tried to argue in these lectures in favor of Majorana masses of neutrinos, and the possibility of seeing its origin through lepton number violation or the connection with proton decays. The lepton number violation will be searched for in the

312

´ G. Senjanovic

new generation of neutrinoless double-beta decay and at LHC. Hopefully, a serious effort will be put in the next generation of proton decay experiments; they could be simultaneously a probe of baryon number violation in nature and an origin of neutrino masses and mixings. Appendix A. Dirac and Majorana masses The irreducible spin 1/2 representations of the Lorentz group are the two-component left- and right-handed chiral fermion Weyl fields uL and uR , which transform under the Lorentz group as uL,R → ΛL,R uL,R ,

(A.1) with









ΛL ≡ eiσ/2(θ+iφ ) ,

(A.2)

ΛR ≡ eiσ/2(θ−iφ ) .  denotes the boosts. The spinors ψL The three Euler angles θ stand for rotations, ad φ and ψR transform the same under the rotations, but in an opposite manner under the boosts. It is straightforward to show that the following bilinear combinations are Lorentz invariant: (A.3)

(M )

uTL iσ2 uL

(D)

u†L uR

uTR iσ2 uR

and and

u†R uL

(Majorana type),

(Dirac type).

Historically, the Dirac type came first, but in a sense the Majorana invariant is even more fundamental for it needs only one species of fermions. To bridge the gap with Dirac four-component fermions, we need the Dirac algebra (A.4)

{γ μ , γ ν } = 2g μν ,

g μν = diag(1, −1, −1, −1),

with  (A.5)

i

γ =

0 −σ i

 σi , 0

 0

γ = 

(A.6)

γ5 = iγ 1 γ 2 γ 3 γ 0 =

12 0

and the projectors (A.7)

PL.R ≡

1 ± γ5 . 2

0 12

0 −12

 12 , 0 

313

Theory of neutrino masses and mixings

The Dirac charge conjugation, defined through C T γ μ C = −γμT ,

(A.8)

C T = −C

is with my conventions C = iγ2 γ0 .

(A.9)

In other words, the Majorana mass term can be written as T CψL + h.c.) (M ) mM (ψL

(A.10) and the Dirac one as (A.11)

¯ (D) mD (ψ¯L ψR + ψ¯R ψL ) ≡ mD ψψ,

ψ ≡ ψ L + ψR .

It is convenient to work with left-handed antiparticles instead of right-handed particles (A.12)

T , (ψ C )L ≡ C ψ¯R

in which case one can write a mass matrix for ψL and (ψ C )L in the Majorana notation (ψ1T Cψ2 )  (A.13)

mL mD

 mD , mR

where mL and mR are the Majorana mass terms of ψL and ψR , respectively. The case of a pure Dirac fermion simply means mL = mR = 0. If neutrino mass is of the Majorana type, on the other hand, it will imply a violation of the lepton number and a new rich physics associated with it. Appendix B. Majorana spinors: Feynman rules Take a two-component spinor with left-handed chirality ψL with the following Lagrangian:  m M T ψL CψL + h.c. , (B.1) LM = iψ¯L γ μ ∂μ ΨL − 2 where the subscript M indicates the Majorana nature of the mass term. In order to bridge the gap with the familiar 4-component Dirac case, introduce by analogy (B.2)

T ψM ≡ ψL + C ψ¯L .

From (B.3)

ψ¯M γ μ ∂μ ψM = 2ψ¯L γ μ ∂μ ψL

314

´ G. Senjanovic

and T CψL + h.c., ψ¯M ψM = ψL

(B.4) we get

 1 ¯ μ iψM γ ∂μ − mM ψ¯M ψM . 2

LM =

(B.5)

Two important facts emerge 1) mM is the (Majorana) mass of ψM , 2) one can use the usual Dirac case Feynman rules. Appendix C. SU (N ) group theory On a fundamental N -dimensional complex representation Φ, the SU (N ) group acts as (C.1)

U † U = 1,

Φ → U Φ,

det(U ) = 1

and U can be written as (C.2)

U = e−iθa Ta ,

a = 1 . . . N 2 − 1,

where the group generators Ta satisfy (C.3)

Ta = Ta† ,

Tr(Ta ) = 0,

[Ta , Tb ] = ifabc Tc ,

where fabc are the group structure constants. There is also a complex conjugate representation (C.4)

Φ∗ → U ∗ Φ∗

and an (N 2 − 1)-dimensional adjoint representation (C.5)

A → U AU † = A − iθa [Ta , A] + . . . .

In other words, the generators act on A as commutators. One can write A = Aa Ta , so that Aa transforms under a small group rotation as (C.6)

Aa → Aa + fabc θb Ac .

Examples of fields transforming as the adjoint representation are the gauge bosons A of SU (N ) and the heavy scalars Σ employed to break the grand unified symmetry. The

315

Theory of neutrino masses and mixings

reason for the latter is the fact that under a unitary transformation Σ → U ΣU † , one can have Σ diagonal, which in turn implies (C.7)

[Σ, Ta ∈ Cartan] = 0.

The adjoint Higgs preserves the rank of the group after the symmetry breaking. This is specially important in SU (5) since it has the same rank (= 4) as the SM gauge group. All other representations are built out of the fundamental Φ (and/or Φ∗ ) by symmetrizing and antisymmetrizing (and subtracting the trace when necessary). For example (C.8)

Φi Φj = Φ[i,j] + Φ{i,j} N (N − 1) N (N + 1) . 2 2

This means that all the charges get summed up (C.9)

Q(Φi Φj ) = Q(Φi ) + Q(Φj ).

Appendix D. SO(2N ) group theory SO(2N ) is the group of real orthogonal transformations, OT O = OOT = 1, with det(O) = 1. It can be generated by N (N − 1)/2 Hermitian antisymmetric matrices (D.1)

O = e−iθij Lij ,

with (D.2)

(Lij )kl = −i(δik δjl − δil δjk ),

so that one has the following commutation relations: (D.3)

[Lij , Lkl ] = i(δik Ljl − δjl Lik ).

The N -dimensional Cartan subalgebra is spanned by (D.4)

Cartan = {L12 , L34 , . . . , L2N −1,2N },

whose eigenvalues are ±1. The fundamental (vector) representation transforms as (D.5)

Φi → Oij Φj

and is generated by Lij in Appendix D.2. One can construct the general N -index irreducible representation by antisymmetrizing or symmetrizing (and subtracting traces)

316

´ G. Senjanovic

N times the vector representation. Rather interesting are the [N ]-index antisymmetric ones, for one can complexify them by introducing Φ± [a1 ...aN ] = Φ[a1 ...aN ] ±

(D.6)

iN a ...a b ...b Φb ...b . N! 1 N 1 N 1 N

We illustrate this on a simple example below in SO(2) where this amounts to just complexifying a fundamental representation. It turns out that such 5 index antisymmetric 126-dimensional representation of SO(10) plays a profound role in the physics of neutrino mass; this is discussed in sect. 6. . D 1. SO(2N ): spinors. – By analogy with the Dirac algebra in Minkowski space, an Euclidean version is based on the Clifford algebra of the Γi matrices (i = 1 . . . 2N ) {Γi , Γj } = 2δij ,

(D.7)

out of which one can construct N (N − 1)/2 generators Σij =

(D.8)

1 [Γi , Γj ], 4i

which satisfy the usual commutation relations of the SO(2N ) generators in Appendix D.3. It is easy to see that the Cartan subalgebra consists of N generators Cartan = {Σ12 , . . . , Σ2N −1,2N },

(D.9)

whose eigenvalues are ±1/2. The appropriate 2N -dimensional complex representation Ψ is called a spinor of SO(2N ). Adding a spinor changes of course a group, just as SO(3) becomes SU (2). One often calls SO(10) with spinors Spin(2N ). The spinors transforms in the following manner: Ψ → e−iθij Σij Ψ.

(D.10)

Again, by analogy with Dirac γ5 matrix, one can introduce ΓFIVE = (−1)N Γ1 . . . Γ2N ,

(D.11) with the properties (D.12)

Γ2FIVE = 1,

[ΓFIVE , Σij ] = 0,

{ΓFIVE , Γi } = 0.

By using the projectors (D.13)

Γ+(−) ≡

1 ± ΓFIVE , 2

one can construct the irreducible 2N −1 dimensional spinors (D.14)

Ψ± ≡ Γ+(−) Ψ,

by analogy with Weyl spinors of the Lorentz group.

317

Theory of neutrino masses and mixings

One can also introduce the analogue of the usual charge conjugation by demanding that (D.15)

ΨT BΨ = invariant ⇔ Ψc ≡ BΨ∗ ,

which amounts to (D.16)

ΣT B + BΣ = 0.

There are two possible solutions for B (D.17)

B(1) = Γ1 . . . Γ2N −1 ,

B(2) = Γ2 . . . Γ2N .

. D 2. The ket notation for spinors. – From (D.18)

ΓFIVE = 2Σ12 . . . 2Σ2N +1,2N ,

one can write (D.19)

ΓFIVE = 1 2 . . . N ,

where i are ±1, the eigenvalues of Σ2i−1,2i . Then one can denote the Ψ+ spinors as a ket (D.20)

Ψ+ ≡ |1 . . . N 

For example, take the spinors Ψ+ of SO(10) (D.21)

Ψ+ ≡ |1 . . . 5 ;

1 . . . 5 = +1.

The 16-component Ψ+ can be decomposed as ⎧ 1 field | + + + ++ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ | + + + −−, | + + − +−, | + + − −+ ⎪ ⎪ ⎨ 10 fields | + − + +−, | + − + −+, | + − − ++ (D.22) Ψ+ = ⎪ | − + + +−, | − + + −+, | − + − ++, | − − + ++ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ ⎪ | + − − −−, | − + − −− ⎪ ⎪ ⎩ 5 fields | − − + −, | − − − +−, | − − − −+ We will see that this can be interpreted as a decomposition under SU (5) (D.23)

16 = 10 + 5 + 1,

in other words, a family of fermions augmented by a right-handed neutrino makes an irreducible spinorial representation of SO(10). The unification of matter, on top of gauge interactions, points strongly towards SO(10). However, in order to appreciate this fact and have fun with SO(10), we first go through some pedagogical exposition of smaller groups.

318

´ G. Senjanovic

. D 3. SO(2): a prototype for SO(4n + 2). – We choose (D.24)

Γ1 = σ1 ,

Γ2 = σ2 ,

so that (D.25)

ΓFIVE = σ3

σ3 , 2

Σ12 =

which illustrates clearly [ΓFIVE , Σi,j ] = 0. The irreducible 1-component spinors transform as (D.26)

Ψ+ → e−iθ/2 Ψ+ ,

Ψ− → e+iθ/2 Ψ− ,

since  (D.27)

Ψ≡

Ψ+ Ψ−



−iθσ3 /2



→e

 Ψ+ . Ψ−

On the other hand, the two-component vectors transform as      φ1 φ1 cos θ sin θ (D.28) → , − sin θ cos θ φ2 φ2 or (D.29)

φ1 ± iφ2 → e±iθ (φ1 ± iφ2 ).

Equations (D.26) and (D.29) simply account for the fact SO(2) U (1). The internal “charge” conjugation B can be chosen as B1 = σ1 , so that (D.30)

ΨT BΨ = Ψ+ Ψ− .

However, only Ψ+ (or Ψ− ) is an irreducible spinor, therefore there is no mass term for an irreducible spinor of SO(2). In other words, the spinors Ψ+ (Ψ− ) are chiral and can represent physical particles such as the fermions of the SM. This is true in any SO(4n + 2) theory. In particular, in SO(10), which means that it offers hope of being realistic. Dual representation. From (D.31)

ij det O = Oik Ojl kl ,

is is easy to see that φi and ij φi transform in the same way. We can introduce the self(anti-self) dual representation (D.32)

1 Φi (±) = √ (φi ± iij φj ), 2

which is nothing but the complex representation of U (1) (D.29). This should make clear the generic concept of self-dual representations in SO(2N ) discussed before.

319

Theory of neutrino masses and mixings

Yukawa couplings. We have seen that there is no direct mass term. There are Yukawa couplings, though, of the type (D.33)

LY = ΨT Bσi Ψφi = Ψ+ Ψ+ (φ1 − iφ2 ) + Ψ− Ψ− (φ1 + iφ2 ),

as dictated by U (1) charges. . D 4. SO(4). – One knows that SO(4) is isomorphic to SU (2) × SU (2), and it plays an important role in providing a left-right symmetric subgroup of SO(10). It is a Euclidean analog of the Lorentz group and the Clifford algebra can be generated by 

(D.34)

0 Γ1 = σ1  0 Γ3 = σ3

   σ1 0 σ2 Γ2 = 0 σ2 0    σ3 0 −i , Γ4 = i 0 0

so that (D.35)







 0 , −iσ2

1 0 0 −1

ΓFIVE =

and “charge” conjugation can be taken as (D.36)

B(1) = Γ1 Γ3 =

−iσ2 0

or  (D.37)

B(2) = Γ2 Γ4 =

iσ2 0

 0 . −iσ2

The mass term (D.38)

ΨT BΨ ∝ ΨT+ iσ2 Ψ+ + . . . ,

where (D.39)

Ψ± =

1 ± Γ5 Ψ± . 2

In other words, the mass term for Ψ+ (or Ψ− ) is invariant, which means that we can have no chiral fermions in SO(4). This is true for all SO(4n) groups. In the ket notation (D.40)

Ψ+ = |1 2 ;

1 2 = 1;

1,2 = ±1,

320

´ G. Senjanovic

or  | + + . | − −

 (D.41)

Ψ+ =

Introduce the neutral generator of SU (2)L and SU (2)R (D.42)

T3L ≡

1 (Σ12 + Σ34 ), 2

T3R ≡

1 (Σ12 − Σ34 ), 2

and you see that Ψ+ is an SU (2)L doublet, SU (2)R singlet field, an analog of left-handed Weyl spinors of the Lorentz group. Similarly, Ψ− is an SU (2)L singlet, SU (2)R doublet field. . D 5. SO(6). – SO(6) ∼ SU (4)C is the Pati-Salam group of quark-lepton symmetry, with leptons as the fourth color. It deserves a brief description. Start with a six-dimensional vector Φi (i = 1 . . . 6). It is easy to see that the components (φ1 ± φ2 ), (φ3 ± φ4 ), (φ5 ± φ6 ) transform as 3 and 3∗ of its subgroup SU (3) which we identify with the color. The neutral generators are identified as 1 (Σ12 − Σ34 ), 2 1 = (Σ12 + Σ34 − 2Σ56 ). 2

T3C =

(D.43)

T8C

The additional neutral generator of SU (4), identifiable as B-L, can be written as 2 B-L = − (Σ12 + Σ34 + Σ56 ). 3

(D.44)

Regarding spinors, the positive chirality can be written as

(D.45)

Ψ+ =

⎧ ⎨color singlet

| + ++,

⎩color triplet (B-L) = 1/3

| + −−, | − +−, | − −+.

It says simply that the irreducible 4-component spinor of SO(6) is a fundamental of SU (4) with the decomposition under SU (3)C (with B-L) (D.46)

Ψ+ = 4 = 1−1 + 31/3 ,

which is precisely a combination of a lepton and a colored quark. Similarly, Ψi = 4∗ = 1+1 + 3−1/3 stands for an antilepton and antiquark. Exercise: As a check, show that 4 × 4 = 6 + 10. Show that 6 of SO(6) has the quantum number of the 6 (antisymmetric) of SU (4).

321

Theory of neutrino masses and mixings

Yukawa couplings in SO(6). We know that the irreducible spinors of SO(6) are fundamental representations of SU (4) and 4 × 4 = 6 + 10. There are then two types of Yukawa couplings (D.47)

LY = y6 ΨT BΓi ΨΦi + y10 ΨT BΓi Γj Γk ΨΦ− [ijk] ,

where it is a simple exercise to show that Φ− [ijk] is an anti-self-dual representation (D.48)

− Φ− ijk = Φ[ijk] =

i ijklmn Φ[lmn] , 3!

and where Φ− [ijk] is the 3-index antisymmetric tensor of SO(6). Exercise: Construct the self-dual and anti-self-dual representation of SO(6) out of the 3-index antisymmetric representation Φ[ijk] . Show that 20 = 10 + 10. Then prove equation (D.47) and show that there are no other couplings. Exercise: Take the Pati-Salam group SO(4) × SO(6) SU (2)L × SU (2)R × SU (4)c . Show that the representations (2, 1, 4) and (1, 2, 4) give a family of quarks and leptons augmented by a right-handed neutrino. Exercise: The chiral anomalies are proportional to Λijk = Tr({Ti , Tj }Tk ). Show that the SO(2N ) groups are anomaly free, except for the SO(6). Comment on why SO(6) must have an anomaly. REFERENCES [1] Mohapatra R. N. and Pal P. B., World Sci. Lect. Notes Phys., 60 (1998) 1 (World Sci. Lect. Notes Phys., 72 (2004) 1). [2] Strumia A. and Vissani F., arXiv:hep-ph/0606054. [3] Glashow S. L., Nucl. Phys., 22 (1961) 579. [4] For useful reviews on spinors in SO(2N ), see Mohapatra R. N. and Sakita B., Phys. Rev. D, 21 (1980) 1062; Wilczek F. and Zee A., Phys. Rev. D, 25 (1982) 553. See also Nath P. and Syed R. M., Nucl. Phys. B, 618 (2001) 138; Aulakh C. S. and Girdhar A., arXiv:hep-ph/0204097. [5] Mohapatra R. N., Phys. Rev. Lett., 43 (1979) 893. [6] Nath P. and Perez P. F., arXiv:hep-ph/0601023. [7] Minkowski P., Phys. Lett. B, 67 (1977) 421; Yanagida T., Proceedings of the Workshop on Unified Theories and Baryon Number in the Universe, Tsukuba, 1979, edited by Sawada A., Sugamoto A. and Glashow S., in Cargese 1979, Proceedings, Quarks and Leptons (1979); Gell-Mann M., Ramond P. and Slansky R., Proceedings of the Supergravity Stony Brook Workshop, New York, 1979, edited by Van Niewenhuizen P., ´ G., Phys. Rev. Lett., 44 (1980) 912. Freeman D., Mohapatra R. and Senjanovic [8] Magg M. and Wetterich C., Phys. Lett. B, 94 (1980) 61; Lazarides G., Shafi Q. and ´ G., Wetterich C., Nucl. Phys. B, 181 (1981) 287; Mohapatra R. N. and Senjanovic Phys. Rev. D, 23 (1981) 165. [9] Pati J. C. and Salam A., Phys. Rev. D, 10 (1974) 275. [10] Mohapatra R. N. and Pati J. C., Phys. Rev. D, 11 (1975) 2558.

322

´ G. Senjanovic

[11] [12] [13] [14] [15] [16]

´ G. and Mohapatra R. N., Phys. Rev. D, 12 (1975) 1502. Senjanovic ´ G., Nucl. Phys. B, 153 (1979) 334. Senjanovic ´ G., arXiv:hep-ph/0612029. Bajc B. and Senjanovic Ellis J. R. and Gaillard M. K., Phys. Lett. B, 88 (1979) 315. Bajc B., Nemevsek M. and Senjanovic G., arXiv:hep-ph/0703080. ´n ˜ez L. E. and Quevedo Mohapatra R. N., Phys. Rev. D, 34 (1986) 3457; Font A., Iba F., Phys. Lett. B, 228 (1989) 79; Martin S. P., Phys. Rev. D, 46 (1992) 2769; Aulakh ´ G., Phys. Rev. Lett., 79 (1997) 2188; Aulakh C. S., C. S., Benakli K. and Senjanovic ´ G., Phys. Rev. D, 57 (1998) 4174 (arXiv:hep-ph/9707256); Melfo A. and Senjanovic ´ G., Phys. Rev. D, 58 (1998) 115007 Aulakh C. S., Melfo A., Raˇ sin A. and Senjanovic ´ G., Phys. sin A. and Senjanovic (arXiv:hep-ph/9712551); Aulakh C. S., Melfo A., Raˇ Lett. B, 459 (1999) 557 (arXiv:hep-ph/9902409). ´ G., Phys. Rev. Lett., 79 (1997) 2188; Aulakh C. S., Benakli K. and Senjanovic ´ G., Phys. Rev. D, 57 (1998) 4174; Aulakh Aulakh C. S., Melfo A. and Senjanovic ´ G., Phys. Lett. B, 459 (1999) 557. C. S., Melfo A., Raˇ sin A. and Senjanovic ´ G., Nucl. Phys. B, 597 Aulakh C. S., Bajc B., Melfo A., Raˇ sin A. and Senjanovic (2001) 89. ´ G. and Vissani F., Phys. Rev. Lett., 90 (2003) 051802. Bajc B., Senjanovic Babu K. S. and Mohapatra R. N., Phys. Rev. Lett., 70 (1993) 2845. Witten E., Phys. Lett. B, 91 (1980) 81. See e.g. Chang D., Mohapatra R. N., Gipson J., Marshak R. E. and Parida M. K., Phys. Rev. D, 31 (1985) 1718. Dvali G. and Vilenkin A., arXiv:hep-th/0304043; Dvali G., arXiv:hep-th/0410286. ´ G. and Vissani F., Phys. Rev. D, 70 (2004) 093002 (arXiv:hepBajc B., Senjanovic ph/0402140). ´ G. and Vissani F., Phys. Rev. D, 70 (2004) 035007. Bajc B., Melfo A., Senjanovic Fukuyama T., Ilakovac A., Kikuchi T., Meljanac S. and Okada N., arXiv:hepph/0401213. Aulakh C. S. and Girdhar A., arXiv:hep-ph/0204097. Aulakh C. S. and Girdhar A., arXiv:hep-ph/0405074. Goh H. S., Mohapatra R. N. and Nasri S., arXiv:hep-ph/0408139. Babu K. S. and Macesanu C., Phys. Rev. D, 72 (2005) 115003 (arXiv:hep-ph/0505200). Bertolini S., Frigerio M. and Malinsky M., Phys. Rev. D, 70 (2004) 095002 (arXiv:hep-ph/0406117). Arason H., Castano D. J., Piard E. J. and Ramond P., Phys. Rev. D, 47 (1993) 232 (arXiv:hep-ph/9204225). Aulakh C. S. and Mohapatra R. N., Phys. Rev. D, 28 (1983) 217. Clark T. E., Kuo T. K. and Nakagawa N., Phys. Lett. B, 115 (1982) 26. Chang D., Mohapatra R. N. and Parida M. K., Phys. Rev. D, 30 (1984) 1052. He X. G. and Meljanac S., Phys. Rev. D, 41 (1990) 1620. Lee D. G., Phys. Rev. D, 49 (1994) 1417; Lee D. G. and Mohapatra R. N., Phys. Rev. D, 51 (1995) 1353. ´ G. and Vissani F., Phys. Lett. B, 588 Aulakh C. S., Bajc B., Melfo A., Senjanovi c (2004) 196. Bajc B., Melfo A., Senjanovic G. and Vissani F., Phys. Rev. D, 73 (2006) 055001 (arXiv:hep-ph/0510139). Keung W. Y. and Senjanovic G., Phys. Rev. Lett., 50 (1983) 1427.

[17]

[18] [19] [20] [21] [22] [23] [24] [25] [26] [27] [28] [29]

[30] [31] [32] [33]

[34] [35] [36]

DOI 10.3254/978-1-60750-038-4-323

Calorimetric beta spectroscopy F. Gatti Dipartimento di Fisica, Universit` a di Genova e INFN, Sezione di Genova - Italy

Summary. — In the last decade the energy dispersive spectroscopy of nuclear radiation has made impressive progresses by means of small thermal microcalorimeters operating at about 0.1 K. The present status of this technology, which has achieved 2 eV energy resolution, allows to design a true calorimetric experiment for neutrino mass direct determination with sub-eV sensitivity from the β spectrum of 187 Re and the E.C. spectrum of 163 Ho. The calorimetric method, often indicated as solution for a model-independent measurement, allows to overcome the final states problem of impulse spectroscopy. A further reduction of the systematic uncertatinties might be achived by comparing the finite neutrino mass effect of the two isotopes. Here, the motivations, the principles of operations, the results from the first pilot measurements and the future perspectives are described.

1. – Introduction In 1914 Chadwick made the discovery of the continuous spectra of β-ray of RaB (214 Pb) with a magnetic spectrometer and electron counter [1]. The large spread of the electron kinetic energy from the nuclear decay was in contrast with the quantum theory of the disintegration of the bodies. Actually, at that time, it was already established that α-rays were emitted as mono-energetic lines in transitions from a nucleus to a quantum state of a final nucleus, which could subsequently decay emitting γ lines, definitively demonstrating that the nuclear phenomena were regulated by the quantum c Societ`  a Italiana di Fisica

323

324

F. Gatti

Fig. 1. – Schematics of the Ellis and Wooster experiment: two identical lead calorimeters are suspended with low thermal conductivity mica supports in an adiabatic box. The RaE source was deposited onto one of the two thin rods, which can be fully inserted in the lead calorimeter. The second rod, without radioactive source, is used for subtracting the systematic heating effect caused by its introduction.

rules. Rutherford [2], taking into consideration that discrete electron lines have been found over the continuous spectrum of RaB, supposed the existence of slowing down processes of the primary mono-energetic electrons in the atom itself, therefore accounting for the observed wide distributions. Similarly, Mitner [3] attributed these secondary processes to the surrounding materials. After the observation of the RaE (210 Bi) β decay, which was showing a pure continuous distribution without lines, more fundamental concerns about the nuclear phenomenology were posed, including the non-conservation of the energy. Bohr [4] supported the explanation that in the nuclear processes the energy conservation was no longer valid. In the paper The Average Energy of Disintegration of Radium E [5], in 1927, Ellis and Wooster described an experiment for testing whether the β-ray bodies emit always the same energy in the disintegration or, as they supposed in previous reports, the electrons were directly emitted from the nucleus with varying energies. They performed the first calorimetric experiment that has been applied to the study of the β decay. The calorimeter, which has been depicted in fig. 1, was made with a cylinder of lead 13 mm long and 3.5 mm in diameter with a central hole of 1 mm in diameter. A second copy of the lead calorimeter was built and mounted close to the first. The thermal conductance was minimized by using supports of thin foils of mica and the temperature measured with thermocouples. The calorimeter was placed in a copper box and the RaE sources were inserted and extracted in and from the lead cylinder using small rods. The same tools without radioactive source were used for the second lead cylinder in order to subtract the systematic heating effect of the introduction. Temperature increases of about 1 mK at room temperature were measured with the source inside the calorimeter,

Calorimetric beta spectroscopy

325

with a precision good enough to establish that the mean energy per disintegrating atom was 1/3 of the maximum energy of the β-ray spectrum, within 15% accuracy. This result excludes the presence of a “slowing-down” mechanism in the atom or the surrounding materials and opens the way to the Pauli conjecture [6] of the emission of a weakly neutral non-interacting particle accompanying the electron, later named neutrino by Fermi [7]. 2. – Towards the calorimetric single-event detection The Ellis and Wooster calorimeter was not able to detect single decay events. An a important step forward in the single-particle thermal detection has been made in 1949 by Andrews, Fowler and Williams [8] in bombarding with α-particles a superconducting strip of NbN, 6 μm thick, that was maintained at the normal-to-superconducting critical temperature of about 15.5 K with a current of 40 mA. They reported a countable electrical pulse for each particle impact, corresponding to an equivalent pulse height of 10−7 V. The readout electronics were made crudely with an audio transformer and a pulse amplifier. This technique is incredibly similar to the present one that is used in the best performing calorimetric detectors. However, the sensitivity of the thermal detectors to single particles has been for a long time unsatisfactory with respect to gas proportional chambers and solid-state silicon or germanium PIN diodes. For many decades the development of thermal detectors has concentrated mainly on bolometers for radiant power measurements or for molecular beam experiments. Single-particle thermal detection experiments have been only sporadic tests of prototypes. The boost in the evolution of these detectors started in the ’80s, thanks to the wider availability of new techniques in cryogenics, cold electronics and superconductivity. First of all, the development of cryogenic techniques in the ’60s and ’70s made easy tools available for working at 0.1 K with the He3 -He4 dilution fridges. The achievements of precise surface implantation doping of silicon for the microelectronics and the high-accuracy neutron bulk doping of germanium have made new sensitive semiconducting thermistors available operating at 0.1 K, very close to the metal-to-insulating transition. Furthermore, the achievements in superconductivity with the invention of the SQUID made today a new wide set of very low-noise readout techniques accessible. After two decades of developments, the present generations of thermal detectors show unsurpassed spectral resolution in the energy-dispersive spectroscopy applications. For reference purpose, the microcalorimeters have achieved 2 eV FWHM at 5.9 keV [9], about 70 times better than Si(Li) detectors, and 50 eV FWHM at 100 keV [10], about 10 times better than Ge(Li) detectors. The cryogenic microcalorimeters are commonly composed of a radiation absorber, a thermal sensor that detects the absorber temperature and a weak thermal link between the detector and the heat sink. The operating principle of the microcalorimeter is in principle very simple: when the radiation releases the energy ER in the absorber, this is fully and instantaneously converted into thermal phonons. The temperature of the detector first rises and then drops to its original value, due to the weak thermal link with the heat sink. The height of the temperature transient is ΔT = ER /C, where C is

326

F. Gatti

Fig. 2. – TES microcalorimeter of heat capacity C and thermal conductance G biased at voltage V . The current signal flowing in the inductance L is measured by means of a SQUID in current amplifier configuration.

the microcalorimeter heat capacity. The sensor is generally a resistor whose resistance has a strong dependence on the temperature. Such a thermistor can be biased either at constant current or constant voltage, then the temperature transient is readout as voltage or current pulse, respectively. The modern detectors working with a sensor at the normal-to-superconducting transition, as in the previously cited work of Andrews et al., are usually called Transition Edge Sensor (TES) microcalorimenters (see fig. 2). A simple model of a microcalorimeter is explained in the following. For highsensitivity operations, the detector is first of all brought to a steady state at temperature T0 higher than the one of the thermal sink TS , by means of a Joule power PJ0 , so that the power (1)

W (T0 , TS ) = PJ0

flows through the weak link to the sink. If the radiation gives rise to a small impulsive thermal release in the absorber, the corresponding time evolution of the power PI (t) drives the thermal balance equation of the microcalorimeter (2)

C

T (t) + W (T (t), TS ) = PJ (t) + PI (t). dt

Within the limit of small signals, the difference of the two powers, W (T, TS ) and W (T0 , TS ) of eq. (1) and eq. (2), are approximated by the thermal conductancetemperature drop product: G(T0 ) × ΔT (t), in which ΔT = T (t) − T0 . Therefore it can be written as  (3)

W (T (t), TS ) − W (T0 , TS ) ≈

dW (T (t), T0 ) dT

 × ΔT (t) = G(T0 ) × ΔT (t). T =T0

In the case in which a constant voltage V is applied, and always in the small signals approximation, the difference of the two Joule powers of eq. (1) and eq. (2) can be

327

Calorimetric beta spectroscopy

written as (4) PJ (t) − PJ0

V 2 T0 d V2 × δT (t) ≈ 0 ≈ dT R R0 R0



dR dT

 × T =T0

ΔT (t) ΔT (t) = PJ0 α(T0 ) , T0 T0

where α = T /R(dR/dT ) is the TES thermometric sensitivity, and R its resistance. Finally, subtracting term by term eq. (1) from eq. (2), and taking the first-order approximation, the pulse regime of the TES microcalorimeter is described by the equation (5)

dΔT 1 + dt C

  PJ0 α G+ δT = PR (t), T0

or (6)

dΔT + dt



1+L τ

 ΔT = PR (t),

where τ is the decay time constant of the heat pulse and L = (αPJ0 /GT0 ) is the electrothermal feedback (ETF) parameter. In the TES microcalorimeters L can achieve values as high as several hundreds. In this regime, which is called strong electrothermal feedback, the effective temperature transient becomes so small that the detector works almost at constant temperature. This improves linearity, dynamic range and response speed. Indeed, the effective time constant goes inversely proportional to L, for L  1, (7)

τeff =

τ 1+L

and becomes much smaller than the physical time constant τ = C/G. Because the strong electrothermal feedback forces the detector to work at constant temperature, the bias current changes in order to balance the power PR (t) produced by the primary energy release of the radiation. This current is typically measured with a low-noise SQUID galvanometer in series with the TES thermistor (see fig. 2). Actually, most of the approximations that have been done in the previous crude model of the microcalorimeter cannot be applied in practice, because of the complexity of thermal systems at this low temperatures and the strong dependence from the temperature of several thermodynamic quantities. As an example, a simple normal conducting metal film at the sub-kelvin temperatures behaves as two systems, respectively, of heat capacity Ce ∝ T of the conduction electron gas, and Cph ∝ T 3 of the phonons of the crystal lattice, which are connected by a thermal conductance Ge-ph ∝ T 5 . If a heat excess is produced in the electron gas, this flows to the heat sink through the series of Ge-ph , the phononphonon conductance GKapitza ∝ T 3 and Gph ∝ T 3 of a dielectric link. Therefore, a set of non-linear differential equations should be used for modelling the near-equilibrium thermal evolution of the microcalorimeter. Far out-of-equilibrium evolution needs dedicated models, including also Monte Carlo simulations, like in ballistic or quasidiffusive phonon

328

F. Gatti

Fig. 3. – Left: an example of a first modern microcalorimeter prototype (Genoa, 1995) made with a neutron transmutation doped germanium sensor, (Ge-NTD) 100 × 100 × 250 μm3 , with ultrasonically bonded Al wires at the opposite contact faces. This prototype achieved an energy resolution of about 30 eV FWHM at 5.9 keV. Right: a present (Genoa, 2004) Ir-Au Transition Edge Sensor, TES, 100 × 200 × 0.05 μm3 microcalorimeter onto a suspended membrane of 1 μm thick silicon nitride (Si3 N4 ). This was built with all thin metal film planar techniques. A gold radiation absorber (vertical bar) was grown on top. This prototype achieved an energy resolution of about 4 eV FWHM at 5.9 keV.

transport or in diffusion of high-energy quasiparticles. For a more detailed discussion, see ref. [11]. The cryogenic microcalorimeters are so attractive because the spectral resolutions are much higher than in any other energy-dispersive detector. A simple estimation of the intrinsic limit of the energy resolution is obtained by considering the microcalorimeter at the thermal equilibrium with the heat sink through a weak thermal link. Actually this is not the case, but it can be seen that this is a good approximation. The intrinsic limits in energy resolution are caused by the unavoidable temperature fluctuations in the microcalorimeter. These are determined by the Brownian motion of the phonons between the two bodies. If U is the internal energy, the corresponding average number of phonons is Nph  = (U/kT ) = (CT /kT ). Consequently, the r.m.s. energy fluctuations √ are ΔUr.m.s. = kT Nph and then ΔUr.m.s. = kT 2 C. It can be easily calculated that at T = 0.1 K, and C = 10−13 J/K, the r.m.s. energy noise ΔUr.m.s. is as small as 1 eV. A more detailed model that is based on the hypothesis of the steady state and includes the electrothermal feedback effect, gives the similar expression

(8)

√ ΔUr.m.s. = ζ kT 2 C,

with a correction parameter ζ that is a function of L, G, α and is smaller than 1 in conditions of strong electrothermal feedback. Examples of modern microcalorimeters are shown in fig. 3.

Calorimetric beta spectroscopy

329

3. – The calorimetric measurement of neutrino mass In 1980 Simpson reported the results of a measurement of the 3 H β-energy spectrum for antineutrino mass determination that was made with a Si(Li) X-ray detector into which a dose of tritium was implanted with a Van der Graff accelerator [12]. The motivation of this new approach lies in the necessity to examine with a different method the results on neutrino mass measurements with β magnetic spectrometer. After the claiming of finite neutrino mass that was made by the group of ITEP [13], it was pointed out that an incorrect estimation of the detector response function (see Bergkvist [14]) could simulate finite neutrino mass. The analysis of β spectra with resolution of tens of eV or better with an external source requires special and accurate calculations of the energy losses and its distribution. Energy losses of the β are due to inelastic scattering inside the source, that depends from the geometry and composition, but also to the so-called final-state interactions. The final states available to the decay have energies appropriate to the helium ion, in the 25–50 eV range, so that any precise measurement might take into account the probabilities of the various final states. In the conjecture of Simpson these final states should be automatically accounted for in a full absorption experiment with the source inside the detector. Here we analyze more deeply this experiment. First of all, a dose of about 13 3 10 H atoms/cm3 has been implanted in Si(Li) diode with energy between 8.0 and 9.1 MeV, corresponding to an implantation depth of 0.2 mm, that is large if compared to the range of 18.6 keV β particles and the absorption length of the Si K X-ray line and external bremsstrahlung. Then the probability of energy escaping the active volume of the detector was negligible. The 3 H implanted ions move by channelling inside the crystal and stop as neutral atoms in a well-defined site inside the tetragonal structure of the silicon lattice at about 0.2 ˚ A from the nearest Si atom. This can be assumed as initial state. The final state of the β transition is 3 He+ ion with one electron in 1s or 2s orbital. The transition to the ground state might follow two ways. A second electron fills the 1s orbital, relaxing the atoms in 1S0 ground state with a typical time scale of 10 ns. The 2s state is metastable in free atoms, but because of the mixing of 2s and 2p orbitals due to the screening effect of Si and the Stark effect, which is caused by the crystal electric field, it undergoes fast (≤ ns) decay to 1S with the emission of 58.4 nm photon. Finally it can be concluded that the excited final states decay within the charge collection time of the Si(Li)diode, which is about hundreds of ns. Further, the main de-excitation processes release several tens of eV. As a reference example, the decay from the electron configuration (1s)(2p) to the (1s)(1s) gives about 20 eV. Being the energy for electronhole pair creation w = 1.1 eV, these small-energy releases contribute to the total charge signal of the single β decay. For these reasons the Simpson experiment can be considered a calorimetric energy-dispersive measurement of the β decay, even if a charge mediated detector was used. The first proposals for a true calorimetric β spectroscopy with phonon-mediated detectors for neutrino mass measurement were made independently by McCammon [15]

330

F. Gatti

and Vitale [16]. In the first proposal, McCammon conceived a tritium-implanted monolithic Si microcalorimeter 0.5 × 0.5 mm2 of a total heat capacity of 10−15 J/K at 0.1 K. The expected energy resolution was calculated to be about 1 eV FWHM. In the proposal of Vitale it has been pointed out that the main disadvantages of the calorimetric technique, i.e. the impossibility of cutting out the non-interesting part of the spectrum, can be balanced by choosing the lowest Q value β isotope that is known in nature: 187 Re, whose Q is about 2.5 keV. This allows gaining a factor 400 in statistical sensitivity with respect to the tritium. The statistical sensitivity is calculated as the ratio of the end-point fraction sensitive to the neutrino mass over the whole spectrum itself: this factor scales as m3ν /Q3 . In Vitale’s proposal, the detector was conceived as a metallic Re cryogenic microcalorimeter with an expected energy resolution of about 2 eV FWHM. As pointed out by Bergkvist [14] the presence of non-defined final states gives rise to a smearing of the spectral shape at the end-point, at least, as wide as the distribution of excited levels. If we call, respectively, i , E0i and E0 the energy of the generic final state i, the corresponding end-point and the ground-to-ground end-point value of the transition, then the β spectrum can be written as follows: (9)

N (E) ∝



 (E0i − Ei ) (E0i − Ei )2 − m2ν ,

i

where (10)

E0i = E0 − i .

The term pEFS, that is approximately constant approaching the end-point, has been disregarded. As reference, the calculated excited levels i available for the transition T2 to HeT+ are more than 110 and cover an energy range of about 160 eV [17]. The effect of the sum in eq. (1) is the well-known “banana-like”-shaped Kurie plot at the end-point (see fig. 4, left). In an ideal calorimeter the releases i should be added to the β particle energy in a single event with energy (11)

Ec = Ei + i

and the calorimetric β spectrum becomes (12)

 N (Ec ) ∝ (E0 − Ec ) (E0 − Ec )2 − m2ν

In which (13)

E0 = E01 + 1 = E02 + 2 = . . . = E0i + i = . . . .

Thus, each β transition spectrum adds coherently to the others generating a ground-toground state calorimetric energy spectrum, which is shown in fig. 4, right.

331

Calorimetric beta spectroscopy

Fig. 4. – Left: simplified Kurie plot for a β transition with 3 excited states: the full spectrum has a typical banana-like feature at the end-point. Right: simplified Kurie plot of the same transition as measured with a calorimetric β spectrometer, in which all the 3 excited state spectra add coherently whith the same end-point.

4. – The case of a Re metal detector for studying

187

Re decay

Here we analyze the case of the cryogenic microcalorimeters with Re metal absorber that is one of the simplest chemical forms in which it can be prepared. The natural isotopic abundance of 187 Re is 63%. Since the beginning of the ’90s the group of the Genoa has undertaken the study of Re metal properties [18-20], showing that single crystals are at the same time suitable radiation absorbers and sources for cryogenic detectors operating around 0.1 K, at which they behave superconducting. The specific heat in the superconducting state approaches the one of dielectric materials, which allows building detectors with absorber masses of the order of mg, otherwise impossible to be achieved in normal conducting state. Another chemical form, the dielectric compound AgReO4 , has been studied by the group of Milan [21, 22], that found them similarly suitable for calorimetric applications. For the sake of simplicity, we focus the attention on the phenomenology of the β decay 187 of Re in Re metal absorber. However, most of the following considerations apply to other kinds of chemical forms. For many years the decay spectrum of 187 Re, a first forbidden unique transition, has been unknown because of the very low energy of the β particles (2.5 keV) in conjunction with the high atomic number Z = 75 and density ρ = 21 g/cm3 . Being the electron range of few hundreds of ˚ A, the escape probability from a solid sample is therefore negligible and any attempt to detect the products of the decay has been vain. Only in 1965 [23] and 1967 [24] two groups, using a gas proportional chamber filled with a Re volatile compound that is stable at 250◦ C, revealed the spectral shape, even if with a poor resolution of about 1 keV FWHM at 3 keV. They found E0 = 2.62 ± 0.09 and 2.65±0.04 keV, respectively. This measurement has been repeated in 1993 with the same method giving E0 = 2.70 ± 0.09 keV [25]. In Re metal microcalorimeter (see an example in fig. 5), the 187 Re decays to the ground level of neutral 187 Os76 atom in the Re crystal. The 187 Re75 end-point energy in

332

F. Gatti

Fig. 5. – Left: picture of a Re single-crystal microcalorimeter with germanium transmutation doped sensor on top built in Genoa. Centre and right: AgRe3 O4 crystal microcalorimeter built in Milan: front side with wire connections and back side with the crystal.

the crystal is related to one of the isolated isotopes (14)

E0,crystal = E0,isolated − (eΦ + EFermi ) − ΔBlattice ,

where (eΦ+EFermi ) is the electron binding energy in the crystal as a sum of the electronic work function, 5.1 eV, and the Fermi energy, 11.2 eV. ΔBlattice is the change in the potential energy of the isotope in the crystal due to the change of the nuclear charge by one unit. This lattice contribution is negligible: it corresponds to about 2.6% of the total binding energy of rhenium atom in the crystal, which has been evaluated to be 16.9 eV/atom. It is interesting to note that the Os electron cloud is more strongly bound than in Re by ΔBe = −13.77 keV. Therefore the difference of nuclear binding energies M (Os) + me c2 − M (Re) is about +11 keV, preventing the β decay to the continuum in the bare nucleus. The bare 187 Re75+ can only undergo bound state decay to 187 Os75+ , which has been observed in a storage ring having a 32 y half-life and 63 keV Q value [26]. Because the atomic binding energy is the leading term, the decay rate is strongly influenced by the EM fine-structure constant α, making the 187 Re one of the most sensitive probes for the EM coupling over a wide time scale comparable to the age of the universe [27]. It is worth noting that the microcalorimetric detectors are able to measure the relaxation of possible final excited states if their lifetimes are shorter than the heat pulse formation times, which have been measured to be about 10−5 s in fast detectors. However, an assessment of the final excited state energies and probabilities and other causes of energy losses is made in the following. Final excited states. In the course of the 187 Re decay, the β particles pass through the atom, that may not have the time to rearrange the electrons. As can be seen in table I, the atomic binding energy difference from Re to Os+ is very close to the one from Re to the neutral Os. Therefore, being the energy of the Os+ after the decay almost equal to the one of the ground state of Os, high excited final states are very unlikely. A provisional analysis of the possible atomic excited final states shows that, due to the very similar atomic wave functions and levels of Re75 and Os76 , the probability of transitions towards

333

Calorimetric beta spectroscopy

Table I. – Re and Os electronic configuration and the total atomic binding energies. 75 Re 76 Os+ 76 Os

Xe 4f 14 5d5 6s2 Xe 4f 14 5d6 6s1 Xe 4f 14 5d6 6s2

Etot = −429402.3 eV Etot = −443164.5 eV Etot = −443172.8 eV

an excited level is very small, being the Os excited eigenstates orthogonal to the Re ground state. An evaluation of this probability gives values lower than 7 × 10−5 . Then, the energy loss via long-living atomic excited state should be negligible. Lattice defects. The possibility of energy losses in the dislocations that are caused by the recoils of the daughters can be excluded. The energy of the recoils is lower than 8 meV, therefore, it is not sufficient to cause crystal defects, but only to create phonons belonging to the elastic branches, which contributes to the heat pulse formation. Recoil-free decay. Another process, that in principle could smear the position of the end-point, is the recoil-free β decay. This effect has not been observed until now, but it can be foreseen on the basis of the extension of the theory of the well-known Mossbauer effect to the β decay. In the case of recoil-free decay the energy of the neutrino-electron pairs is increased by an amount equal to the nucleus recoil. Since this exchanged energy is very small, the effect on the shape of the end-point region is negligible. Shake off. The shake off probability is at 1% level and involves the N and O shells that emit photons or Auger electron with an average energy of 50 eV. These are fully absorbed in much less than a thickness of 1 μm of Re metal. IB and EB. Inner and external bremsstrahlung generate photons with a maximum energy equal to Q, that have a larger penetration depth than the electrons, but however within few μm. Quasiparticle metastable states. Collective excitations in the crystal can also contribute to the generation of long-lived metastable states, which can trap a variable amount of energy for a long time. Because the rhenium crystal is operated well below the normal-to-superconducting transition temperature Tc = 1.69 K, long-living quasiparticle states are predicted by the models that extend the BCS theory to the systems out of the thermal equilibrium [28], as expected in the region of the β tracks. A dedicate set of measurements has shown that the thermalization efficiency, i.e., the fraction of the primary energy converted into heat in a short time, is 100% over a wide range of temperatures and decreases to lower, but non-vanishing values below 80 mK. In order to explain this behaviour, it has been supposed that at so low T /Tc the quasiparticles created in the narrow region of the track re-condense promptly in Cooper pairs before diffusing over the whole crystal volume, providing this unexpected full thermalization of the primary energy till below 0.1 K. Even if these measurements are biased by the specific choice of the sensor type (Ge-NTD) and the absorber geometry (Re crystal and foils), its general trend has been confirmed in other materials (Pb, Sn, Nb, Ti, Al) and indirectly by other groups. At the lowest temperatures, much less than 80 mK, long tails appear on the thermal pulses indicating a possible incomplete thermalization [29].

334

F. Gatti

In this case the possibility of intrinsic fluctuation caused by incomplete thermalization processes cannot be excluded a priori. 5. – First detector prototypes and pilot experiments Here we describe in detail examples of Re detectors, the measurement methods and the first results. The decay of 187 Re was observed for the first time with a cryogenic microcalorimeter with 660 eV FWHM energy resolution in 1992 by the group of Genoa [20]. After a few years spent in improving the detector [30], a spectrum with 30 eV FWHM resolution and 50 eV threshold has been achieved [31]. The first high-statistics calorimetric measurement has been realized later, in 1998. About 6 × 106 187 Re decays with energy threshold of 420 eV and energy resolution of about 96 eV FWHM have been acquired. The high statistics and good performance of the experiment allowed the measurement of the end-point energy and half-life, with an accuracy never obtained before [32]. In this first experiment a rhenium single crystal of 1.572 mg was used as absorber, with a β activity of about 1.1 Bq. The sensor was a neutron transmutation doped, NTD, germanium thermistor. Sensor and absorber have been connected with a small drop of epoxy. The microcalorimeter was suspended by two ultrasonic-bounded Al wires that provided both the electrical connections and the weak thermal link to the heat sink. During the measurements the refrigerator operated at the base temperature of 60 mK for an uninterrupted period of three months. The detector was thermally and radioactively shielded in a small box of low-activity copper and lead. Only a small hole with a Be window was used for the detector energy calibration with soft X-rays of an external calibration source. This was obtained with the fluorescence of Cl, Ca, Ti, and Va salts that were excited with a 50 μCi 55 Fe X-ray source. The monitor of the detector gain was provided by a weak 55 Fe X-ray at 5898 eV and 6490 eV with a count rate of about 10−2 Hz. Al and Be foils were used to filter out the low-energy emissions of the source itself in the range of interest below 3 keV. The stability of the detector calibration has been proven to be very good over periods of several days, so that such a low-activity source was sufficient for monitoring the energy calibration for periods of about one week during the entire data taking. These measurements led to the discovery of the influence of a crystalline structure on the β decay [33], as shown in fig. 6. This phenomenon, named beta environmental fine structure, BEFS, was hypothesized in 1991 [34]. It appears as an oscillatory modulation of the β spectrum of the order of 1%, whose parameters depend on the crystalline structure. This fine structure is caused by the interference of the outgoing β wave function with the reflected ones from the neighbouring atomic cores. The emitted β, whose wavelength changes from about 2 ˚ A at 10 eV, to about 0.02 ˚ A at 1 keV, moves away from the decaying atoms, expanding over several tens of ˚ A in the crystal. All the backscattered waves from the encountered atoms along their pathway travel back and interfere with each other at the site of the decaying nucleus. Therefore, for a finite coherence time, around the nucleus a complex electronic standing wave pattern is created with maxima and minima that depend on the wavelength. Therefore the amplitude of the electronic

335

Calorimetric beta spectroscopy

Fig. 6. – First observation of the fine structure of the beta spectrum (BEFS) in Re metal (Genoa, 1999): data and fit function.

final state of the β decay inside the crystal is modulated by the β energy itself. In general we can state that the general β decay in a solid should be corrected by the fine-structure term (15)

ξ(Ee ) =

 Ni fi (π) i

kRi

2 2

sin(2kRi + φi + 2δ0 )e−γRi e−2σi k ,

where the sum is over all neighbouring i-shells containing Ni atoms, fi (π) is the backward scattering amplitude for an electron of energy Ee and wave number k, γ is the inverse of the energy-dependent electron mean free path, Ri is the distance between the central decaying atom and the surrounding i-shell of atoms and σ accounts for the corrections of the thermal lattice motion occurring in the Debye-Waller term. This formula holds for electrons emitted in s-wave. A phase factor is needed to account for p-wave beta emission. The statistics of this first data are not sufficient for determining the phase factor. A first determination of the phase factor and consequently the s- and p-wave mixing has been done by the Milan group in 2005 [35]. In table II the parameters of the selected detectors built in Genoa are presented: improvements of about one order of magnitude of energy resolution have been achieved from Table II. – Parameters of typical Re metal calorimeters built in Genoa from 1998 to 2005. The resolutions are measured at 5.9 keV. Sensor Re (μg) C(sensor) pJ/K C(Re) pJ/K Calculated FWHM resolution Measured FWHM at 6 keV

Ge NTD 1572.3 3.6 3.7 48.3 96.0

Ge NTD 60.1 3.6 0.1 28.4 31.3

Ge NTD 210.3 1.8 0.5 33.2 37.2

Ir/Au TES 215.50 0.02 0.54 5.80 11.0

336

F. Gatti

Table III. – Parameters of typical AgReO4 calorimeters built in Milan for the experiment in 2002. Detector 1 2 3 4 5 6 7 8

AgReO4 mass (μg)

Toperating (K)

EFWHM (eV) at 1.5 keV

EFWHM (eV) at 2.6 keV

272 259 280 249 284 282 268 278

78.6 70.2 78.5 80.6 67.4 57.3 74.0 76.6

23.7 23.2 28.7 25.4 25.7 29.3 21.3 29.2

26.3 26.6 30.5 28.9 29.2 33.4 24.9 34.5

1998 to 2005. Further efforts are under way to achieve a spectral resolution of 2–5 eV. In 2002–2003 the group of Milan performed a high-statistics measurement with an array of 10 microcalorimeters with AgReO4 dielectric absorber. The AgReO4 absorbers were coupled to doped silicon thermistors. Even if the data from two detectors with poorer resolution were not included in the statistics, the effective total mass of the array was 2.174 mg, for a 187 Re total activity of 1.17 Hz. See table III for the details on the detector parameters. The total lifetime was 210 days, 42 of which have been devoted to the periodic calibrations while 168 days correspond to pure data acquisition. The total efficiency of this run was therefore of 54%. The calibrations were made with X-rays at 1.5, 2.6, 3.7, and 4.5 keV of excited sample of Al, Cl, Ca, and Ti, respectively. The calibrations were repeated periodically every 2 hours. The performance of the detectors was quite stable during the run. The FWHM resolution at 1.5 keV in the single-detector final spectra ranges from 21.3 to 29.3 eV; with an average of 25.5 eV. The 10% to 90% rise time of the 8 detectors was in the range 340–680 μs; with an average value of 492 μs. The FWHM resolution of the entire array extrapolated at the energy of the end-point at 2.46 keV was 28.5 eV [36-38]. In table IV the main results of the two first experiments of calorimetric beta spectroscopy are summarized.

Table IV. – Experiment, energy resolution, end-point energy, half-life, bound to neutrino mass of the pilot experiments in Genoa and Milan. Experiment Resolution-FWHM (eV) E0 (eV) τ1/2 (Gy) mν (eV/c2 )

MANU-1998

MiBeta-2003/04

96 2470 ± 1 ± 4 41.2 ± 0.2 ± 1.1 ≤ 25 95% C.L.

28.5 2465 ± 0.5 ± 1.6 43.2 ± 0.2 ± 0.1 ≤ 15 90% C.L.

337

Calorimetric beta spectroscopy

Fig. 7. – Left: an example of 64 microcalorimeters having 2 eV FWHM energy resolution that have been integrated in 8 × 8 array (Courtesy of GSFC-NASA). Rigth: simulated sensitivity on mν of 187 Re experiment (MARE) with 4 ×104 microcalorimeters vs. measurement live time with different detector parameters: energy resolution, time resolution and count rate per detector.

6. – Towards a sub-eV mν calorimetric experiment The sensitivity of a calorimetric experiment to the neutrino mass is related to the total statistics N and energy resolution ΔE  (16)

(mν )90%CL 0.9

E03 ΔE N

1/4 ,

where N = Aβ × tM , the β source activity-live time product. The activity and spectral resolution of 187 Re detectors are strictly connected to each other: high counting rates need high absorber masses and conversely high resolutions require instead small heat capacities and consequently small absorbers. In natural Re the ratio activity/mass is roughly 1 Bq/mg. The counting rate might be limited also by the maximum acceptable pile-up rate for achieving the wanted mass sensitivity, once the detector time resolution and the pile-up recognition capability of the analysis have been fixed. The trade off among these parameters can be met by using highly pixelated detectors. Each pixel can arrange a Re single crystal as absorber with mass up to few mg. The conceptual design of an experiment with sub-eV sensitivity has been discussed within the proposal MARE [39]. The present status of the integration technology for microcalorimetric detectors is such that 32× 32 pixels array of area of few cm2 and with spectral resolution of about 2 eV are being produced [40]. An experiment with 4 × 104 detectors that might be built with subarrays of 103 pixels can achieve the same sensitivities as the KATRIN experiment [41]. In fig. 7 are shown a prototype of an array of 8 × 8 detectors with 2 eV FWHM energy resolution and the expected sensitivity-live time plot of the 187 Re microcalorimeters experiment (MARE) with different detector parameters. Researches and developments are under way for fixing the main technological issues of the detector integration and readout. Further improvements of the detector performance

338

F. Gatti

Fig. 8. – Left: Calculated E.C. spectra for Q = 2150 and 2750 eV. Right: expected normalized deficit vs. mν of 187 Re and 163 Ho with Q = 2150 and 2800 eV.

are foreseen in the next years, thus allowing better sensitivity expectations. The E.C. decaying isotope 163 Ho is another attractive probe for finite neutrino mass, equally to 187 Re. Among several different methods that have been proposed in the past [42-45], the most suitable is the kink search at the end-point of the E.C. spectrum, which is

(17)

  dW ΓH /2π , = M 2 (Q − Ec ) (Q − Ec )2 − m2ν φ2H dEc (Ec − EH )2 + Γ2H /4 H

where Ec is the energy released in the electron capture decay, EH is the orbital binding energy, M is the nuclear matrix coefficient, φ2H is the H electron wave function amplitude on the nucleus, Γ is the linewidth. A first attempt of calorimetric measurement of 163 Ho spectrum has been made in 1997 at Genoa [46]. Nevertheless, the results were much better than the previous experiments, the final spectral resolution at the M1 capture line (2047 eV) was about 80 eV FWHM, because of the difficulties in synthesizing a homogenous absorber starting from a water solution of holmium chloride. A novel approach in 163 Ho filled absorber, which can be based on the production by proton activation and subsequent ion implantation in the absorber, might allow building high-spectral-resolution detectors. The main advantages of 163 Ho E.C. calorimetry are that the activity is roughly unconnected from the absorber mass, thus allowing the minimization of heat capacity, and that the spectrum is self-calibrated. A comparison of the merit factors, which are defined as the expected normalized deficit for a finite neutrino mass, is presented in fig. 8. These have been calculated for the minimum and maximum Q values found in the literature: 2150 eV and 2750, respectively. It can be concluded that calorimetric spectroscopy of 163 Ho should have theoretical sensitivities from a factor 2 better to a factor 1.5 poorer than in 187 Re, depending on the effective Q value.

Calorimetric beta spectroscopy

339

7. – Conclusion High-precision calorimetric spectroscopy of 187 Re and 163 Ho can achieve sensitivity in mν deep in the sub-eV region. The present status of cryogenic microcalorimeter technology allows to design an experiment with 0.2–0.3 eV sensitivity. Further developments that are under way might open new perspectives for further improvements in neutrino mass direct searches. REFERENCES [1] [2] [3] [4] [5] [6]

[7]

[8] [9] [10] [11] [12] [13] [14] [15] [16] [17] [18] [19] [20] [21] [22] [23] [24] [25] [26]

Chadwick J., Verh. Deutschen Phys. Ges., 16 (1914) 383. Rutherford E., Philos. Mag., 28 (1914) 305. Mitner L., Z. Phys., 9 (1922) 145. Bohr N., Convegno di Fisica Nucleare (Reale Accademia d’Italia, Roma) 1932, p. 119. Ellis C. D. and Wooster W. A., Proc. R. Soc. London, Ser. A, 117 (1927) 109. Pauli W., letter to L. Mitner and colleagues, Dec. 4th, 1930, in Wis. Brief. mit Bohr, Einstein, Heisenberg (Springer) 1985, p. 39. It is interesting to note that in a letter from Heisenberg to Pauli on Dec. 1st, 1930, there is an explicit reference to a neutral particle emitted in beta decay. These communications were done before the discovery of the neutron by Chadwick in 1932 (Nature, 129 (1932) 312) and the theory of nucleus made up of neutrons and protons by Ivanenko (Nature, 129 (1932) 798), Heisenberg (Z. Phys., 77 (1932) 1), Majorana (Z. Phys., 82 (1933) 137). Fermi E., Convegno di Fisica Nucleare (Reale Accademia d’Italia, Roma) 1932. Fermi referred to the Pauli particle as “neutrino” to distinguish it from the neutron newly discovered by Chadwick. Andrews D. H., Fowler R. D. and Williams M. C., Phys. Rev. A, 76 (1949) 157. Bandler S. R. et al., J. Low Temp. Phys., 151 (2008) 400. Doriese W. B. et al., J. Low Temp. Phys., 151 (2008) 754. Irwin K. D. and Hilton G. C., Cryogenic Particle Detection, Vol. 99 (Springer) 2005, p. 63. Simpson J. J. et al., Phys. Rev. D, 23 (1981) 649. Lubimov V. A. et al., Phys. Lett. B, 94 (1980) 266. Bergkvist K. E. et al., Phys. Lett. B, 154 (1985) 224. McCammon D. et al., 3rd Telemark Conference, Oct. 1984, AIP Conf. Proc. (1985). Vitale S. et al., Erice International School of Physics of Exotic Atoms, 1984, and Blasi A. et al., INFN Report, BE-85/2 (1985). Jonsell K. E. and Monkhorst H. J., Phys. Rev. Lett., 76 (1996) 4476. Gallinaro G., Gatti F. and Vitale S., Europhys. Lett., 14 (1991) 225. Gatti F., Vitale S. and Barabino A., Nucl. Instrum. Methods Phys. Res. A, 315 (1992) 260. Cosulich E. et al., Phys. Lett. B, 295 (1992) 143. Alessandrello A. et al., J. Phys. D., 32 (1999) 3099. Alessandrello A. et al., Phys. Lett. B, 457 (1999) 253. Brodzinski R. L. and Conway D. C., Phys. Rev. B, 138 (1965) 1368. Huster E. and Verbeek H., Z. Phys., 203 (1967) 435. Akshtorab K. et al., Phys. Rev. C., 47 (1993) 2954. Bosch F. et al., Phys. Rev. Lett., 77 (1996) 5190.

340

F. Gatti

[27] Olive K. A. et al., Phys. Rev. D, 69 (2004) 027701. Low-Q isotopes are the most sensitive to changes of the fine-structure constant α, being the relative variation of the decay rate (Δλ/λ) = 3(ΔQ/Q) large for small Q. If 187 Re were incorporated into a meteorite in the early Solar System, the present abundance of 187 Os in the meteorite is 187 Ospres = 187 Osinit + 187 Repres [exp(−λ187 t) − 1], where λ187 is the time-averaged decay rate for 187 Re and t the meteorite age. Independent determinations of meteorite age allow to measure λ187 over about 5 Gy and then (Δα/α)  5 × 10−5 (Δλ/λ). [28] Kaplan S. B. et al., Phys. Rev. B, 14 (1976) 4854. [29] Cosulich E., Gatti F. and Vitale S., J. Low Temp. Phys., 93 (1993) 263. [30] Cosulich E. et al., Nucl. Phys. A, 529 (1995) 59. [31] Gatti F., in 7th International Workshop on Neutrino Telescopes, edited by M. Baldo Ceolin (1997) 141. [32] Galeazzi M. et al., Phys. Rev. C, 63 (2000) 014302. [33] Gatti F. et al., Nature, 397 (1999) 137. [34] Koonin S. E., Nature, 354 (1991) 468. [35] Arnaboldi C. et al., Phys. Rev. Lett., 96 (2006) 042503. [36] Arnaboldi C. et al., Phys. Rev. Lett., 91 (2003) 161802. [37] Sisti M. et al., Nucl. Instrum. Methods Phys. Res., 520 (2004) 125. [38] Nucciotti A. et al., Nucl. Instrum. Methods Phys. Res., 520 (2004) 148. [39] Gatti F. et al., MARE Proposal, http://www.ge.infn.it/∼numass. [40] Kelley R. et al., GFSC-NASA, private communication. [41] Weinheimer C., this volume, p. 215. [42] De Rujula A. et al., Nucl. Phys. B., 114 (1981) 488. [43] Yasumi S. et al., Phys. Lett. B., 334 (1994) 229. [44] De Rujula A. and Lusignoli M., Nucl. Phys. B., 219 (1983) 277. [45] De Rujula A. and Lusignoli M., Phys. Lett., 9 (1982) 429. [46] Gatti F. et al., Phys. Lett. B, 398 (1997) 415.

DOI 10.3254/978-1-60750-038-4-341

Leptogenesis A. Riotto CERN, Theory Division - Geneva 23, CH-1211, Switzerland

Summary. — We summarize the state of the art of the theory of thermal leptogenesis according to which the baryon asymmetry in the Universe is produced at very high temperatures from the decay of heavy right-handed neutrinos. The same heavy states might be responsible through the see-saw mechanism of the lightness of the left-handed neutrinos. This opens up the possibility that measuring the low-energy neutrino parameters would lead to know something about the primordial Universe.

1. – Introduction The symmetry between particles and antiparticles, firmly established in collider physics, naturally leads to the question of why the observed universe is composed almost entirely of matter with little or no primordial antimatter. Outside of particle accelerators, antimatter can be seen in cosmic rays in the form of a few antiprotons, present at a level of around 10−4 in comparison with the number of protons. However, this proportion is consistent with secondary antiproton production through accelerator-like processes, p + p → 3p + p¯, as the cosmic rays stream towards us. Thus there is no evidence for primordial antimatter in our galaxy. Also, if matter and antimatter galaxies were to coexist in clusters of galaxies, then we would expect there to be a detectable background of γ-radiation from nucleon-antinucleon annihilations within c Societ`  a Italiana di Fisica

341

342

A. Riotto

the clusters. This background is not observed and so we conclude that there is negligible antimatter on the scale of clusters. More generally, if large domains of matter and antimatter exist, then annihilations would take place at the interfaces between them. If the typical size of such a domain was small enough, then the energy released by these annihilations would result in a diffuse γ-ray background and a distortion of the cosmic microwave radiation, neither of which is observed. A careful numerical analysis of this problem demonstrates that the universe must consist entirely of either matter or antimatter on all scales up to the Hubble size. It therefore seems that the universe is fundamentally matter-antimatter asymmetric. While the above considerations put an experimental upper bound on the amount of antimatter in the universe, strict quantitative estimates of the relative abundances of baryonic matter and antimatter may also be obtained from the standard cosmology. The baryon number density does not remain constant during the evolution of the universe, instead scaling like a−3 , where a is the cosmological scale factor [1]. It is therefore convenient to define the baryon asymmetry of the universe in terms of the quantity (1)

YB ≡

nB , s

where nB = nb − n¯b is the difference between the number of baryons and antibaryons per unit volume and s = (2π 2 /45)g is the entropy density at temperature T when the thermal plasma contained g relativistic degrees of freedom. The observed baryon asymmetry of the Universe is now accurately determined by Cosmic Microwave (CMB) Anisotropy measurements [2] (2)

YBCMB = (8.75 ± 0.23) × 10−11 .

The physics behind the connection behind the determination of YB and the CMB anisotropy would require another set of lectures. It suffices to say that the baryon number plays a crucial role in determining the relative amplitude of the even peaks to the odd ones. Measuring this ratio gives a determination of the baryon asymmetry of the Universe [3]. Primordial nucleosynthesis (for a review see [4]) is also one of the most powerful predictions of the standard cosmological model. The theory allows accurate predictions of the cosmological abundances of all the light elements, H, 3 He, 4 He, D, B and 7 Li, while requiring only the single input parameter YB which has been constant since nucleosynthesis. The range of YB consistent with nucleosynthesis agrees with the one provided by CMB anisotropies, even though they are relevant on various ranges of temperatures, about MeV for nucleosinthesis and a fraction of eV for the CMB anisotropies. To see that the standard cosmological model cannot explain the observed value of YB , suppose that initially we start with YB = 0 [5,6]. We can compute the final number density of nucleons b that are left over after annihilations have frozen out. At temperatures T  1 GeV the equilibrium abundance of nucleons and antinucleons is [1] (3)

 m 3/2 mp n¯ nb p

b e− T . nγ nγ T

343

Leptogenesis

When the universe cools off, the number of nucleons and antinucleons decreases as long as the annihilation rate Γann nb σA v is larger than the expansion rate of the universe 1/2 T 2 . The thermally averaged annihilation cross-section σA v is of the H 1.66 g M P order of m2π , so at T 20 MeV, Γann H, and annihilations freeze out, nucleons and antinucleons being so rare that they cannot annihilate any longer. Therefore, from (3) we obtain (4)

nb n¯

b 10−18 , nγ nγ

which is much smaller than the value required by nucleosynthesis. In conclusion, in the standard cosmological model there is no explanation for the value of the observed baryon asymmetry, if we start from YB = 0. An initial asymmetry may be imposed by hand as an initial condition, but this would violate any naturalness principle. Rather, the guiding principle behind modern cosmology is to attempt to explain the initial conditions required by the standard cosmology on the basis of quantum field theories of elementary particles in the early universe. In this context, the generation of the observed value of YB is referred to as baryogenesis. The goal of this lecture is to present the thermal leptogenesis scenario. As we shall see, it is strictly related to neutrino physics, the main subject of this School. As such, one would hope, through low-energy neutrino measurements, to open a window on the early Universe dynamics. For more details about the subject, the reader is forwarded to the excellent recent review of the subject [7]. Other useful reviews are [5, 6]. A note about our conventions. Throughout we use a metric with signature +2 and, unless explicitly stated otherwise, we employ units such that  = c = k = 1. The review is laid out as follows. In sect. 3 we provide some usful cosmological tools, in sect. 4 we discuss the out-of-equilibroum decay scenario, while sects. 5 and 6 are devoted to leptogenesis. Section 7 contains our conclusions. 2. – The Sakharov criteria A small baryon asymmetry YB may have been produced in the early universe if three necessary conditions are satisfied [8]: i) baryon number (B) violation; ii) violation of C (charge conjugation symmetry) and CP (the composition of parity and C) and iii) departure from thermal equilibrium. The first condition should be clear since, starting from a baryon-symmetric universe with YB = 0, baryon number violation must take place in order to evolve into a universe in which YB does not vanish. The second Sakharov criterion is required because, if C and CP are exact symmetries, then one can prove that the total rate for any process which produces an excess of baryons is equal to the rate of the complementary process which produces an excess of antibaryons and so no net baryon number can be created. That is to say that the thermal average of the baryon number operator B, which is odd under both C and CP , is zero unless those discrete symmetries are violated. CP violation is present either if there are complex phases in the Lagrangian which cannot be reabsorbed by field redifinitions (explicit breaking) or

344

A. Riotto

if some Higgs scalar field acquires a VEV which is not real (spontaneous breaking). We will discuss this in detail shortly. Finally, to explain the third criterion, one can calculate the equilibrium average of B (5)

BT = Tr(e−βH B) = Tr[(CP T )(CP T )−1 e−βH B] = Tr[e−βH (CP T )−1 B(CP T )] = − Tr(e−βH B),

where we have used that the Hamiltonian H commutes with CP T . Thus BT = 0 in equilibrium and there is no generation of net baryon number. Of the three Sakharov conditions, baryon number violation and C and CP violation may be investigated only within a given particle physics model, while the third condition —the departure from thermal equilibrium— may be discussed in a more general way, as we shall see. Let us discuss the Sakharov criteria in more detail. . 2 1. Baryon number violation. . 2 1.1. B-violation in Grand Unified Theories. Grand Unified Theories (GUTs) describe the fundamental interactions by means of a unique gauge group G which contains the Standard Model (SM) gauge group SU (3)C ⊗ SU (2)L ⊗ U (1)Y . The fundamental idea of GUTs is that at energies higher than a certain energy threshold MGUT , the group symmetry is G and that, at lower energies, the symmetry is broken down to the SM gauge symmetry, possibly through a chain of symmetry breakings. The main motivation for this scenario is that, at least in supersymmetric models, the (running) gauge couplings of the SM unify at the scale MGUT 2 × 1016 GeV, hinting at the presence of a GUT involving a higher symmetry with a single gauge coupling. Baryon number violation seems very natural in GUTs. Indeed, a general property of these theories is that the same representation of G may contain both quarks and leptons, and therefore it is possible for scalar and gauge bosons to mediate gauge interactions among fermions having different baryon number. However, this alone is not sufficient to conclude that baryon number is automatically violated in GUTs, since in some circumstances it is possible to assign a baryonic charge to the gauge bosons in such a way that at each boson-fermion-fermion vertex the baryon number is conserved. In the particular case of the gauge group SU (5), it turns out that among all the scalar and gauge bosons which couple only to the fermions of the SM, five of them may give rise to interactions which violate the baryon number. The fermionic content of SU (5) is the same as that of the SM. Fermions are assigned to the reducible representation 5f ⊕ 10f as 5f = {dcL , L } and 10f = {QL , ucL , ecL }. In addition, there are 24 gauge bosons which belong to the adjoint representation 24V and which may couple to the fermions through the couplings (6)

√   (g/ 2)24V (5f )† (5f ) + (10f )† 10f .

Because of this structure, the gauge bosons XY with SM gauge numbers (3, 2, −5/6) may undergo baryon-number-violating decays. While in the gauge sector of SU (5) the structure is uniquely determined by the gauge group, in the Higgs sector the results

345

Leptogenesis

depend upon the choice of the representation. The Higgs fields which couple to the fermions may be in the representation 5H or in the representations 10H , 15H , 45H and 50H . If we consider the minimal choice 5H , we obtain (7)

hU (10f )T (10f )5H + hD (5f )T (10f )5H ,

where hU,D are complex matrices in the flavor space. The representation 5H contains the Higgs doublet of the SM, (1, 2, 1/2) and the triplet H3 = (3, 1, −1/3) which is Bviolating. Note that each of these bosons have the same value of the charge combination (B − L), which means that this symmetry may not be violated in any vertex of SU (5). However, if we extend the fermionic content of the theory beyond that of minimal SU (5), we allow the presence of more heavy bosons which may violate B and even (B − L). In GUTs based on SO(10), for instance, there exists a fermion which is a singlet under the SM gauge group, carries lepton number L = −1, and is identified with the right-handed antineutrino. However, this choice for the lepton number assignment leads to no new gauge boson which violates (B −L). As we mentioned, the generation of a baryon asymmetry requires C violation. Since SO(10) is C-symmetric, the C symmetry must be broken before a baryon asymmetry may be created. If SO(10) breaks down to SU (2)L ⊗ SU (2)R ⊗ SU (4) via the nonzero expectation value of a Higgs field in the 54H representation, the C symmetry is not broken until U (1)B−L is broken at the scale MB−L . In this case, the right-handed neutrino acquires a Majorana mass MN = O(MB−L ) and its out-of-equilibrium decays may generate a nonvanishing (B − L) asymmetry [9]. . 2 2. B-violation in the electroweak theory. – It is well known that the most general Lagrangian invariant under the SM gauge group and containing only color singlet Higgs fields is automatically invariant under global Abelian symmetries which may be identified with the baryonic and leptonic symmetries. These, therefore, are accidental symmetries and as a result it is not possible to violate B and L at tree-level or at any order of perturbation theory. Nevertheless, in many cases the perturbative expansion does not describe all the dynamics of the theory and, indeed, in 1976 ’t Hooft realized that nonperturbative effects (instantons) may give rise to processes which violate the combination (B + L), but not the orthogonal combination (B − L). The probability of these processes occurring today is exponentially suppressed and probably irrelevant. However, in more extreme situations —like the primordial universe at very high temperatures— baryonand lepton-number-violating processes may be fast enough to play a significant role in baryogenesis. Let us have a closer look. At the quantum level, the baryon and the lepton symmetries are anomalous  (8)

μ ∂ μ jB = ∂μ jLμ = nf

 g2 g 2 a ˜ aμν ˜ μν , W − F W F μν 32π 2 μν 32π 2

where g and g  are the gauge couplings of SU (2)L and U (1)Y , respectively, nf is the ˜ μν = (1/2)μναβ Wαβ is the dual of the SU (2)L field strength number of families and W tensor, with an analogous expression holding for F˜ . To understand how the anomaly

346

A. Riotto

is closely related to the vacuum structure of the theory, we may compute the change in baryon number from time t = 0 to some arbitrary final time t = tf . For transitions between vacua, the average values of the field strengths are zero at the beginning and the end of the evolution. The change in baryon number may be written as (9)

ΔB = ΔNCS ≡ nf [NCS (tf ) − NCS (0)].

where the Cherns-Simon number is defined to be    g2 2 3 ijk d x Tr Ai ∂j Ak + igAi Aj Ak . (10) NCS (t) ≡ 32π 2 3 Although the Chern-Simons number is not gauge invariant, the change ΔNCS is. Thus, changes in Chern-Simons number result in changes in baryon number which are integral multiples of the number of families nf . Gauge transformations U (x) which connect two degenerate vacua of the gauge theory may change the Chern-Simons number by an integer n, the winding number. If the system is able to perform a transition from the (n) (n±1) vacuum Gvac to the closest one Gvac , the Chern-Simons number is changed by unity and ΔB = ΔL = nf . Each transition creates 9 left-handed quarks (3 color states for each generation) and 3 left-handed leptons (one per generation). However, adjacent vacua of the electroweak theory are separated by a ridge of configurations with energies larger than that of the vacuum. The lowest energy point on this ridge is a saddle point solution to the equations of motion with a single negative eigenvalue, and is referred to as the sphaleron. The probability of baryon-number-nonconserving processes at zero temperature has been computed by ’t Hooft and is highly suppressed by a factor exp[−4π/αW ], where αW = g 2 /4π. This factor may be interpreted as the probability of making a transition from one classical vacuum to the closest one by tunneling through an energy barrier of height ∼ 10 TeV corresponding to the sphaleron. On the other hand, one might think that fast baryon-number-violating transitions may be obtained in physical situations which involve a large number of fields. Since the sphaleron may be produced by collective and coherent excitations containing ∼ 1/αW quanta with wavelength of the order of 1/MW , one expects that at temperatures T  MW these modes essentially obey statistical mechanics and the transition probability may be computed via classical considerations. Analogously to the case of zero temperature and since the transition which violates the baryon number is sustained by the sphaleron configuration, the thermal rate of baryon number violation in the broken phase is proportional to exp[−S3 /T ], where S3 is the three-diemensional action computed along the sphaleron configuration, (11)

S3 = Esp (T ) ≡ (MW (T )/αW )E,

with the dimensionless parameter E lying in the range 3.1 < E < 5.4 depending on the Higgs mass. The prefactor of the thermal rate reads  (12)

Γsp (T ) = μ

MW αW T

3 4 MW

  Esp (T ) , exp − T

347

Leptogenesis

where μ is a dimensionless constant. Although the Boltzmann suppression in (12) appears large, it is to be expected that, when the electroweak symmetry becomes restored at a temperature of around 100 GeV, there will no longer be an exponential suppression factor. Although calculation of the baryon-number-violating rate in the high-temperature unbroken phase is extremely difficult, a simple estimate is possible. The only important scale in the symmetric phase is the magnetic screening length given by ξ = (αW T )−1 . Thus, on dimensional grounds, we expect the rate per unit volume of sphaleron events to be (13)

Γsp (T ) = κ(αW T )4 ,

with κ another dimensionless constant. The rate of sphaleron processes can be related to the diffusion constant for Chern-Simons number by a fluctuation-dissipation theorem. In almost all numerical calculations of the sphaleron rate, this relationship is used and what is actually evaluated is the diffusion constant. The first attempts to numerically estimate κ in this way yielded κ ∼ 0.1–1, but the approach suffered from limited statistics and large volume systematic errors. Nevertheless, more recent numerical attempts found approximately the same result. However, these approaches employ a poor definition of the Chern-Simons number which compromises their reliability. This simple scaling argument leading to (13) is not correct, however. Damping effects 5 in the plasma suppress the rate by an extra power of αW to give Γsp ∼ αW T 4 . Indeed, 2 since the transition rate involves physics at soft energies g T that are small compared to the typical hard energies ∼ T of the thermal excitations in the plasma, the simplest way of analyzing the problem is to consider an effective theory for the soft modes, where the hard modes have been integrated out, and to keep the dominant contributions, the so-called hard thermal loops. It is the resulting typical frequency ωc of a gauge field configuration immersed in the plasma and with spatial extent (g 2 T )−1 that determines the change of baryon number per unit time and unit volume. This frequency ωc has been estimated to be ∼ g 4 T when taking into account the damping effects of the hard modes. Using the effective dynamics of soft nonAbelian gauge fields at finite temperature, one 5 can find that Γsp ∼ αW T 4 ln(1/αW ). Lattice simulations with hard thermal loops seem 5 4 to indicate the Γsp ∼ 30αW T 4 , which is not far from αW T 4. 3. – Some necessary notions of cosmology and equilibrium thermodynamics . 3 1. Expansion rate, number density, and entropy. – Before launching ourselves into the issue of baryon asymmetry production in the early Universe, let us just remind the reader a few notions about thermodynamics in an expanding Universe that will turn out to be useful in the following [1, 3]. According to general relativity, the space-time evolution is determined via the Einstein equation by the matter content of the Universe, which differs from epoch to epoch depending on what kind of energy dominates the energy density of the Universe at that time. There are three important epochs characterized by different relations between the energy density ρ and the pressure p: 1) vacuum energy

348

A. Riotto

dominance with p = −ρ, 2) massless (relativistic) particle dominance with p = ρ/3 and 3) nonrelativistic particle dominance with p ρ. The Einstein equation reads (14)

1 Rμν − gμν R = 8πGN Tμν , 2

where Rμν is the Ricci tensor, R is the Ricci scalar, gμν is the metric, GN = MP−2 = (1.2 × 1019 )−2 GeV−2 is the Newton constant and Tμν is the stress-energy tensor. With the homogeneity and isotropy of the three space, the Einstein equation is much simplified with the Robertson-Walker metric (15)

ds2 = dt2 − a2 (t)x2 ,

where a(t) is the cosmic scale factor and the stress-energy tensor is reduced to Tμν = −pgμν + (p + ρ)uμ uν . Here uμ is the velocity vector which in the rest frame of the plasma reads uμ = (1, 0) and has the property uμ uμ = 1. The (0 − 0) component of eq. (14) becomes the so-called Friedmann equation (16)

H2 +

k 8πGN ρ, = 2 a 3

where k can be chosen to be +1, −1 or 0 for spaces of constant positive, negative or zero spatial curvature, respectively, and we have defined the Hubble parameter H≡

(17)

a˙ , a

which measures how fast the Universe is expanding during the different stages of its evolution. The μ = 0 component of the conservation of the stress-energy tensor (T;νμν = 0) gives the first law of thermodynamics in the familiar form (18)

d(ρa3 ) = −p d(a3 ),

that is, the change in energy in a comiving volume element, d(ρa3 ) is equal to minus the pressure times the change in volume, p d(a3 ). For a simple equation of state p = wρ, where w is independent of time, the energy density evolves like ρ ∝ a−3(1+w) . Examples of interest include radiation (ρ ∝ a−4 ), matter (ρ ∝ a−3 ), vacuum energy (ρ ∝ constant). The time behaviour of the scale factor a(t) then is : (19)

1) a ∝ e

Ht

,

2) a ∝ t1/2 , 3) a ∝ t2/3 .

H=

8πV , 3MP2

349

Leptogenesis

The first stage is the inflationary epoch where the constant vacuum energy V gives the exponential growth of the scale factor, which is believed to solve the horizon and the flatness problems of the standard Big-Bang theory of cosmology (for a review, see [10]). Of great importance is the transient stage from inflation to radiation dominance. This epoch is called reheating after inflation and we shall come back to it later in these lectures. What is relevant for us is that the early Universe was to a good approximation in thermal equilibrium at temperature T [1] and we can define the equilibrium number density nEQ X of a generic interacting species X as nEQ X =

(20)

gX (2π)3

 fEQ (p, μX ) d3 p,

where gX denotes the number of degrees of freedom of the species X and the phase space occupancy fEQ is given by the familiar Fermi-Dirac or Bose-Einstein distributions fEQ (p, μX ) = [exp[(EX − μX )/T ] ± 1] ,

(21)

where EX = (p2 + m2X )1/2 is the energy, μX is the chemical potential of the species and +1 pertains to the Fermi-Dirac species and −1 to the Bose-Einstein species. In the relativistic regime T  mX , μX formula (20) reduces to nEQ X =

(22)

⎧ ⎨(ζ(3)/π 2 )gX T 3

(Bose),

⎩(3/4)(ζ(3)/π 2 )gX T 3

(Fermi),

where ζ(3) 1.2 is the Riemann function of 3. In the nonrelativitic limit, T mX , the number density is the same for Bose and Fermi species and reads  nEQ X = gX

(23)

mX T 2π

3/2

e−

mX T

+

μX T

.

It is also important to define the number density of particles minus the number density of antiparticles (24)

nEQ X

−

nEQ X

 gX = fEQ (p, μX )d3 p − (μX ↔ −μX ) (2π)3 ⎧      ⎨ gX T23 π 2 μX + μX 3 , 6π T T = ⎩2g (m T /2π)3/2 sinh(μ /T ) exp[−m /T ], X X X X

(T  mX ), (T mX ).

Notice that, in the relativistic limit T  mX , this difference scales linearly for T  μX . This means that detailed balances among particle number asymmetries may be expressed in terms of linear equations in the chemical potentials.

350

A. Riotto

We can similarly define the equilibrium energy density ρEQ X of a species X as  gX E fEQ (p)d3 p, (25) ρEQ = X (2π)3 which reads in the relativistic limit ⎧ ⎨(π 2 /30)gX T 4 = (26) ρEQ X ⎩(7/8)(π 2 /30)gX T 4

(Bose), (Fermi).

Since the energy density of a nonrelativistic particle species is exponentially smaller than that of a relativisitic species, it is a very convenient approximation to include only relativistic species with energy density ρR in the total energy density ρ of the Universe at temperature T π2 g T 4 , 30

ρ ρR =

(27)

where g counts the total number of effectively massless degrees of freedom of the plasma (28)

g =



 gi

i=Bose

4

Ti T

7 + 8





gi

i=Fermi

Ti T

4 .

Here Ti denotes the effective temperature of any species i (which might be decoupled from the thermal bath at temperature T ). In the rest of these lectures we will be always concerned with temperatures higher than about 100 GeV. At these temperatures, all the degrees of freedom of the standard model are in equilibrium and g is at least equal to 106.75. From this expression, we derive that, when the energy density of the Universe was dominated by a gas of relativistic particles, ρ ∝ a−4 ∝ T 4 and, therefore [1] T ∝ a−1 .

(29)

Assuming that during the early radiation-dominated epoch (t  4 × 1010 s), the scale factor scales like tα , where α is a constant, the Hubble parameter scales like t−1 ∝ T 2 ∝ a−2 . This means that the scale factor a(t) scales like t1/2 and we recover 2) of eq. (19). More precisely, the expansion rate of the Universe H is [1]  (30)

H=

1/2

8π ρ 3MP2

1/2

1.66 g

T2 . MP

Using the fact that H = (1/2t) and eq. (30), we can easily relate time and temperature as (31)

t 0.301

MP 1/2

g T 2



T MeV

−2 s.

351

Leptogenesis

Another quantity that will turn out to be useful in the following is the entropy density. Throughout most of the history of the Universe, local thermal equilibrium is attained and the entropy in a comoving volume element s remains constant. Since it is dominated by the contribution of relativisitic particles, to a very good approximation (32)

s=

2π 2 g∗S T 3 , 45



3

where (33)

g∗S =

 i=Bose

gi

Ti T

7 + 8

 i=Fermi

 gi

Ti T

3 .

For most of the history of the Universe, however, all the particles have the same temperature and we can safely replace g∗S with g . Notice that the conservation of entropy implies that s ∝ a−3 and therefore g∗S T 3 a3 remains a constant as the Universe expands. This means that the number of some species X in a comoving volume NX ≡ a3 nX is proportional to the number density of that species divided by s, NX ∝ nX /s. . 3 2. Local thermal equilibrium and chemical equilibrium. – So far we have been using the fact that, throughout most of the history of the Universe, thermal equilibrium was attained. The characteristic time τX for particles of a species X with respect to the process X + A · · · → C + D + · · · is defined by the rate of change of the number of particles per unit volume nX due to this process:   dnX 1 1 (34) =− . τX nX dt X+A···→C+D+··· In the early Universe, if τX is smaller than the characteristic time of the expansion H −1 , then there is enough time for the process to occur and the particles X’s are said to be thermally coupled to the cosmic fluid. By contrast, if τX  H −1 , for every process in which the particles X’s are involved, then they are not in thermal equilibrium and they are said to be decoupled. In order to analyze the evolution of the particle populations which constitute the cosmic fluid, it is necessary to compare H −1 with τX at different temperatures. This is done through the Boltzmann equation, which, in an expanding Universe, reads  1 d 3 (a nX ) = πX C[fX ], (35) a3 dt where C is the collision operator. Equation (35) may be rewritten as   dnX π f fm · · · (1±fX )(1±fj ) · · · W (+m+· · · → X +j +· · · ) +3HnX = (36) dt j,,m,···

−fX fj · · · (1 ± f )(1 ± fm ) · · · W (X + j + · · · →  + m + · · · ) ,

352

A. Riotto

where π ≡ πX πj · · · π πm · · · , πi = (2π)−3 gi (d3 p/2Ei ) is the volume element in the phase space, W is the matrix element of the given process and (+) applies to bosons and (−) to fermions. The second term on the left-hand side of eq. (36) accounts for the nX diluition due to the cosmic expansion and the right-hand side accounts for the nX variations due to any elemenatry process X +j +· · · → +m+· · · in which the X particles are involved. As it stands, eq. (36) is rather formidable and complicated, but some approximations can be made to transform it in a simpler form. Let us consider, for example, a process like X + f → X  + f , where the number of X particles does change in the scatterings and let us also suppose that the f particles are light (T  mf ) and that the corresponding population is in thermal equilibrium. In the case in which the X distribution function is described by a Maxwell-Boltzmann distribution, i.e. the X particles are in equilibrium at temperatures smaller than mX , it is easy to see that the right-hand side of eq. (36) may be expressed in the form (37)

 S, r.h.s. of eq. (36) = − nX − nEQ X

where  (38)

S=

πf Ef ffEQ σ(X + f → X  + f )



nEQ f σ(X + f → X + f )v.

The notation σv stands for the thermal-average cross-section times the relative velocity −1 = ΓX associated to the elastic process is therefore v. The inverse time scale τX (39)

−1 

nEQ ΓX = τX f σ(X + f → X + f )v.

From these very simple considerations, we may conclude that the X degrees of freedom are in thermal equilibrium if (40)

 ΓX nEQ f σ(X + f → X + f )v  H

(thermal equilibrium is attained).

Departure from thermal equilibrium is expected whenever a rate crucial for mantaining thermal equilibrium becomes smaller than the expansion rate, ΓX  H. Another useful concept is that of chemical equilibrium. In general, a species X is in chemical equilibrium if the inelastic scatterings which change the number of X particles in the plasma, X + j →  + m, have a rate Γinel larger than the expansion rate of the Universe. In such a case, one is allowed to write down a relation between the different chemical potentials μ’s, (41)

μX + μj = μ + μm ,

of the particles involved in the process. With these simple notions in mind, we may start our voyage towards the country of baryogenesis. According to one of Sakharov’s criteria,

353

Leptogenesis

if all the particles in the Universe remained in thermal equilibrium, then no preferred direction for time may be defined and the CP T invariance would prevent the appearance of any baryon excess, making the presence of CP -violating interactions irrelevant. Let us indeed suppose that a certain species X with mass mX is in thermal equilibrium at temperatures T mX . Its number density will be given by (42)

nX gX (mX T )3/2 e−

mX T

+

μX T

,

where μX is the associated chemical potential. As we have mentioned, a species X is in chemical equilibrium if the inelastic scatterings which change the number of X particles in the plasma, X + A → B + C, have a rate Γinel larger than the expansion rate of the Universe. In such a case, one can write down a relation among the different chemical potentials of the particles involved in the process (43)

μX + μA = μB + μC .

In this way the number density in thermal equilibrium of the antiparticle X (mX = mX¯ ) is (44)

nX¯ gX (mX T )3/2 e−

mX T

−

μX T

,

where we have made use of the fact that μX¯ = −μX because of the process (45)

XX → γγ,

and μγ = 0. If the X particle carries baryon number, then B will get a contribution from (46)

B ∝ nX − nX¯ = 2gX (mX T )3/2 e−

mX T

sinh

μ  X

T

.

The crucial point is now that, if X and X undergo B-violating reactions, as required by the first Sakharov condition, (47)

XX → XX,

then μX = 0 and the relative contribution of the X particles to the net baryon number vanishes. Only a departure from thermal equilibrium can allow for a finite baryon excess. 4. – The standard out-of-equilibrium decay scenario Out of the three Sakharov’s conditions, the baryon number violation and C and CP violation may be investigated thoroughly only within a given particle physics model, while the third condition —the departure from thermal equilibrium— may be discussed in a more general way. Very roughly speaking, the various models of baryogenesis that

354

A. Riotto

have been proposed so far fall into two categories [5]: – models where the out-of-equilibrium condition is attained thanks to the expansion of the Universe and the presence of heavy decaying particles; – models where the departure from thermal equilibrium is attained during the phase transitions which lead to the breaking of some global and/or gauge symmetry. In this lecture we will analyse the first category, the standard out-of-equilibrium decay scenario [1]. . 4 1. The conditions for the out-of-equilibrium decay scenario. – It is obvious that in a static Universe any particle, even very weakly interacting, will attain sooner or later thermodynamical equilibrium with the surroinding plasma. The expansion of the Universe, however, introduces a finite time scale, τU ∼ H −1 . Let suppose that X is a baryon-number-violating superheavy boson field (vector or scalar) which is coupled to 1/2 lighter fermionic degrees of freedom with a strength αX (either a gauge coupling αgauge or a Yukawa coupling αY ). In the case in which the couplings are renormalizable, the decay rate ΓX of the superheavy boson may be easily estimated to be (48)

ΓX ∼ αX MX ,

where MX is the mass of the particle X. In the opposite case in which the boson is a gauge singlet scalar field and it only couples to light matter through gravitational interactions —this is the case of singlets in the hidden sector of supergravity models— the decay rate is from dimensional arguments (49)

ΓX ∼

3 MX . MP2

At very large temperatures T  MX , it is assumed that all the particles species are in thermal equilibrium, i.e. nX nX nγ (up to statistical factors) and that B = 0. At T  MX the equilibrium abundance of X and X relative to photons is given by (50)

nEQ nEQ X

X nγ nγ



MX T

3/2

e−

MX T

,

where we have neglected the chemical potential μX . For the X and X particles to mantain their equilibrium abundances, they must be able to diminish their number rapidly with respect to the Hubble rate H(T ). The conditions necessary for doing so are easily quantified. The superheavy X and X particles may attain equilibrium through decays with rate ΓX , inverse decays with rate ΓID X ⎧ ⎨1, T  MX , (51) ΓID X ΓX ⎩(MX /T )3/2 exp[−MX /T ], T  MX ,

355

Leptogenesis

and annihilation processes with rate Γann X ∝ nX . The latter, however are “self-quenching” and therefore less important than the decay and inverse decay processes. They will be ignored from now on. Of crucial interest are the B-nonconserving scattering processes 2 ↔ 2 mediated by the X and X particles with rate ΓSX (52)

ΓSX nσ α2 T 3

T2 2 + T 2 )2 , (MX

where α g 2 /4π denotes the coupling strength of the X boson. At high temperatures, the 2 ↔ 2 scatterings cross-section is σ α2 /T 2 , while at low temperatures 4 σ α2 T 2 /MX . For baryogenesis, the most important rate is the decay rate, as decays (and inverse decays) are the mechanisms that regulate the number of X and X particles in the plasma. It is therefore useful to define the following quantity: (53)

K≡

 ΓX  , H T =MX

which measures the effectiveness of decays at the crucial epoch (T ∼ MX ) when the X and X particles must decrease in number if they are to stay in equilibrium. Note also that for T  MX , K determines the effectiveness of inverse decays and 2 ↔ 2 scatterings 3/2 as well: ΓID exp[−MX /T ] K and ΓSX /H α(T /MX )5 K. X /H (MX /T ) Now, if K  1, and therefore (54)

ΓX  H|T =MX ,

then the X and X particles will adjust their abundances by decaying to their equilibrium abundances and no baryogenesis can be induced by their decays —this is simply because out-of-equilibrium conditions are not attained. Given the expression (30) for the expansion rate of the Universe, the condition (54) is equivalent to (55)

−1/2

MX g∗

αX MP ,

for strongly coupled scalar bosons, and to (56)

1/2

MX  g

MP ,

for gravitationally coupled X particles. Obviously, this last condition is never satisfied for MX  MP . However, if the decay rate is such that K 1, and therefore (57)

ΓX  H|T =MX ,

356

A. Riotto

then the X and X particles cannot decay on the expansion time scale τU and so they remain as abundant as photons for T  MX . In other words, at some temperature T > MX , the superheavy bosons X and X are so weakly interacting that they cannot catch up with the expansion of the Universe and they decouple from the thermal bath when still relativistic, nX nX nγ at the time of decoupling. Therefore, at temperature T MX , they will populate the Universe with an abundance which is much larger than the equilibrium one. This overbundance with respect to the equilibrium abundance is precisely the departure from thermal equilibrium needed to produce a final nonvanishing baryon asymmetry. Condition (57) is equivalent to (58)

−1/2

MX  g∗

αX MP ,

for strongly coupled scalar bosons, and to (59)

1/2

MX  g

MP ,

for gravitationally coupled X particles. It is clear that this last condition is always −1/2 satisfied, whereas condition (58) is based on the smallness of the quantity g∗ αX . In particular, if the X particle is a gauge boson, αX ∼ αgauge can span the range (2.5 × 10−2 –10−1 ), while g is about 102 . In this way we obtain from (58) that the condition of out-of-equilibrium can be satisfied for (60)

MX  (10−4 –10−3 ) MP (1015 –1016 ) GeV.

If X is a scalar boson, its coupling αY to fermions f with mass mf is proportional to the squared mass of the fermions  (61)

αY ∼

mf mW

2 αgauge ,

where mW is the W -boson mass and αY is typically in the range (10−2 –10−7 ), from which (62)

MX  (10−8 –10−3 ) MP (1010 –1016 ) GeV.

Obviously, condition (62) is more easily satisfied than condition (60) and we conclude that baryogenesis is more easily produced through the decay of superheavy scalar bosons. On the other hand, as we have seen above, condition (59) tells us that the out-of-equilibrium condition is automatically satisfied for gravitationally interacting particles. . 4 2. The production of the baryon asymmetry. – Let us now follow the subsequent evolution of the X and X particles. When the Universe becomes as old as the lifetime of

357

Leptogenesis

these particles, t ∼ H −1 ∼ Γ−1 X , they start decaying. This takes place at a temperature TD defined by the condition ΓX H|T =TD ,

(63) i.e. at (64)

−1/4

TD g∗

1/2

αX (MX MP )1/2 < MX ,

where the last inequality comes from (58) and is valid for particles with unsuppressed couplings. For particles with only gravitational interactions (65)

−1/4

TD ∼ g

 MX

MX MP

1/2 < MX ,

the last inequality coming from (59). At T ∼ TD , X and X particles start to decay and their number decreases. If their decay violates the baryon number, they will generate a net baryon number per decay. Suppose now that the X particle may decay into two channels, let us denote them by a and b, with different baryon numbers Ba and Bb , respectively. Correspondingly, the decay channels of X, a and b, have baryon numbers −Ba and −Bb , respectively. Let r(r) be the branching ratio of the X(X) in channel a(a) and 1 − r(r) the branching ratio of X(X) in channel b(b), (66)

Γ(X → a) , ΓX Γ(X → a) r= , ΓX Γ(X → b) 1−r = , ΓX Γ(X → b) , 1−r = ΓX r=

where we have been using the fact that the total decay rates of X and X are equal because of the CP T theorem plus unitarity. The average net baryon number produced in the X decays is (67)

rBa + (1 − r)Bb ,

and that produced by X decays is (68)

−rBa − (1 − r)Bb .

358

A. Riotto

Finally, the mean net baryon number produced in X and X decays is (69)

ΔB = (r − r)Ba + [(1 − r) − (1 − r)] Bb = (r − r)(Ba − Bb ).

Equation (69) may be easily generalized to the case in which X(X) may decay into a set of final states fn (f n ) with baryon number Bn (−Bn ) (70)

ΔB =

  1  Bn Γ(X → fn ) − Γ(X → f n ) . ΓX n

At the decay temperature, TD  MX , because K 1, both inverse decays and 2 ↔ 2 baryon-violating scatterings are impotent and can be safely ignored and thus the net baryon number produced per decay ΔB is not destroyed by the net baryon number −ΔB produced by the inverse decays and by the baryon-number-violating scatterings. At T TD , nX nX nγ and therefore the net baryon number density produced by the out-of-equilibrium decay is (71)

nB = ΔB nX .

The three Sakharov ingredients for producing a net baryon asymmetry can be easily traced back here: – If B is not violated, then Bn = 0 and ΔB = 0. – If C and CP are not violated, then Γ(X → fn ) = Γ(X → f n ), and also ΔB = 0. – In thermal equilibrium, the inverse processes are not suppressed and the net baryon number produced by decays will be erased by the inverse decays. Since each decay produces a mean net baryon number density nB = ΔBnX ΔBnγ and since the entropy density is s g nγ , the net baryon number produced is (72)

B≡

ΔBnγ ΔB nB

. s g nγ g

Taking g ∼ 102 , we see that only tiny C and CP violations are required to generate ΔB ∼ 10−8 , and thus B ∼ 10−10 . To obtain (72) we have assumed that the entropy release in X decays is negligible. However, sometimes, this is not a good approximation (especially if the X particles decay very late, at TD MX , which is the case of gravitationally interacting particles). In that case, assuming that the energy density of the Universe at TD is dominated by X particles (73)

ρX MX nX ,

359

Leptogenesis

and that it is converted entirely into radiation at the reheating temperature TRH (74)

π2 4 g TRH , 30

ρ=

we obtain nX

(75)

π2 T4 g RH . 30 MX

We can therefore write the baryon number as B

(76)

3 TRH ΔB. 4 MX

We can relate TRH with the decay rate ΓX using the decay condition (77)

Γ2X H 2 (TD )

8πρX , 3MP2

and so we can write  (78)

B

−1/2

ΓX M P 2 MX

g

1/2 ΔB.

For the case of strongly decaying particles (through renormalizable interactions) we obtain  (79)

B

−1/2

g

αMP MX

1/2 ΔB,

while for the case of weakly decaying particles (through gravitational interactions) we obtain  (80)

B

−1/2

g

MX

MP

1/2 ΔB.

In the other extreme regime K  1, one expects the abundance of X and X bosons to track the equilibrium values as ΓX  H for T ∼ MX . If the equilibrium is tracked precisely enough, there will be no departure from thermal equilibrium and no baryon number may evolve. The intermediate regime, K ∼ 1, is more interesting and to address it one has to invoke numerical analysis involving Boltzmann equations for the evolution of B. The numerical analysis essentially confirms the qualitative picture we have described so far and its discussion is beyond the scope of these lectures.

360

A. Riotto

f

f

1

f

3

Y

X

X f

f

f2

1

(d)

(c)

(b)

4

Y

f4

2

(a)

f

3

Fig. 1. – Couplings of X and Y to fermions fi .

f3

f1 f3 X

f4

3

f4

f1

f3

Y

X

Y

Y X f2

f2

f4

f4

f2 (a)

f

X f1

f1 (c)

(b)

f2 (d)

Fig. 2. – One-loop corrections to the Born amplitude of fig. 1.

. 4 2.1. An explicit example. Let us consider first two massive boson fields X and Y coupled to four fermions f1 , f2 , f3 and f4 through the vertices of fig. 1 and describing the decays X → f 1 f2 , f 3 f4 and Y → f 3 f1 , f 4 f2 . We will refer to these vertices as f2 |X|f1 , f4 |X|f3 , f1 |Y |f3  and f2 |Y |f4 , and their CP conjugate X → f 2 f1 , f 4 f3 and Y → f 1 f3 , f 2 f4 by their complex conjugate. In the Born approximation ΔB = 0 because from (70) one finds (81)

2

12 |f2 |X|f1 | = Γ(X → f 2 f1 )Born , Γ(X → f 1 f2 )Born = IX

12 accounts for the kinematic structures of the processes X → f 1 f2 and X → where IX f 2 f1 and the same may be found for the other processes contributing to ΔB. This shows that, to obtain a nonzero result for ΔB, one must include (at least) corrections arising from the interference of Born amplitudes of fig. 1 with the one-loop amplitude of fig. 2. For example, the interference of the diagrams in fig. 1(a) and fig. 2(a) (in the square amplitude) is shown in fig. 3(a), where the thick dashed line is the unitarity cut (equivalent to say that each cut line represents on-shell mass particles). The amplitude of 1234 1234 the diagram in fig. 3(a) is given by IXY Ω1234 , where the kinematic factor IXY accounts for the integration over the final state phase space of f2 and f 1 and over momenta of the internal states f4 and f 3 , and

(82)

Ω1234 = f1 |Y |f3 ∗ f4 |X|f3 f2 |Y |f4 f2 |X|f1 ∗ .

361

Leptogenesis (a) f3 X

f1 X

Y

f4

(c)

(b) f1 X

X

Y

f2

f2

f1

f3

(d) f3

X

f3 X

X

Y

f4

f2

f1

X Y

f4

f4

f2

Fig. 3. – Intereference between the diagrams of fig. 1 and fig. 2 for the square amplitudes of X decay.

The complex-conjugate diagram of fig. 3(b) has the complex-conjugate amplitude. Therefore, the contribution from the diagrams in figs. 3(a) and (b) to the decay X → f 1 f2 is (83)

1234 Ω1234 + h.c. Γ(X → f 1 f2 )interference = IXY

To obtain the CP conjugate amplitude X → f 2 f1 , all couplings must be complex conjugated, although the kinematic factors IXY are unaffected by CP conjugation. Therefore the interference contribution to the X → f 2 f1 decay rate is given by (84)

1234 ∗ Ω1234 + h.c. Γ(X → f 2 f1 )interference = IXY

and the relevant quantity for baryogenesis is given by (85)

 1234  Im [Ω1234 ] . Γ(X → f 1 f2 ) − Γ(X → f 2 f1 ) = −4 Im IXY

The diagrams of the decays X → f 3 f4 and X → f 3 f4 differ from the one in figs. 3(a) and (b) only in that the unitarity cut is taken through f3 and f4 instead of f1 and f2 . One easily obtains (86)

 3412  Im [Ω∗1234 ] . Γ(X → f 3 f4 ) − Γ(X → f 4 f3 ) = −4 Im IXY

The kinematic factors IXY for loop diagrams may have an imaginary part whenever any internal lines may propagate on their mass shells in the intermediate states, picking the pole of the propagator (87)

p2

1 PP = 2 + iπδ(p2 − m2 ), 2 − m + i p − m2

where PP stands for the principal part. This happens if MX > m1 + m2 and MX > m3 + m4 . This means that with light fermions, the imaginary part of IXY will be always 1234 3412 nonzero. The kinematic factors Im[IXY ] and Im[IXY ] are therefore obtained from diagrams involving two unitarity cuts: one through the lines f1 and f2 and the other through the lines f3 and f4 . The resulting quantities are invariant under the interchanges f1 ↔ f3 and f2 ↔ f4 and consequently (88)

 3412   1234  = Im IXY = Im [IXY ] . Im IXY

362

A. Riotto

Defining Bi the baryon number of the fermion fi , the net baryon number produced in the X decays is therefore (89)

(ΔB)X =

4 Im [IXY ] Im [Ω1234 ] [B4 − B3 − (B2 − B1 )] . ΓX

To compute the baryon asymmetry (ΔB)Y one may observe that the set of vertices in fig. 1 is invariant under the transformations X ↔ Y and f1 ↔ f4 . These rules yield (90)

(ΔB)Y =

4 Im [IY X ] Im [Ω∗1234 ] [B4 − B3 − (B2 − B1 )] ΓY

and the total baryon number is therefore given by (91)

(ΔB) = (ΔB)X + (ΔB)Y ! " Im [IXY ] Im [IY X ] =4 Im [Ω1234 ] [B4 − B3 − (B2 − B1 )] . − ΓX ΓY

We can notice a few things: – If the X and Y couplings were B conserving, the two possible final states in X and Y decays would have the same baryon number, i.e. B4 − B3 = B2 − B1 and therefore ΔB = 0. Therefore the baryon number must be violated not only in X decays but also in the decays of the particle exchanged in the loop. – Some coupling constants in the Lagrangian must be complex to have Im[Ω1234 ]. – Even if (ΔB)X and (ΔB)Y are both nonvanishing, the sum can vanish if the first bracket in (91) cancels out. This happens if the X and Y particles have the same mass and ΓX = ΓY . . 4 3. Baryon number violation within the SM and out-of-equilibrium baryogenesis. – At this point, we are ready to discuss the implications of the baryon number violation in the early Universe for the baryogenesis scenarios discussed so far. The basic lesson we have learned previously is that any asymmetry (B + L) is rapidly erased by sphaleron transitions as soon as the temperature drops down at ∼ 1012 GeV. Now, we can always write the baryon number B as (92)

B=

B+L B−L + . 2 2

This equation seems trivial, but is dense of physical significance! Sphaleron transitions only erase the combination (B + L), but leave the orthogonal combination (B − L) untouched. This means that the only chance for a GUT baryogenesis scenario to work is to produce at high scale an asymmetry in (B − L). However, we have learned that there is no possibility of generating such an asymmetry in the framework of SU (5). This is because the fermionic content of the theory is the one of the SM and there is no violation of (B −L). Sphaleron transitions are therefore the killers of any GUT baryogenesis model

363

Leptogenesis

based on the supersymmetric version of SU (5) with R parity conserved (the nonsupersymmetric version is already ruled out by experiments on the proton decay lifetime). This is a striking result. However, theories with (B − L) violation incorporated in them may be successful. Indeed, any asymmetry in (B − L) will correspond to an asymmetry in B once sphalerons are allowed to act, see eq. (92). This is, in a nutshell, the idea of leptogenesis, which we now describe. 5. – Baryogenesis via leptogenesis: one-flavour approximation Baryogenesis through leptogenesis [9] is a simple mechanism to explain this baryon asymmetry of the Universe. As we said, a lepton asymmetry is dynamically generated and then converted into a baryon asymmetry due to (B + L)-violating sphaleron interactions which exist in the SM. The reader is forwarded to refs. [11] and [12] for more details. A simple model in which this mechanism can be implemented is the “see-saw”(type I) [13], consisting of the SM plus two or three right-handed (RH) Majorana neutrinos. In this simple extension of the SM, the usual scenario that is explored (referred to as “thermal leptogenesis”) consists of a hierarchical spectrum for the RH neutrinos, such that the lightest of the RH neutrinos is produced by thermal scattering after inflation, and subsequently decays out-of-equilibrium in a lepton number and CP -violating way, thus satisfying Sakharov’s constraints. This section introduces notations and reviews the calculation of the lepton asymmetry when the charged lepton Yukawa couplings are neglected. As we shall see, the commonly used formulae for the final lepton asymmetry, which we report here, may not be appropriate once flavours are considered. The reader should be patient, flavour effects will be discussed later. Our starting point is the Lagrangian of the SM with the addition of three righthanded neutrinos Ni (i = 1, 2, 3) with heavy Majorana masses M3 > M2 > M1 and Yukawa couplings λαi . Working in the basis in which the Yukawa couplings for the charged leptons are diagonal, the Lagrangian reads  (93)

L = LSM +

Mi 2 N + λαi Lα HNi 2 i

 + h.c.

Here Lα is the lepton doublet with flavour (α = e, μ, τ ), and H is the Higgs doublet whose neutral component has a vacuum expectation value (VEV) equal to v = 175 GeV. After spontaneous symmetry breaking, a Dirac mass term mD = λv, is generated by the VEV of the Higgs boson. In the see-saw limit, M  mD , the spectrum of neutrino mass eigenstates splits in two sets: three very heavy neutrinos, N1 , N2 and N3 , respectively with masses M1 ≤ M2 ≤ M3 , almost coinciding with the eigenvalues of M , and three light neutrinos with masses m1 ≤ m2 ≤ m3 , the eigenvalues of the light neutrino mass matrix given by the see-saw formula [13] (94)

mν = −mD

1 T m . M D

364

A. Riotto

Neutrino oscillation experiments measure two neutrino mass-squared differences. For normal schemes one has m23 − m22 = Δm2atm and m22 − m21 = Δm2sol , whereas for inverted schemes one has m23 − m22 = Δm2sol and m22 − m21 = Δm2atm . For m1  matm ≡  2 = (0.050 ± 0.001) eV [14] the spectrum is quasi-degenerate, while for Δm2atm + Δm sol m1 msol ≡ Δm2sol = (0.00875 ± 0.00012) eV [14] it is fully hierarchical (normal or inverted). Here we will restrict ourselves to the case of normal schemes. The most stringent upper bound on the absolute neutrino mass scale comes from cosmological observations. Recently, a conservative upper bound on the sum of neutrino masses,  i mi ≤ 0.61 eV (95% CL), has been obtained by the WMAP collaboration combining CMB, baryon acoustic oscillations and supernovae type-Ia observations [2]. Considering that it falls in the quasi-degenerate regime, it straightforwardly translates into (95)

m1 < 0.2 eV (95% CL).

It proves sometimes useful to adopt the bi-unitary parametrization (96)

mD = VL† DmD UR ,

where VL and UR are two unitary matrices that diagonalize mD and DmD is the diagonal matrix whose elements are the eigenvalues of mD : DmD ≡ diag(lD1 , lD2 , lD3 ). This shows that in the process of see-saw, 9 parameters are lost: at high energies there 18 real parameters (3 from the eigenvalues of mD , 3 from Mi , and 12 from VL and VR ). At low energy there are only 9 (3 from mi and 6 from the matrix U diagonalizing mν ). We now assume that right-handed neutrinos are hierarchical, M2,3  M1 so that studying the evolution of the number density of N1 suffices. The final amount of (B − L) asymmetry can be parametrized as YB−L = nB−L /s, where s = 2π 2 g T 3 /45 is again the entropy density and g counts the effective number of spin-degrees of freedom in thermal equilibrium (g = 217/2 in the SM with a single generation of right-handed neutrinos). After reprocessing by sphaleron transitions, the baryon asymmetry is related to the L asymmetry by [5]  (97)

YB = −

8nG + 4nH 14nG + 9nH

 YL ,

where nH is the number of Higgs doublets, and nG the number of fermion generations (in equilibrium). It is also useful to define an efficiency factor η which tells how efficient is the production of the baryon asymmetry, e.g. how much of the asymmetry per RH neutrino decay remais after wash-out processes are accounted for (98)

YB 1.38 · 10−3 1 η,

where we have assumed nH = 1. Now, the idea of thermal leptogenesis is that RH neutrinos decay in the early Universe out of equilibrium, thus producing a lepton asymmetry.

365

Leptogenesis

One defines the CP asymmetry generated by N1 decays as (99)

  2    Im (λλ† )2j1 Mj [Γ(N → H ) − Γ(N → H )] 1 1 α 1 α . g 1 ≡ α = †] 8π [λλ M12 11 α [Γ(N1 → Hα ) + Γ(N1 → Hα )] j =1

It is the sum of two contributions, the vertex and the wave function ones. A calculation similar to the one performed in the toy model previously discussed leads to (100)

g(x) =

√ x



1 + 1 − (1 + x) ln 1−x



1+x x



3 −→ − √ . 2 x

x 1

Besides the CP parameter 1 , the final baryon asymmetry depends on a single washout parameter,  (101)

K≡

α

Γ(N1 → Hα ) ≡ H(M1 )



m A1 m A∗

 ,

where H(M1 ) denotes the value of the Hubble rate evaluated at a temperature T = M1 (m A ∗ ∼ 10−3 eV) and (102)

m ˜1 ≡

(λλ† )11 v 2 M1

is proportional to the total decay rate of the right-handed neutrino N1 . One could now proceed as in the previous sections by estimating the baryon asymmetry. However, we want to do a better job and we resort to the Boltzmann equations. By defining the variable z = M1 /T , the Boltzmann equations for the lepton asymmetry YL , and the right-handed neutrino number density YN1 (both normalised to the entropy s), may be written in a compact form as (103)

(104)

  d(YN1 − YNEQ ) dYNEQ z YN1 1 1 =− (γD + γΔL=1 ) , − 1 − dz sH(M1 ) dz YNEQ 1   z dYL YL YN1 = − 1 1 (γD + γΔL=1 ) − EQ (γD + γΔL=1 ) . dz sH(M1 ) YNEQ YL 1

The processes taken into account in these equations are decays and inverse decays with rate γD , ΔL = 1 scatterings such as (qtc → N ), and ΔL = 2 processes mediated by heavy neutrinos (see fig. 4). The first three modify the abundance of the lightest righthanded neutrinos. The ΔL = 2 scatterings mediated by N2,3 are neglected in our analysis for simplicity. The various γ are thermally averaged rates, including all contributions summed over flavour (s, t channel interference, etc.); explicit expressions can be found in the literature. Notice that in this “usual” analysis, ΔL = 1 scattering contributes to the

366

A. Riotto L

L

H

N1

N1

L

N2, 3 H

H L

H

L N2, 3

H

L

L

N1, 2, 3

L N1

H

L

N1, 2, 3

H N1, 2, 3

H

H

H

L

L

H

N1

U3

N1

L

N1

L

H

H

H

L

Q3

U3

Q3

Q3

U3

N1

H

N1

H

N1

H

H

L

L

L

A

L

A

A

L

N1

L

N1

L

N1

L

L H

H A

H

H

A

A

H

Fig. 4. – Feynman diagrams contributing to thermal leptogenesis.

creation of N1 ’s and not to the production of a lepton asymmetry, only to the wash-out. can be obtained from Approximate analytic solutions for YL and ΔN1 ≡ YN1 − YNEQ 1 simplified equations. Calculating in zero-temperature field theory for simplicity, one obtains (105)

γD sYNEQ 1

K1 (z) ΓD , K2 (z)

YNEQ

1

1 2 z K2 (z). 4g

The Boltzmann equations can be approximated (106)

ΔN1 = −zK

(107)

YL = 1 Kz

K1 (z) f1 (z)ΔN1 − YNEQ , 1 K2 (z) K1 (z) 1 ΔN1 − z 3 KK1 (z)f2 (z)YL , K2 (z) 4

where K1 and K2 are modified Bessel functions of the second kind. The function f1 (z) accounts for the presence of ΔL = 1 scatterings, and f2 (z) accounts for scatterings in the

367

Leptogenesis

wash-out term of the asymmetry. They can be approximated, in interesting limits, as ⎧ ⎨1, for z  1, (108) f1 (z) 2 2 ⎩ N2c m2 t 2 , for z  1, 4π v z and f2 (z)

(109)

⎧ ⎨1,

for z  1,

2 2 ⎩ aK 2Nc2m2t , 8π v z

for z  1,

N 2 m2

where 8πc2 v2t ≡ Ks /K ∼ 0.1 parametrizes the strength of the ΔL = 1 scatterings and aK = 4/3(2) for the weak (strong) wash out case. A good approximation to the rate Kz(K1 (z)/K2 (z))f1 (z) is given by the function (Ks + Kz) while the wash-out term −(1/4)z 3 KK1 (z)f2 (z)YL is well approximated at small z by −aK Ks YL . . 5 1. Strong wash-out regime. – In the strong wash-out regime, the parameter K  1 and the right-handed neutrinos N1 ’s are nearly in thermal equilibrium. Under these circumstances, one can set ΔN1 0 and ΔN1 (zK2 /4g K). Exploiting a saddle-point approximation in eq. (107), we find that the lepton asymmetry is given by  ∞ K 2 − R ∞ dz ((z )3 /4)K1 (z )K (110) YL 1 dz z e z . 4g 0 Using the steepest-descent method to evaluate the integral, one finds that it gets the major contribution at z such that z = log K + (5 ln z/2) when inverse decays become inefficient. The lepton asymmetry in the flavour α becomes 1 YL 0.3 g

(111)



0.55 × 10−3 eV m ˜1

1.16 .

. 5 2. Weak wash-out regime. – In this case all the K 1. We assume that right-handed neutrinos are not initially present in the plasma, but they are generated by inverse decays and scatterings. The equation of motion for YN1 is well approximated by   (112) YN 1 = −(Ks + Kz) YN1 − YNEQ , 1 We split the solution into two pieces. Let us define zEQ the value of z at which YN1 (zEQ ) = YNEQ (zEQ ). This value has to be found a posteriori. For z zEQ , we may suppose that 1 and eq. (112) is solved by YN1 YNEQ 1 (113)

YN−1 (z)



z



dz (Ks + Kz 0



)YNEQ 1

1 = 4g K = 4g



z

0



dz  (Ks + Kz  )(z  )2 K2 (z  )

 Ks I1 (z) + I2 (z) . K

368

A. Riotto

With I1 and I2 integral involving the modified Bessel functions,  (114)

z

I1 (z) =

x2 K2 (x)dx f (z) + z 3 K2 (z),

0

where (115)

f (z) =

3πz 3 ((9π)c + (2z 3 )c )

1/c

,

c = 0.7.

The integral I2 is well known, and equals  I2 (z) =

(116)

z

x3 K2 (x)dx = 8 − z 3 K3 (z).

0

Therefore (117)

YN−1 (z)

K

4g



 Ks 3 3 (f (z) + z K2 (z)) + 8 − z K3 (z) . K

As expected for weak wash-out, we find that the maximum number density of N1 is proportional to K (recall Ks ∝ K). Let us now compute the value of zEQ . We expect it to be  1 and we therefore  π −1/2 −z approximate, up to O(z −3/2 ): K2 (z) K3 (z) e . Imposing YN−1 (zEQ ) = 2z EQ YN1 (zEQ ), we find (118)

zEQ

3

ln zEQ − ln 2



 ) π  Ks . K +3 2 π/2 8

This solution is a good approximation to the real value for K 1. For z > zEQ , we have (Ks + Kz) Kz and (119)

2 2 (zEQ )eK/2(zEQ −z ) . YN1 (z) YNEQ 1

Notice that we have included CP violation in ΔL = 1 scattering, unlike the usual analysis, so we expect our solution for YL to have a different scaling with K than in the traditional literature: if CP / in scattering is neglected, then YN ∝ K, and the N1 ’s decay out of equilibrium, so one expects YL ∝ K1 . However, if CP / in N1 production ( scattering) is included, and washout is neglected, then the equations for YN1 and YL are identical, so YL (z → ∞) vanishes. That is, for every |1/1 | N1 ’s that are created, be it by inverse decay or scattering, an (anti)-lepton is produced. This (anti-)asymmetry will approximately cancel against the lepton asymmetry generated later on, when the N1 ’s decay. However the cancellation will be imperfect, because the anti-asymmetry has more time to be washed out, so the final asymmetry should scale as K 2 . After integrating by

369

Leptogenesis SM

102

SM

1

dominant N1 thermal N1 zero N1

10− 4 −6

10− 1

10− 2

atm

efficiency η

10− 2

sun

efficiency η

1

10

10− 8 − 10 10

10− 8

10− 6 10− 4 ∼ in eV m 1

10− 2

10− 3 10− 3

1

10− 2 ∼ in eV m 1

10− 1

Fig. 5. – The efficiency factor as a function of m ˜ 1 . Notice that for small values of m ˜ 1 the slope as the CP asymmetry from scattering is not accounted for. On the left-hand side three is m ˜ −1 1 and dominant N1 . On cases are analyzed: zero N1 abundance, thermal abundance (nN1 ∼ neq N1 the right-hand side, there is a zoom). From [11].

parts, this is what we find for the lepton asymmetry, which is given by  ∞ R ∞   1 (120) YL 1 dz  YN1 (z  )g1 (z  )e− z dz g1 (z ) , g1 (z) = z 3 KK1 (z)f2 (z), 4 0 2  m ˜1 1 .

1.5 g 3.3 × 10−3 eV Our findings hold provided that the nonresonant ΔL = 2 scattering rates, in particular those mediated by the N2 and N3 heavy neutrinos, are slower than decays and ΔL = 1 scatterings when most of the asymmetry is generated. We estimate that this applies when   M1 (121)  10−1 . 1014 GeV This means that K should be larger than 10−4 . Our results can be summarized with simple analytical fits for the efficiency factor (122)

1 ≈ η



3.3 × 10−3 eV m ˜1

2

 +

m ˜1 0.55 × 10−3 eV

1.16 ,

valid for MN1  1014 GeV and when one starts with no RH neutrinos in the plasma. Numerical results are presented in fig. 5. This enables the reader to study leptogenesis in neutrino mass models without setting up and solving the complicated Boltzmann equations. . 5 3. Implications of one-flavour leptogenesis. – Experiments have not yet determined the mass m3 of the heaviest mainly left-handed neutrinos. We assume m3 = max(m ˜ 1 , matm ). A crucial assumption we have so far is that right-handed neutrinos are

370

A. Riotto

very hierarchical. Under this hypothesis the CP asymmetry is bounded by the expression [15] that in the hierarchical and quasi-degenerate light neutrino limit simplifies as follows:

(123)

⎧ ˜ 1, if m1 m3 , 3 M1 (m3 − m1 ) ⎨1 − m1 /m |1 | ≤ ×  2 ⎩ 1 − m2 /m 16π v2 1 ˜ 1 , if m1 m3 ,

where all parameters are renormalized at the high-energy scale ∼ M1 . The 3σ ranges of matm and of YB imply the lower bound (124)

M1 >

4.5 × 108 GeV > 2.4 × 109 GeV, η

in the case in which no RH neutrinos are present in the plasma at the beginning of the dynamics and we have assumed that the efficiency is maximal (and therefore η minimal). This bound is relevant because it tells us that a working model of thermal leptogenesis (in the one-flavour approximation) needs enough heavy RH neutrinos. This has implications for SO(10) grand-unified theories, commonly regarded as the most attractive way to embed the see-saw mechanism. Indeed, in a traditional version of leptogenesis, where the spectrum of right-handed (RH) neutrinos is hierarchical and the asymmetry is produced from the decays of the lightest ones, there is a stringent lower bound on their mass [15], M1 > O(109 ) GeV, for a sufficiently large baryon asymmetry to be produced. On the other hand, SO(10) grand-unified theories typically yield, in their simplest version and for the measured values of the neutrino mixing parameters, a hierarchical spectrum with the RH neutrino masses proportional to the squared of the up-quark masses, leading to M1 = O(105 ) GeV and to a final asymmetry that falls a few orders of magnitude below the observed one.  We can also work out a bound on the light neutrino masses, i mi  0.15 eV. It can be understood to arise from the lower bound on the total decay rate m1 ≤ m ˜ 1 , and the upper bound on the total CP asymmetry (123). We assume the light neutrinos are √ degenerate, so |m1 | |m2 | |m3 | ≡ m/ ¯ 3 —but the masses can have different Majorana phases. Leptogenesis takes place in the strong wash-out regime, due to the lower bound on the total decay rate. The final baryon asymmetry can be roughly approximated as YB ∼ 10−4 /K ∝ Δm2atm /m ¯ 2 . As the light neutrino mass scale is increased, M1 and the temperature of leptogenesis must increase to compensate the Δm2atm /m ¯ 2 suppression. However, this temperature is bounded from above, from the requirement of having the ΔL = 2 processes out of equilibrium when leptogenesis takes place: (125)

m ¯ 2T 3 10T 2  , 12πv 4 MP

¯ 2 GeV. There is therefore an upper bound on the baryon asymmetry so M1  1010 (eV/m)

371

Leptogenesis

SM 3σ ranges

10− 9

10− 10 0.08

0.1 0.12 0.14 heaviest ν mass m3 in eV

MSSM

10− 8 maximal nB / nγ

maximal nB / nγ

10− 8

0.16

3σ ranges

10− 9

10− 10 0.08

0.1 0.12 0.14 heaviest ν mass m3 in eV

0.16

Fig. 6. – The bound on the heaviest light neutrino mass for the SM and for the Minimal Supersymmetric Standard Model (MSSM).

which scales as 1/m ¯ 4 , and with our rough estimates, one finds (126)

√ 3  0.1 eV. m/ ¯

This result is confirmed by a full numerical analysis [11], see fig. 6. 6. – Comments on baryogenesis via leptogenesis when flavours are accounted for In recent years, a lot of work has been devoted to a thorough analysis of thermal leptogenesis giving limited attention to the issue of lepton flavour [16]. The dynamics of leptogenesis is usually addressed within the “one-flavour” approximation, where Boltzmann equations are written for the abundance of the lightest RH neutrino, responsible for the out of equilibrium and CP asymmetric decays, and for the total lepton asymmetry. However, this “one-flavour” approximation is rigorously correct only when the interactions mediated by charged lepton Yukawa couplings are out of equilibrium. Flavour effects have not been included in leptogenesis calculations till very recently [17-19]. This is perhaps because perturbatively, they seem to be a small correction. For instance, if the asymmetry is a consequence of the very-out-of-equilibrium decay of an initial population of right-handed neutrinos, then the total lepton asymmetry is of order /g∗ , where  is the total CP asymmetry in the decay, and g∗ counts for the entropy dilution factor. Clearly the small charged lepton Yukawa couplings have no effect on . However, realistic leptogenesis is a drawn-out dynamical process, involving the production and destruction of right-handed neutrinos, and of a lepton asymmetry that is distributed among distinguishable flavours. The processes which wash out lepton number are flavour dependent, e.g., the inverse decays from electrons can destroy the lepton asymmetry carried by, and only by, the electrons. The asymmetries in each flavour are therefore washed out differently, and will appear with different weights in the final formula for the baryon asymmetry. This is physically inequivalent to the treatment of wash-out in the one-flavour approximation, where indistinguishable leptons propagate between decays and inverse decays, so inverse decays from all flavours are taken to wash out asymmetries in any flavour.

372

A. Riotto

We define Yαα to be the lepton asymmetry in flavour α, where the α are the lepton mass eigenstates at the temperature of leptogenesis. The Yαα are the diagonal elements of a matrix [Y ] in flavour space, whose trace is the total lepton asymmetry. In this lecture the off-diagonal elements are neglected. The equations of motion for the matrix [Y ] are more complicated than the Boltzmann equations, but at most temperatures are equivalent to Boltzmann equations written in the mass eigenstate basis of the leptons in the plasma. The off-diagonal elements of [Y ] could have some effect on the lepton asymmetry, if leptogenesis takes place just as a charged lepton Yukawa coupling is coming into equilibrium (so the mass eigenstate basis is changing). The mass eigenstates for the particles in the Boltzmann equations (BE) are determined by the interactions which are fast compared to those processes included in the BE. The interaction rate for Yukawa coupling hα can be estimated as Γα 5 × 10−3 h2α T,

(127)

so interactions involving the τ (μ) Yukawa coupling are out of equilibrium in the primeval plasma if T  1012 GeV (T  109 GeV)(1 ). Thermal leptogenesis takes place at temperatures on the order of M1 , and the asymmetry is generated when the rates  H, so we conclude that the τ (μ) lepton doublet is a distinguishable mass eigenstate, for the purposes of leptogenesis, at T < 1012 (109 ) GeV. Suppose therefore that M1 is below 109 GeV and we forget for the time being about the bound (124). All flavours are distinguishable. The Boltzmann equations for the flavour asymmetries Yαα , are as follows. The equation for the N1 number density remains unchanged, and the equation for the flavoured lepton asymmetry is   αα z YN1 Y dY αα αα αα (128) = − 1 αα (γD + γΔL=1 ) − EQ (γD + γΔL=1 ) . dz sH(M1 ) YNEQ YL 1

To obtain analytic solutions, we could simplify this, with the approximations introduced in the previous section, to (129) (130)

 Yαα = αα Kz

K1 (z) 1 f1 (z)ΔN1 − z 3 K1 (z)f2 (z)Kαα Yαα , K2 (z) 4

ΔN1 = −zK

K1 (z) f1 (z)ΔN1 − YNEQ , 1 K2 (z)

ΔN1 = −zK

K1 (z) f1 (z)ΔN1 − YNEQ , 1 K2 (z)

where (131)

(1 ) The electron Yukawa coupling mediates interactions relevant in the early Universe only for temperatures below ∼ 105 GeV and can be safely disregarded.

373

Leptogenesis

where (132)

Kαα

λ1α λ∗1α = K = 2 γ |λ1γ |



m ˜ αα 10−3 eV

 ,

K=



Kαα .

α

 Kαα parametrizes the decay rate of N1 to the α-th flavour, and the trace α Kαα coincides with the K parameter defined in the previous section, see eq. (101). Notice, in particular, that the dynamics of the right-handed neutrinos is always set by the total K. The CP asymmetry in the α-th flavour is αα and is normalised by the total decay rate    @ ? Mj2 1 1 † ∗ αα = (133) Im (λ1α )(λλ )1j λjα g (8π) [λλ† ]11 j M12 " ! 3 [m∗ ]βα (134) Im λ λ → 1β 1α , (16π)[λλ† ]11 v2 where the second line is in the limit of hierarchical NJ , and m = U ∗ Dm U † = v 2 λT M −1 λ is the light neutrino mass matrix. If m3 is the heaviest light neutrino mass (= matm for the nondegenerate case) and we define max = 3Δm2atm M1 /(8πv 2 mmax ) [15], then the flavour-dependent CP asymmetries are bounded by ) ) 3M1 m3 Kαα Kαα m23 max = , (135) αα ≤ 2 2 16πv K Δmatm K so the maximum CP asymmetry in a given flavour is unsuppressed for degenerate light neutrinos [17], but decreases as the square root of the branching ratio to that flavour = Kαα /K. The first consequence of this result is that there is no upper bound on the light neutrino masses when flavours are accounted for. The CP asymmetry αα can be written in terms of the diagonal matrix of the light neutrino mass eigenvalues m = Diag(m1 , m2 , m3 ), the diagonal matrix of the the right handed neutrino masses M = Diag(M1 , M2 , M3 ) and an orthogonal complex matrix [20] (136)

R = vM −1/2 λU m−1/2 ,

where the matrix U diagonalizes the light neutrino mass matrix mν , so that (137)

U † mν U  = −Dm

and it can be identified with the lepton mixing matrix in a basis where the charged lepton mass matrix is diagonal. The asymmetry reads   1/2 3/2 ∗ m m U U R R Im ρ αρ β1 ρ1 αβ βρ β 3M1  (138) αα = − . 2 16πv 2 m |R β 1β | β

374

A. Riotto

For a real R matrix, the individual CP asymmetries αα may not vanish because of the presence of CP violation in the U matrix. On the contrary, the total CP asymmetry  1 = α αα vanishes. This is the second implication of the flavours: leptogenesis works even if the matrix R is real. Let us say this in other words. The neutrino Yukawa coupling can be written in its singular value decomposition, λ = VL† Diag(λ1 , λ2 , λ3 )UR . Hence, the CP violation in the right-handed neutrino sector is encoded in the phases in VR , that can be extracted from diagonalizing the combination λλ† = UR† Diag(λ21 , λ22 , λ23 )UR . In the one-flavour regime, only the phases of the matrix VR count, in the flavour regime the phase of the matrix VL also counts and the final lepton asymmetry does not vanish even if the matrix VR is real. Implications of this result can be found in [21-23]. 7. – Conclusions In this lecture we have presented the scenario of thermal leptogenesis. Because of the lack of time, we have touched in more details the one-flavour scenario, while we have left the more realistic flavourful scenario to the curiousity of students. Leptogenesis is very much linked to neutrino physics and therefore any future new discovery in this field will open for us a new window into the primordial Universe. ∗ ∗ ∗ It is with great pleasure that the author thanks the Directors of the School F. Ferroni and F. Vissani for the wonderful atmosphere they have created around the School.

REFERENCES [1] Kolb E. W. and Turner M. S., Front. Phys., 69 (1990) 1. [2] Komatsu E. et al. (WMAP Collaboration), arXiv:0803.0547 [astro-ph]. [3] Dodelson S., Modern Cosmology (Academic Press, Amsterdam, The Netherlands) 2003, p. 440. [4] Iocco F., Mangano G., Miele G., Pisanti O. and Serpico P. D., arXiv:0809.0631 [astro-ph]. [5] Riotto A., arXiv:hep-ph/9807454. [6] Riotto A. and Trodden M., Annu. Rev. Nucl. Part. Sci., 49 (1999) 35 [arXiv:hepph/9901362]. [7] Davidson S., Nardi E. and Nir Y., arXiv:0802.2962 [hep-ph]. [8] Sakharov A. D., Zh. Eksp. Teor. Fiz. Pis’ma, 5 (1967) 32; JETP Lett. B, 91 (1967) 24. [9] Fukugita M. and Yanagida T., Phys. Lett. B, 174 (1986) 45. [10] Lyth D. H. and Riotto A., Phys. Rep., 314 (1999) 1 [arXiv:hep-ph/9807278]. [11] Giudice G. F., Notari A., Raidal M., Riotto A. and Strumia A., Nucl. Phys. B, 685 (2004) 89 [arXiv:hep-ph/0310123]. [12] Buchmuller W., Di Bari P. and Plumacher M., Ann. Phys. (NY), 315 (2005) 305. [13] Minkowski P., Phys. Lett. B, 67 (1977) 421; Gell-Mann M., Ramond P. and Slansky R., Proceedings of the Supergravity Stony Brook Workshop, edited by Van Nieuwenhuizen P. and Freedman D. (New York) 1979; Yanagida T., Proceedings of the Workshop on Unified Theories and Baryon Number in the Universe, Tsukuba, Japan 1979, edited by

Leptogenesis

[14] [15] [16]

[17] [18] [19] [20] [21] [22] [23]

375

Sawada A. and Sugamoto A.; Mohapatra R. N. and Senjanovic G., Phys. Rev. Lett., 44 (1980) 912. Strumia A., this volume, p. 21. Davidson S. and Ibarra A., Phys. Lett. B, 535 (2002) 25 [arXiv:hep-ph/0202239]. See also, Barbieri R., Creminelli P., Strumia A. and Tetradis N., Nucl. Phys. B, 575 (2000) 61; Endoh T., Morozumi T. and Xiong Z. h., Prog. Theor. Phys., 111 (2004) 123. Abada A., Davidson S., Josse-Michaux F. X., Losada M. and Riotto A., J. Cosmol. Astroparticle Phys., 0604 (2006) 004. Nardi E., Nir Y., Roulet E. and Racker J., JHEP, 0601 (2006) 164. Abada A., Davidson S., Ibarra A., Josse-Michaux F. X., Losada M. and Riotto A., JHEP, 0609 (2006) 010. Casas J. A. and Ibarra A., Nucl. Phys. B, 618 (2001) 171 [arXiv:hep-ph/0103065]. Pascoli S., Petcov S. T. and Riotto A., Phys. Rev. D, 75 (2007) 083511 [arXiv:hepph/0609125]. Branco G. C., Gonzalez Felipe R. and Joaquim F. R., Phys. Lett. B, 645 (2007) 432 [arXiv:hep-ph/0609297]. Pascoli S., Petcov S. T. and Riotto A., Nucl. Phys. B, 774 (2007) 1 [arXiv:hepph/0611338].

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-377

Measurements of neutrino mass. Concluding remarks A. Yu. Smirnov International Centre for Theoretical Physics - Strada Costiera 11, Trieste, Italy and Institute for Nuclear Research, RAN - Moscow, Russia

Summary. — Measurements of the neutrino mass are considered in a general context of neutrino studies and searches for new physics beyond the standard model. The topics include: phenomenology of mass, origins and nature of neutrino masses, explanation of their smallness, relation between masses and mixing, implications of mass determination for fundamental theory and a possibility to predict neutrino mass or type of mass spectrum.

1. – Introduction It took more than 70 years since Pauli’s original idea (1930) that the neutrino mass is of the order of the electron mass (or smaller) and the first Fermi’s estimation (1934) that mν < 0.1me to conclude that at least one of neutrino masses is in the range (1)

m = (0.04–0.20) eV.

Behind this conclusion, one finds marvelous works of several generations of experimentalists and theoreticians, particle physicists and cosmologists [1]. The scale (1) is about 10−7 me , 10−10 mp , 10−12 mt , and the latter provides strong evidence that with neutrino masses we are touching something really new. c Societ`  a Italiana di Fisica

377

378

A. Yu. Smirnov

Q3

Qe

Q2 Q1

MASS

QP

QW Q2

Q3

Q1 NORMAL

INVERTED

Fig. 1. – Neutrino mass and flavor spectra for the normal (left) and inverted (right) mass hierarchies. The distribution of flavors (parts of boxes with different shadowing) in the mass eigenstates corresponds to the best-fit values of the mixing parameters and sin2 θ13 = 0.05.

The long history of the direct kinematic measurements (better —searches) of neutrino mass will culminate next year with the start of the KATRIN experiment [2]. One can measure “time in neutrino physics” using the upper bounds on the mass of the electron neutrino with ∼ 105 eV as the starting point down to 2 eV now. The breakthrough came from a completely different side. About 50 years ago in the paper “Mesonium and antimesonium” [3] Bruno Pontecorvo mentioned a possibility of neutrino oscillations which implies non-zero neutrino mass and mixing. Incidentally, in the same year 1957, the discovery of the parity violation was announced. This led to establishing the V -A theory of the weak interactions, and the theory of the two-component massless neutrino which was the dominating idea for almost 40 years. As we know, since 1998, the first line —Pontecorvo’s idea— won. The lesson we can extract from this story is that the “non-standard” and “exotic” process (oscillations) led eventually to this discovery. The fact that neutrinos have mass has been established not from the direct kinematic measurements but indirectly, observing new processes related to the phenomenon of mixing which requires the existence of non-zero mass. Detailed analysis then showed that non-zero mass is the only explanation of data (or at least, the origin of the dominant mechanism behind observations). Without additional assumptions, the oscillations give only the lower bound on the mass. The upper bound in (1) follows from Cosmology, the analysis of the Larger Scale Structure (LSS) of the Universe. The interval (1) is amazingly small in comparison with our staring point. At the same time, it is still large from the point of view of theory. There is a big difference of implications of two different values of mass m = 0.04 eV and m = 0.2 eV. Furthermore, the key questions is: what is the flavor of this heaviest state, that is, what is the mass hierarchy (fig. 1)? How are we going to further improve the determination of the absolute mass scale? Remember the lesson: the answer may come from something unexpected which is based on a new and non-standard phenomenon.

Measurements of neutrino mass. Concluding remarks

379

Fig. 2. – Cosmological bounds on the sum of neutrino masses obtained using different sets of data: CMB (dotted), CMB + LSS (dashed), CMB + Hubble Space Telescope + SN-Ia (dot-dashed), the same as previous + Baryonic acoustic oscillations (long dashed), the same as previous + Lyα (solid); from [4].

2. – Phenomenology of neutrino mass Phenomenology of neutrino masses (their absolute values) includes: 1) Kinematic features in processes with neutrino emission (kinks and shift of the end points in β-decay energy spectra, peaks in the energy distributions of the accompanying charged leptons in 2-body decays (e.g., π-decay). 2) Neutrino decays. 3) Double-beta decays. 4) Helicity flip effects. 5) Dispersion of neutrino signals from supernova and γ-bursters. 6) Neutrino interactions with radioactive nuclei (zero-threshold effects). 7) Neutrino pair emission from metastable atoms. 6) Spectrum of the Z 0 -bursts due to annihilation of high-energy cosmic neutrinos on relic neutrinos. The phenomenology is related to the large-scale structure of the Universe and leptogenesis. What else? What are other possible manifestations of neutrino mass? Which effects are sensitive to neutrino mass? In what follows I will comment on several mentioned phenomenological consequences. . 2 1. Three observables. – There are three parameters that depend on the absolute scale of masses and not on mass differences, as oscillations. These parameters (combinations of masses and mixings) show up in cosmology, beta decays and double-beta decays. 1) Cosmology. The bounds on the sum of neutrino masses, (2)

Σ≡



mi ,

i

follow from the analysis of various sets of cosmological data (see fig. 2 from [4]). The

380

A. Yu. Smirnov

1 disfavoured by 0ν2β

Δm 223 < 0 10-2 Δm 223 > 0 10-3

99% CL (1 dof) 10-4 10-4 10-3 10-2 10-1 lightest neutrino mass in eV

disfavoured by cosmology

| m ee | in eV

10-1

1

Fig. 3. – The 90% CL range for mee as a function of the lightest neutrino mass for the normal (Δm223 > 0) and inverted (Δm223 < 0) mass hierarchies. The darker regions show the allowed range for the present best-fit values of the parameters with negligible errors; from [5].

bounds can be relaxed, e.g., by changing the equation of state of dark matter (the parameter ω). The existence of cosmic stings also weakens the bounds, etc. 2) Neutrinoless double-beta decay: Figure 3 (from [5]) shows the typical dependence of the effective mass of the electron neutrino  2 (3) mee ≡ mi Uei i

on the mass of the lightest neutrino. 3) The effective mass measured in beta decay equals (4)

me =

:

m2i |Uei |2 ,

i

 according to [6], or me = i mi |Uei |2 according to [7]. In the case of quasi-degenerate spectrum, m1 ≈ m2 ≈ m3 = m0 , which is in the range of present day sensitivity, both definitions give the same result me = m0 . The difference matters for a non-degenerate spectrum if the energy resolution of the experiment becomes comparable with the mass difference. Consider the interplay of the observables me , Σ and mee . me versus mee : their relationship can be influenced by the nature of neutrinos. Apparently, there is no connection in the case of Dirac neutrinos. Even if neutrinos are Majorana particles, contributions to mee unrelated to light neutrino masses can exist. Also in this case the relation is essentially absent.

Measurements of neutrino mass. Concluding remarks

381

me versus Σ: factors which can influence their relationship are i) non-standard neutrino properties (e.g., fast decay); ii) degeneracy of cosmological parameters; iii) nonstandard cosmology, e.g., the existence of cosmic strings. mee versus Σ: all the factors listed in the two previous cases are relevant. . 2 2. Mass-dependent processes. – The radiative decay (5)

ν2 → ν1 + γ

has a decay rate (6)

Γ ∝ m52

or

Γ ∝ m32 ,

depending on the model. If the neutrino spectrum is not strongly hierarchical, the rate is proportional to the mass difference again, but the combination is different from what we have in oscillations: Γ ∝ [(m22 − m21 )/m1 ]3 (m22 + m21 ). There are strong astrophysical bounds on this rate. The rate of non-radiative decay (7)

ν2 → ν1 + ν1 + ν¯1

equals Γ ∝ m52 . For the majoron decay, (8)

ν2 → ν1 + φ,

the rate is given by Γ = h2 m2 /16π. The charged current interactions with radioactive nuclei (9)

ν + 3 He → e− + 3 He

have zero threshold and the cross-section is proportional to the neutrino mass, σ ∝ mν [8]. Neutrino (pair) emission from metastable atoms looks intriguing in view of the closeness of the mass scales of atomic transitions and neutrino mass [9]. Here one can expect a strong enhancement of the processes: superradiance due to coherence in large volume. The processes of photon (laser) irradiated neutrino pair emission from metastable atoms, γ + Ai → νi νj + Af , and radiative pair emission, Ai → νi νj + γ + Af , have been considered [9]. Their rates are proportional to neutrino masses: Γ ∝ mi mj . . 2 3. Astrophysics and neutrino mass. – Z 0 burst: the annihilation of cosmic neutrinos on the relic neutrinos (10)

ν + ν¯ → Z 0 → hadrons

has a resonance character [10]. Since the relic neutrinos (at least two of them) are nonrelativistic, the energy of the cosmic neutrino should be E ≈ m2Z /2mi , and this same

382

A. Yu. Smirnov

energy is then released as the energy of the burst of produced particles. So, the energy spectrum of the Z 0 -bursts should have three peaks which correspond to three neutrino masses. Unfortunately, the required energies are above 1021 eV, and the existence of significant fluxes of neutrinos with such an energies is very doubtful, especially after establishing the GZK cutoff. A possibility to get information on neutrino mass from the detection of supernova neutrinos has been proposed long time ago by Zatsepin. The time delay of supernova neutrinos (with respect to massless particles) equals  (11)

Δt = 5.1 ms

L 10 kpc



10 MeV E

2 

m 2 . 1 eV

Possible effects of this delay are: – time delay with respect to some benchmarks, e.g., neutronization peak, the lightest neutrinos arrival, gravitational waves arrival; – increase of the length of the burst; – smoothing fine structures of the burst (neutronization peak, initial steep rise, abrupt interruption of signal in the case of collapse into black hole); – energy ordering; – spread of the wave packets. The problem is that for the Galactic supernova Δt is too small (smaller than all expected structures of the burst); for SN burst from other galaxies one expects too small a number of events. A rather elaborated method of analysis of the data has been proposed in [11]: a) use the high-energy part of the spectrum to reconstruct the time dependence of flux, then b) analyze the whole spectrum using the reconstructed time dependence. The conclusion is that even with high statistics and sophisticated methods, it is difficult to test masses below 1 eV. Detection of neutrino signals from γ bursters may, in principle, give stronger bounds [12]. It is not clear if any of these astrophysical effects can be used to measure the absolute scale of neutrino mass. 3. – Analysing results . 3 1. Three conclusions. – There are three important conclusions which can be drawn from the existing results. 1) Lower bound on the mass of the heaviest neutrino. Apparently mh ≥

(12)

 Δm232 .

Using recent MINOS [13] data (13)

Δm232 = (2.43 ± 0.13) × 10−3 eV2 ,

383

Measurements of neutrino mass. Concluding remarks

we obtain from (12) mh ≥ 0.049 eV.

(14)

Cosmology gives mh < 0.2 eV. 2) Bound on mass hierarchy. The lower bound on the ratio of neutrino masses equals : m2 ≥ m3

(15)

Δm221 . Δm232

Taking Δm221 = (7.66 ± 0.35) × 10−5 eV2 and Δm232 from (13), we obtain from this equation rν ≡

(16)

m2 ≥ 0.179. m3

Comparing with the corresponding ratios of masses of quarks and leptons, we conclude that neutrinos have the weakest mass hierarchy (if any) among fermions. This may be related to the large lepton mixing. Notice that r(up quarks) < rν3 . 3) Bound on the type of mass spectrum. In terms of m2 (the mass of tri-maximal mixed state, see fig. 1) other neutrino masses can be written as  (17)

m1 =

m22 − Δm221 ,

 m3 =

Δm232 + m22 .

Using these relations and the known values of Δm2 , and taking criteria of the mass degeneracy, Δm/m < 0.1, we conclude that in the case of normal mass hierarchy the spectrum can be – completely (quasi-) degenerate for m2 > 0.1 eV; – partially degenerate for 0.07 < m2 < 0.1 eV; – hierarchical m2 < 0.05 eV. In the case of inverted mass ordering, the spectrum can be either completely degenerate or partially degenerate. It seems that a possibility of non-degenerate and nonhierarchical spectrum with Δmij ∼ mk is not realized. The spectrum with “anarchy” is probably excluded. Each of these spectra has different theoretical implications. . 3 2. Heidelberg-Moscow result. – Special comments on the positive claim of the Heidelberg-Moscow experiment on 76 Ge → 76 Se + e− + e− . The latest (2006) analysis [14] has reinforced the evidence of the neutrinoless double-beta decay. The new rate (18)

25 years T1/2 = (2.23+0.44 −0.31 ) × 10

has more that 6σ deviation from zero. Being interpreted as due to exchange of light Majorana neutrino, one obtains, using new values of nuclear matrix elements, (19)

mee = 0.16–0.52 eV (2σ).

384

A. Yu. Smirnov

Fig. 4. – The allowed region of parameters from cosmological and oscillations data confronted with the HM positive claim; from [4].

This, in turn, implies a strongly degenerate mass spectrum with Σ > 0.5 eV and a serious tension with the cosmological bound, see fig. 4 from [4]. A possible way out is to assume that some other mechanism (which differs from the light Majorana neutrino exchange) is responsible for neutrinoless double-beta decay. Alternatively one may “play” with cosmological uncertainties. . 3 3. Beyond the Standard Model . – Two facts are on the basis of the claim that the discovery of neutrino oscillations is the evidence of physics beyond the SM. 1) Smallness of neutrino mass within a given generation: For the third generation we have (20)

m3 = (0.3–1) · 10−10 , mτ

which should be compared with another mass ratio from the same family mτ /mt ∼ 10−2 . Another scale which is the closest one to the neutrino mass is the scale of Dark Energy in the Universe, 10−3 eV, and there is a number of speculations on how these scales can be connected. 2) Pattern of neutrino mixing with two large angles. 4. – Nature of neutrino mass Here the main issues are: i) Majorana versus Dirac, ii) hard versus soft, iii) effective versus fundamental. Are neutrino masses qualitatively the same as quark masses? In

Measurements of neutrino mass. Concluding remarks

385

fact, the observed smallness of neutrino masses may indicate something different: new contributions to neutrino mass which cannot be seen in masses of other particles. The main line of thinking is that masses and mixing have a pure vacuum origin; they are generated at the electroweak, and probably, higher energy scales. These are “hard” masses. The VEV’s involved are large or, if small, induced by other large VEV’s, as in the case of type-II see-saw. In general (21)

mν = mhard + msoft (E, n),

where msoft (E, n) is the medium-dependent soft component which can be substantial for neutrinos and not for other particles. For instance, according to the MaVaN scenario [15], soft neutrino masses can be generated due to the exchange of very light scalar particles with mφ = 10−8 –10−6 eV between neutrinos and particles of the medium: νL + fR → νR + fL (f = e, u, d, ν). Introducing the corresponding Yukawa couplings λf and number density nf , we find the mass msoft = λν λf nf /mφ . Another soft contribution to neutrino mass may come, e.g., from unparticles. According to the unparticle physics scenario [16], the hidden sector (HS) of theory includes the gauge theory with fermions. The number of fermions in the HS is such that the effective gauge coupling g increases with the decrease of energy and at the energies below a certain scale ΛU approaches the infrared fixed point g → g ∗ . If g ∗  1 fermions form composite (confined) states. This transition is similar, to some extent, to the transition from quarks to hadrons below ∼ ΛQCD . Particles of HS couple to the SM particles via exchange of messenger fields with mass M  ΛU . At energies below M the interaction of SM particles with HS particles is described by the effective interactions 1 OSM OU V , Mk

(22)

where OSM and OU V are operators which depend on the SM and HS fields, respectively. In analogy with QCD, one can consider, e.g., that OSM is the leptonic operator, whereas OU V is the quark operator. Below ΛU the operator OU V transforms into the operator of composite (confined) states OU (e.g., “pion”): OU V → OU and the interaction (22) becomes (23)

C

ΛdUU V −dU OSM OU , Mk

where dU V and dU are dimensions of operators OU V and OU , respectively. The key difference from the hadron case is that here, due to scale invariance (no energy gap), the confined states have a continuous mass spectrum [17,18]. In the QCD case the spectrum is discrete. As a result, individual mass modes have an infinitesimal effect. Finite effects of production and exchange of unparticles appear as a consequence of the integration over the spectrum (integration over the mass) of composite states.

386

A. Yu. Smirnov

As far as applications to neutrinos are concerned, several processes have been considered: the neutrino decays νi → νj + U [19, 20], scattering on electrons να e → νβ e via an unparticle exchange [20]. The exchange of unparticles influences the refraction: modifies matter potential (in the case of vector operators). In the case of scalar unparticles, the effective neutrino mass is generated. This, in turn, modifies the conversion probabilities in matter [21]. An important phenomenological and experimental problem is to put model-independent experimental limits on (or discover) msoft . The existence of extra spatial dimensions opens qualitatively new possibilities to generate small Dirac masses of neutrinos. The left and the right components of neutrinos can have different localizations in extra dimensions. The value of the Yukawa coupling in 4D is then proportional to the degree of overlap of the LH and RH component of the wave functions or the overlap factor κ. Then neutrino mass in 4D can be written as (24)

mD = λvEW ξ,

where λ ∼ 1 and vEW is the electroweak VEV. Due to the fact that the RH neutrinos have no SM interactions, their localization can be substantially different, which leads to strong suppression of masses. This mechanism can be called overlap suppression. Let us evaluate the overlap (suppression) factor in different scenarios with extra dimensions. 1) Large flat extra dimensions; ADD-scenario. The 3D spatial brane is embedded in (3 + δ)D bulk of extra dimensions. Extra dimensions have large radii Ri  1/MPl which allows one to reduce the fundamental scale of theory down to M ∗ ∼ 10–100 TeV. The left-handed neutrino is localized on the brane, whereas the right-handed component (being a singlet of the gauge group) propagates in the bulk. For one extra D with coordinate y the normalization condition gives a typical value of the wave function √ νR (y) ∼ 1/ R. The width of the brane is of the order d ∼ 1/M ∗ , therefore the overlap factor with the LH component which is localized on the brane equals (25)

1 ξ = d1/2 νR ∼ √ . M ∗R

 For δ extra dimensions, we get for the overlap factor ξ = 1/ M ∗δ Vδ , where Vδ is the volume of extra dimensions. 2) Warped extra dimensions; Randall-Sundrum setup. Two branes, the visible and the “hidden”, are localized in different points of the extra dimension with non-factorizable metric. The wave function of the RH neutrino νR (φ) is centered on the hidden brane, whereas the LH one on the visible brane. Due to warped geometry, νR exponentially decreases from the hidden to the observable brane. The overlap factor is given by the value of νR on the visible brane (26)

ξ = ν R (vis) ∼ ν−1/2 ,

 = e−krc π =

vEW . MPl

Measurements of neutrino mass. Concluding remarks

387

Here MPl is the Planck scale, rc is the radius of extra dimension, k ∼ MPl is the curvature parameter. In (26) ν ≡ m/k and m ∼ MPl is the Dirac mass in 5D. For ν = 1.1–1.6, we obtain the mass in the required range. 5. – Masses and mixing What is the connection between masses and mixing? Can we obtain certain predictions for values of masses using information about mixing? . 5 1. Test equalities. – On pure phenomenological ground, one can connect the effective mass mee with the oscillation parameters making certain assumptions on neutrino mass spectrum and the Majorana CP phases. The experimental confirmation of such equalities which we can call the test equalities with high enough precision would testify for a given scenario. Some examples follow. 2 1) Normal mass hierarchy, Ue3

0.04: (27)

mee = sin2 θ12

 Δm221 .

2) Inverted mass hierarchy, opposite CP parities of ν1 and ν2 : (28)

mee = cos 2θ12

 Δm231 ;

the same CP parities give in this case  (29)

mee =

Δm231 .

3) Degenerate spectrum with the same CP parities would lead to (30)

mee = me

and opposite parities give (31)

mee = cos 2θ12 me .

If it turns out that one of these equalities is satisfied with high precision, it will be difficult the believe that this is accidental. . 5 2. Three lines in the bottom-up approach. – Are small neutrino masses related to a strange mixing pattern? What is behind this pattern? Symmetry? If so, what are the implications of this symmetry for mass spectrum? There are three lines of studies in the bottom-up approach with different implications for fundamental physics and with different connections between masses and mixing.

388

A. Yu. Smirnov

1) Tri-bimaximal mixing (TBM). The tri-bimaximal mixing matrix is defined as [22] √ ⎞ 2 2 √0 √ 1 m ⎠ ≡ U23 U12 (θ12 ) = √ ⎝−1 √2 √3 , 6 3 1 − 2 ⎛

(32)

Utbm

m is the maximal (π/4) rotation in the 2-3 plane and sin2 θ12 = 1/3. It agrees where U23 within 1σ with the present experimental results. An immediate implication of this possibility is flavor symmetry. The majority of models proposed so far are based on the discrete symmetry group A4 [23]. Other possibilities include models based on the groups T  , D4 , S3 , S4 , Δ(3n2 ). Extension of these symmetries to quarks is however, problematic, it requires a further complication of the models. TBM may indicate that quarks and leptons are fundamentally different. Mixing is not related (at least in a straightforward way) to masses. Relations between masses and mixing may appear if some bigger structure exists which includes the proposed discrete symmetries and also predicts masses. In this case one would expect some particular relations between masses. 2) Quark-Lepton Complementarity (QLC). QLC [24] is based on observations that q q l l θ12 + θ12 ≈ π/4 and θ23 + θ23 ≈ π/4. It is difficult to expect exact equalities but a certain correlation exists: the 1-2 leptonic mixing deviates from maximal substantially because the quark 1-2 mixing (Cabibbo angle) is not small, the 2-3 leptonic mixing is close to maximal because the 2-3 quark mixing (Vcb ) is small. A general scheme for QLC: “lepton mixing = bi-maximal mixing − CKM”, where the bi-maximal mixing matrix, Ubm , is defined as √ ⎛√ ⎞ 2 2 √0 1 m m (33) Ubm ≡ U23 U12 = ⎝−1 1 √2⎠ . 2 2 1 −1

Two extreme realizations of the complementarity, QLCν and QLCl , are determined by the order of the bi-maximal and CKM rotations: (34)

† UPMNS = Ubm UCKM (QLCl ),

† UPMNS = UCKM Ubm (QLCν ).

Implications: – Quark-lepton symmetry or unification (apparently leptons should know about quark mixing). Alternatively, the information about quark mixing can be communicated to the lepton sector via the horizontal (flavor) symmetry. – Existence of a structure which produces the bi-maximal mixing. It can be the see-saw itself with certain properties of the RH neutrino mass matrix. The latter may require a certain symmetry. Again there is no straightforward connection of mixing to masses. 3) Quark-lepton universality. This approach does not rely on any specific symmetry in the lepton sector. The mass (Yukawa coupling) matrices of quarks and leptons have

389

Measurements of neutrino mass. Concluding remarks

no fundamental distinction. The whole difference is related probably to the see-saw mechanism itself which explains simultaneously the smallness of neutrino mass and large lepton mixing. Mass matrices of quarks and leptons are constructed on the basis of the same principles, and furthermore, masses and mixing are related with each other. “The same principles” could be the Froggatt-Nielsen mechanism based on U (1)-flavor symmetry. Large lepton mixing can be related to weak mass hierarchy of neutrinos. The mass spectrum is expected to be hierarchical unless a screening mechanism is realized (see later). TBM and the two versions of QLC differ by predictions of the 1-2 and 1-3 mixing angles (θ12 , θ13 ): (35)

QLCν : (35.4◦ , 9◦ ),

TBM : (35.2◦ , 0),

QLCl : (32.2◦ , 1.5◦ ).

Notice that θ12 (QLCl ) = π/4 − θC and θ12 (QLCν ) ≈ θ12 (TBM). All three possibilities agree with the present data within 1σ. Clearly, the combination of future precise measurements of these angles will disentangle the schemes. At the same time the predictions can be changed due to the appearance of CP violation phases and by RGE effects. Furthermore, in specific models, some additional corrections appear due to violation of the underlying symmetry. Small deviations from the predictions do not exclude the context. Exact confirmation would be very demanding and restrictive. . 5 3. Absolute scale without measurements. – In the following situations we can conclude about the absolute scale without measurements of masses, e.g., by kinematic method (recall, the answer may come from an unexpected side): 1) Establish that the spectrum is hierarchical. 2) Put the upper bound on the lightest neutrino mass (studying, e.g., the dispersion of the burst from SN). 3) Confirm the scenario which predicts the hierarchical mass spectrum such as – “ νMSM [25]; – some GUT models. 4) Measure the rates of processes such as neutrino decay, further study of the LSS of the Universe. 5) Using LHC, uncover the electroweak-scale mechanisms of neutrino mass generation e.g., with Higgs triplet bosons, measure its couplings. It would be interesting to check whether positive results from these indirect studies will coincides with results of the direct measurements. 6. – Predicting neutrino mass Do we have at least some models or context which lead to the predictions of neutrino mass? . 6 1. Koide relations. – The Koide relations are pure mass relations [26]. (In fact, there is no reason to consider the tri-bimaximal mixing but ignore the Koide relations.

390

A. Yu. Smirnov

Furthermore, they may be related.) Recall that the equality (36)

2 m e + mμ + mτ = √ √ √ ( me + mμ + mτ )2 3

is satisfied with an accuracy of 10−5 for mass shell and with 10−3 at Mz . All three families are involved substantially: no perturbation approach is possible. The relation (36) has been obtained in attempts to explain (37)

tan θC =

√

√ √ mμ − me 3 √ . √ √ 2 mτ − me − mμ

Both relations can be reproduced if (38)

2

mi = m0 (zi + z0 ) ,



zi = 0,

z0 =

i

:

zi2 /3.

i

Brannen [27] has generalized the relation to neutrinos: (39)

2 m1 + m2 + m3 = , √ √ 2 (− m1 + m2 + m3 ) 3 √

where the minus sign in front of the first term in the denominator is crucial. According to (39), neutrinos have a hierarchical spectrum with m1 = 3.9 · 10−4 eV. Non-Abelian flavor symmetry and specific VEV alignment can be behind the relations. . 6 2. Main line. – The dominant line of thinking is that 1) The smallness of the neutrino mass is related to the Majorana nature of neutrinos and eventually to zero values of the conserved charges (electric and QCD). 2) The see-saw scenario is realized: “small = (normal)2 /Large”, where small = masses of usual neutrinos; normal = the electroweak scale 100 GeV; large = masses of “right neutrinos”. 3) The same mechanism explains the large lepton mixing. The large-scale Λ is the scale of new physics. Different realizations of the see-saw depend on which is the carrier of this new scale (physics) and on the size of the scale. In the simplest version Λ is just the bare mass of the RH neutrino. In general, there is some particle sector and dynamics behind. Various realizations have been proposed with Λ √ equal to MPl (which requires many RH neutrinos), or MGUT , or MPl MEW , or MEW . In the νMSM scenario [25] the mass Λss ∼ 0.1–0.5 GeV. Even an extreme possibility, Λ = few eV, is not excluded [28]. All this means that physics behind the neutrino mass is not yet identified. The scale of the RH neutrinos is in favor of GUT. In fact, the value of the mass of the heaviest RH neutrino can coincide with the GUT scale MR ≈ MGUT ∼ 1016 GeV, which can be achieved in the presence of mixing of three generations. Alternatively,

Measurements of neutrino mass. Concluding remarks

391

the scale of RH neutrino masses can be related to MGUT via the Planck scale MPl : 2 MR ≈ MGUT /MPl ∼ 1014 GeV. (The latter is realized, e.g., in the double-see-saw scenario [29].) 7. – Implications of the neutrino mass measurements Why measurements of mν are important? There are three reasons: 1) Knowledge of mν opens new possibilities of the determination of other neutrino parameters, e.g. the type of the neutrino mass spectrum. 2) It is important for implications for fundamental physics: – mechanism of neutrino mass generation, explanation of its smallness; – identification of the underlying physics; – origin and nature of neutrino mass; – flavor symmetry; – difference of mixing patterns of the quarks and leptons. 3) It provides a new way to search for new physics: A comparison of the values of neutrino masses determined in different processes may reveal something new. . 7 1. Type of spectra and implications. – Different types of mass spectra may have different implications for fundamental theory. Some examples follow: A) Normal mass ordering: – degenerate spectrum (m2 > 0.1 eV), m1 ≈ m2 ≈ m3 , would imply a non-Abelian flavor symmetry; – partially degenerate spectrum, m2 = 0.02–0.06 eV, m1 ≈ m2 ∼ m3 , testifies for pseudo-Dirac neutrino and weakly broken U (1); – hierarchical spectrum m2 < 0.01 eV, m1 m2 m3 , may indicate on U (1) symmetry, in the Froggatt-Nielsen scenario. B) In the case of inverted ordering: – degenerate spectrum m2 > 0.1 eV, m1 ≈ m2 ≈ m3 , would imply a non-Abelian flavor symmetry; – partially degenerate spectrum m2 = 0.02–0.06 eV, m1 ≈ m2 > m3 , again, pseudoDirac neutrino and weakly broken U (1); – partially hierarchical (hierarchical-degenerate) spectrum m2 < 0.01 eV, m2 ≈ m1  m3 , would testify for U (1) (Le − Lμ − Lτ ), or non-Abelian symmetries. . 7 2. Quasi-degenerate spectrum. – This spectrum is of special interest: the HeidelbergMoscow result may testify for that. It is in the range of sensitivity of the forthcoming experiments. This spectrum is the most interesting and unusual from the point of view of what we know now. Being identified this possibility would imply different sources of neutrino masses, unrelated to the Dirac mass matrices of the charged leptons and quarks. There are two possible realizations: 1) Higgs triplet, type-II see-saw;

392

A. Yu. Smirnov

2) Screening of Dirac structure in the double see-saw. Here three additional singlets, S, which belong to families, couple to the RH neutrinos. In the basis (ν, ν c , S) the mass matrix has the form ⎛ (40)

0 ⎝mTD 0

mD 0 MT

⎞ 0 M ⎠, MS

due to certain symmetries including the lepton number one. It leads to the light neutrino masses (41)

m = −mTD (M −1 )T MS M −1 mD .

As a consequence of some horizontal symmetry or Grand unification, the two Dirac mass matrices can be proportional to each other: (42)

MD = A−1 mD ,

A ≡ vEW /VGU .

They cancel each other in (41) and for the light neutrinos we obtain (43)

mν = A2 MS .

That is, the structure of the light neutrino mass matrix is determined by MS immediately and does not depend on the Dirac mass matrix. If MS = I, the light neutrinos will be degenerate. Corrections to this scheme can lead to the desirable mass splitting. . 7 3. Applications. – The role of mν measurements in a more general framework can be outlined in the following way. 1) In the Standard neutrino scenario mν is the key element of the picture, it determines the type of mass spectrum. 2) Searches for physics beyond standard scenario: New neutrino states can lead, e.g., to additional kinks in the energy spectra of decays. Non-standard interactions and new dynamics can generate additional contributions to neutrino mass. Violation of the fundamental symmetries may show up first via neutrino masses (e.g., CPT violation may imply different mass spectra of neutrino and antineutrinos). 3) Understanding the fermion masses. Properties of neutrino mass matrix. 4) Unification of particles and forces. Let us underline two aspects. Cosmology: Knowledge of neutrino mass is important for the determination of other cosmological parameters. The mass determines the neutrino structure of the Universe which could include neutrino stars and clouds, neutrino halos of galaxies and clusters of Galaxies [30]. The existence of new neutrino interactions can lead to instabilities in the neutrino sea, neutrino condensation, superfluidity [31], etc. All this determines

Measurements of neutrino mass. Concluding remarks

393

a local (near the Earth) concentration of neutrinos and therefore important for possible detection of relic neutrinos. Kinematics: as we have already mentioned, the neutrino mass enters the probabilities of the processes. However, they are too small and irrelevant for existing and probably future measurements. The hope is that they still can show up in some exotic cases. Neutrino mass determines the rates of rare processes like neutrino decay, zero-threshold scattering, etc. 8. – In conclusion of concluding remarks In conclusion, instead of a summary, I would like to ask several questions. What is the mass of the heaviest neutrino? What are the processes sensitive to neutrino mass? Is something missed? What is the type of neutrino mass spectrum: degenerate, partially degenerate, hierarchical? What is the nature of neutrino mass? Majorana versus Dirac; hard versus soft. What are the bounds on soft contributions? How light is the lightest neutrino? Is mixing related to mass? Can we establish the absolute mass scale without direct measurements of neutrino masses? Can we find some more test equalities or even create a catalog of these equalities? This question is for experimentalists: What are the fundamental limitations of the sensitivity of different experimental techniques: spectrometers, bolometric measurements [32]? ∗ ∗ ∗ I would like to thank F. Vissani for hospitality during my stay in Varenna. REFERENCES [1] For a comprehensive list of references, see the reviews: Strumia A. and Vissani F., arXiv:hep-ph/0606054; Gonzalez-Garcia M. C. and Maltoni M., Phys. Rep., 460 (2008) 1; Mohapatra R. N. and Smirnov A. Y., Annu. Rev. Nucl. Part. Sci., 56 (2006) 569; Altarelli G. and Feruglio F., New J. Phys., 6 (2004) 106; King S. F., Rep. Prog. Phys., 67 (2004) 107. [2] Osipowicz A. et al. (KATRIN Collaboration), arXiv:hep-ex/0109033. [3] Pontecorvo B., Zh. Eksp. Theor. Fiz., 33 (1957) 549; Zh. Eksp. Theor. Fiz. 34 (1958) 247. [4] Fogli G. L. et al., Phys. Rev. D, 78 (2008) 033010. [5] Strumia A. and Vissani F., in [1]. [6] Vissani F., hep-ph/0102235. [7] Farzan Y. and Smirnov A. Y., Phys. Lett. B, 557 (2003) 224. [8] Weinberg S., Phys. Rev., 128 (1962) 1457; Cocco A. G., Mangano G. and Messina M., J. Cosmol. Astroparticle Phys., 0706 (2007) 015 (J. Phys. Conf. Ser., 110 (2008) 082014) [arXiv:hep-ph/0703075]; Lazauskas R., Vogel P. and Volpe C., J. Phys. G, 35 (2008) 025001 [arXiv:0710.5312 [astro-ph]]. [9] Yoshimura M., Phys. Rev. D, 75 (2007) 113007; Yoshimura M. et al., arXiv:0805.1970.

394

A. Yu. Smirnov

[10] Weiler T. J., Astropart. Phys., 11 (1999) 303. [11] Nardi E. and Zuluaga J. I., Nucl. Phys. B, 731 (2005) 140; Phys. Rev. D, 69 (2004) 103002. [12] Choubey S. and King S. F., Phys. Rev. D, 67 (2003) 073005. [13] Adamson P. et al. (MINOS Collaboration), arXiv:0806.2237 [hep-ex]. [14] Klapdor-Kleingrothaus H. V. and Krivosheina I. V., Mod. Phys. Lett. A, 21 (2006) 1547. [15] Hung P. Q., hep-ph/0010126; Peihong Gu, Xiulian Wang and Xinmin Zhang, Phys. Rev. D, 68 (2003) 087301; Fardon R., Nelson A. E. and Weiner N., J. Cosmol. Astroparticle Phys., 0410 (2004) 005; hep-ph/0507235; Kaplan D. B., Nelson A. E. and Weiner N., Phys. Rev. Lett., 93 (2004) 091801. [16] Georgi H., Phys. Rev. Lett., 98 (2007) 221601; Phys. Lett. B, 650 (2007) 275. [17] Krasnikov N. V., Phys. Lett. B, 325 (1994) 430; arXiv:0707.1419. [18] Stepanov M. A., Phys. Rev. D, 76 (2007) 035008. [19] Anchordoqui L. and Goldberg H., ArXiv:0709.0678 [hep-ph]. [20] Shun Zhou, ArXiv:0706.0302 [hep-ph]. [21] Gonzalez-Garcia M. C., de Holanda P. C. and Zukanovich-Funchal R., ArXiv:0803.1180 [hep-ph]. [22] Wolfenstein L., Phys. Rev. D, 18 (1978) 958; Harrison P. F., Perkins D. H. and Scott W. G., Phys. Lett. B, 458 (1999) 79; Phys. Lett. B, 530 (2002) 167. [23] Ma E., Mod. Phys. Lett. A, 17 (2002) 2361; Rajasekaran G., Phys. Rev. D, 64 (2001) 113012; Babu K. S., Ma E. and Valle J. W. F., Phys. Lett. B, 552 (2003) 207. [24] Smirnov A. Yu., hep-ph/0402264; Raidal M., Phys. Rev. Lett., 93 (2004) 161801; Minakata H. and Smirnov A. Yu., Phys. Rev. D, 70 (2004) 073009. [25] Asaka T., Blanchet S. and Shaposhnikov M., Phys. Lett. B, 631 (2005) 151; Asaka T. and Shaposhnikov M., Phys. Lett. B, 620 (2005) 17. [26] Koide Y., Lett. Nuovo Cimento, 34 (1982) 201; Phys. Rev. D, 28 (1983) 252. [27] Brannen C. A., http://brannenwork.com (2006). [28] de Gouvea A., Jenkins J. and Vasudevan N., Phys. Rev. D, 75 (2007) 013003. [29] Mohapatra R. N., Phys. Rev. Lett., 56 (1986) 561; Mohapatra R. N. and Valle J. W. F., Phys. Rev. D, 34 (1986) 1642. [30] Ringwald A. and Wong Y. Y. Y., J. Cosmol. Astroparticle Phys., 0412 (2004) 005 [arXiv:hep-ph/0408241]. [31] Kapusta J. I., Phys. Rev. Lett., 93 (2004) 251801; Bhatt J. R. and Sarkar U., arXiv:0805.2482. [32] Andreotti E. et al., Nucl. Instrum. Methods A, 572 (2007) 208.

POSTERS

This page intentionally left blank

DOI 10.3254/978-1-60750-038-4-395

νe and ν¯e disappearance in Gallium and reactor experiments M. A. Acero Dipartimento di Fisica Teorica, Universit` a di Torino e INFN, Sezione di Torino - Torino, Italy Laboratoire d’Annecy-le-Vieux de Physique Th´ eorique LAPTH, Universit´ e de Savoie Annecy-le-vieux Cedex, France

C. Giunti INFN, Sezione di Torino - Torino, Italy

M. Laveder Dipartimento di Fisica “G. Galilei”, Universit` a di Padova, e INFN, Sezione di Padova Padova, Italy

Summary. — The disappearance of electron neutrinos observed in the Gallium radioactive source experiments is analyzed in the effective framework of two-neutrino mixing. We found an indication of neutrino disappearance due to neutrino oscillations with a square-mass difference much larger than those observed in solar and atmospheric neutrino experiments. We studied the compatibility of this result with the data of the Bugey and Chooz reactor short-baseline antineutrino disappearance experiments. We found an indication in favor of neutrino oscillations with 1.8 eV2  Δm2  1.9 eV2 , from the Bugey data, which is compatible with the Gallium allowed region of the mixing parameters. This indication persists in the combined analyses of Gallium, Bugey, and Chooz data.

1. – Introduction Solar, atmospheric, reactor and accelerator neutrino experiments give very robust evidence of three-neutrino mixing [1, 2]. However, data from LSND, MiniBooNE (at low energy) and the Gallium radioactive source experiments show some anomalies which open a window to the possible existence of exotic neutrino physics beyond three-neutrino mixing. The Gallium radioactive source experiments (GALLEX [3] and SAGE [4, 5]) measured a lower electron neutrino flux than the expected one. This can be interpreted as an indication of the disappearance of electron neutrinos due to neutrino oscillations [6]. c Societ`  a Italiana di Fisica

395

396

M. A. Acero, C. Giunti and M. Laveder

Fig. 1. – Left: allowed region in the oscillation parameter space for the individual Gallium radioactive source experiments. Right: allowed regions in the oscillation parameter space and marginal Δχ2 ’s for the combined fit of the results of the four radioactive source experiments.

2. – Gallium experiments The Gallium radioactive source experiments consist in the detection of electron neutrinos produced by artificial 51 Cr and 37 Ar radioactive sources which decay through electron capture e− + 51 Cr → 51 V + νe and e− + 37 Ar → 37 Cl + νe . The neutrinos are detected through the reaction νe + 71 Ga → 71 Ge + e− . We present the results of the fit of the data of Gallium radioactive source experiments in terms of effective two-neutrino oscillations. The survival probability of electron (anti)neutrinos with energy E at a distance L from the source is given by   Δm2 L 2 2 (1) P(−) (−)(L, E) = 1 − sin 2ϑ sin , 4E νe →νe where ϑ is the mixing angle and Δm2 is the squared-mass difference (see refs. [1, 2]). We use the theoretical value of the ratio R of the predicted 71 Ge production rates in each of the Gallium radioactive source experiments in the cases of presence and absence of neutrino oscillations given by B  dV L−2 i (B.R.)i σi Pνe →νe (L, Ei ) B  (2) R= , −2 i (B.R.)i σi dV L where σi is the cross-section and (B.R.)i the branching ratio of the i-th νe line emitted in Cr and 37 Ar decays. The result of the individual and combined least-squares analysis of the four Gallium source experiments is shown in fig. 1. One can see that there is an allowed region in the sin2 2ϑ–Δm2 plane at 1σ for Δm2  0.6 eV2 and 0.08  sin2 2ϑ  0.4. 51

3. – Bugey and Chooz reactor experiments Reactor neutrino experiments detect antineutrinos through the reaction ν¯e + p → n + e+ . In this process, the neutrino energy is related to the positron energy by Eν = Ee+ +

397

νe and ν¯e disappearance in Gallium and reactor experiments

Table I. – Values of χ2min , number of degrees of freedom (NDF) and best-fit values of sin2 2ϑ and Δm2 from the fit of different combinations of the results of the Gallium radioactive source experiments and the Bugey and Chooz reactor experiments. χ2min NDF GoF sin2 2ϑbf Δm2bf (eV2 )

Ga

Bu

Ga + Bu

Bu + Ch

Ga + Ch

Ga + Bu + Ch

2.69 2 0.26 0.23 2.00

46.55 53 0.72 0.043 1.85

52.59 57 0.64 0.057 1.85

47.12 54 0.73 0.036 1.85

6.57 3 0.087 0.079 1.73

53.40 58 0.65 0.05 1.85

1.8 MeV. The Bugey experiment used three source-detector distances (Lj = 15, 40, 95 m for j = 1, 2, 3), while in Chooz, the distance was about 1 km. For the Bugey experiment we use the ratio of observed and expected (in the case of no oscillation) positron spectra given in fig. 17 of ref. [7], in which there are Nj = 25, 25, 10 energy bins (data). We analyze the data with the following χ2 : ⎧ ⎫ Nj  exp 2 3 ⎨ 2⎬ 2 the  (Aa + b (E − E )) R − R (a b2 (A − 1) − 1) j ji 0 ji j ji + + , + (3) χ2 = 2 2 ⎩ σji σa2j ⎭ σA σb2 j=1 i=1 where Eji is the central energy of the i-th bin in the positron kinetic energy spectrum measured at the Lj source-detector distance; the coefficients (Aaj + b(Eji − E0 )) are introduced to account for the systematic uncertainty of the positron energy calibration [7]; exp Rji is the measures ratio and B +∞ B E +ΔE /2 B dL L−2 Ejiji−ΔEjj/2 dE −∞ dTe F (E, Te ) Pν¯e →¯νe (L, Eν ) the B , (4) Rji = ΔEj dL L−2 here F (E, Te ) is the energy resolution function of the detector. The Chooz experiment gives constrains on sin2 2ϑ for Δm2  10−3 eV2 . Therefore, for our purpose, the Chooz experiment is only sensitive to the average survival probability P(−) (−) = 1 − 12 sin2 2ϑ. The allowed regions obtained from our fits are shown in fig. 2, νe →νe

while the best fit values of the mixing parameters are reported in table I. 4. – Conclusions In the framework of two-neutrino mixing, we found that, from the analysis of the Gallium radioactive source experiments, there is an indication of electron neutrino disappearance due to neutrino oscillations with sin2 2ϑ  0.03 and Δm2  0.1 eV2 . This result is compatible with the data form Bugey and Chooz reactor experiments. Besides, the Bugey data present an indication in favor of neutrino oscillations with 0.01  sin2 2ϑ  0.07 and 1.8 eV2  Δm2  1.9 eV2 . Such a disappearance of electron neutrinos due to Δm2  0.1 eV2 is an indication of the possible existence of at least one light sterile neutrino with a mass of the order of about 1 eV.

398

M. A. Acero, C. Giunti and M. Laveder

Fig. 2. – Top: allowed region in the oscillation parameter space and histograms with the best fit the the ; dashed: Rji , obtained from for the Bugey reactor experiment (solid: (Aaj + b(Eji − E0 ))Rji see eq. (3)). Lower left: allowed regions in the oscillation parameter space from the combined fit of the Bugey and Chooz reactor experiments. Lower right: allowed regions from the combined fit of the Gallium radioactive source experiments and the Bugey and Chooz reactor experiments.

∗ ∗ ∗ We would like to express our gratitude to Y. Declais for giving us detailed information on the Bugey experiment. M.A.A. would like to thank the International Doctorate on AstroParticle Physics (IDAPP) for financial support. C.G. would like to thank the Department of Theoretical Physics of the University of Torino for hospitality and support. REFERENCES [1] Bilenky S. M. and Petcov S. T., Rev. Mod. Phys., 59 (1987) 671. [2] Giunti C. and Kim C. W., Fundamentals of Neutrino Physics and Astrophysics (Oxford University Press) 2007. [3] GALLEX, Hampel W. et al., Phys. Lett. B, 420 (1998) 114. [4] SAGE, Abdurashitov J. N. et al., Phys. Rev. C, 59 (1999) 2246, arXiv:hep-ph/9803418. [5] Abdurashitov J. N. et al., Astropart. Phys., 25 (2006) 349, arXiv:nucl-ex/0509031. [6] Acero M. A., Giunti C. and Laveder M., arXiv:0711.4222. [7] Bugey, Achkar B. et al., Nucl. Phys. B, 434 (1995) 503.

DOI 10.3254/978-1-60750-038-4-399

Feasibility study for a measurement of the QE νμ CC cross-section with the ArgoNeuT liquid-argon TPC M. Antonello on behalf of the ArgoNeuT Collaboration INFN, Laboratori Nazionali del Gran Sasso - Assergi (AQ), Italy

Summary. — The present paper reports a feasibility study for the measurement of the QE CC (Quasi Elastic Charged Current) cross-section for the νμ -nucleus interaction in liquid argon in the few GeV region, using the ArgoNeuT detector on the NuMI Beam and the MINOS near detector as muon catcher. The number of QE νμ CC events expected in 180 days is about 4700 and the relative statistical error between 1 and 4 GeV is at the level of 4%, below the beam systematics.

1. – Introduction Following the recent discovery of neutrino oscillation in the atmospheric neutrino sector and the subsequent confirmation by the long-baseline K2K and MINOS experiments, the next step in studying neutrino mass and mixing are: 1) determine the rate of νμ → νe oscillation in the “atmospheric” oscillation length, characterized by the mixing angle θ13 ; 2) determine the ordering of the three neutrino mass states, known as the “mass hierarchy”; 3) determine whether there is CP violation in the neutrino sector. Assuming typical values of θ13 5◦ , θ23 45◦ , Δm213 2.4 × 10−3 eV2 and a baseline of about 1000 km (typical of the current long-baseline experiments) the oscillation probability becomes maximum in the few GeV region. 2. – The cross-section problem At the few GeV energy scale, that long-baseline experiments are supposed to probe, the main uncertainties come from the poor knowledge of the neutrino-nucleus interacc Societ`  a Italiana di Fisica

399

400

M. Antonello on behalf of the ArgoNeuT Collaboration

tion cross-section. Measurements for ν cross-section determination are available from old data [1,2] with errors around 20–30% in the GeV region. Moreover, only the simplest exclusive channels have been considered. A series of dedicated experiments for cross-section measurements is considered as a high-priority goal for the next few years. A detector based on the Liquid Argon TPC (LAr TPC) technology, developed by the ICARUS Collaboration [3], is one of the best candidate for such a measurement [4], to be exposed to an intense neutrino beam with a well-controlled beam profile. It provides unique features in energy and direction measurements for muons (electrons) and protons (the final-state particles emerging from Quasi Elastic (QE) νμ (νe ) interactions) as well as for pions (emerging from ν-induced nucleon resonances decay). Clean particle identification properties are accomplished when the full containment of the particle tracks in LAr is guaranteed in relatively modest volumes. 3. – The ArgoNeuT detector at the NuMI beam ArgoNeuT [5] is a joint NSF/DOE R&D project at Fermilab (USA) to expose a small liquid-argon TPC (350 kg of LAr) on-axis to the NuMI (Neutrinos at the Main Injector) low-energy neutrino beam [6]. By taking measurements in the 0.1 to 10 GeV range, ArgoNeuT will produce the first ever data for low-energy neutrino interactions within a LAr TPC. ArgoNeuT will also serve as a stepping stone to larger detectors (such as MicroBooNE [7] and LAr5 [8]). The ArgoNeuT detector is presently under construction, with data taking expected to start in July 2008 and last several months. ArgoNeuT will sit upstream the MINOS Near Detector (ND) in the NuMI Tunnel (100 m underground). In fig. 1 the energy spectrum of the NuMI on-axis beam is shown. The flux is known with a 5–10% precision and the mean muon neutrino energy is about 3.7 GeV. The neutrino intensity is Φν = 3 × 1010 ν/cm2 for 1018 POT. 4. – The QE νμ CC cross-section measurement In the few GeV energy range the ν-nucleus interactions are dominated by the QE channel. A feasibility study for the QE νμ CC cross-section measurement is reported hereafter. As a first issue, the total number of νμ CC neutrino events per day (assuming 8 · 1017 POT/day) and the relative energy distribution, as a function of incident neutrino energy, have been calculated taking into account the actual active mass of the ArgoNeuT detector. The cross-sections (as a function of the incident neutrino energy) have been calculated independently for the three channels (QE, RES and DIS) from two independent codes/models (GENEVE [9] and LIPARI [2]) and convoluted with the onaxis NuMI beam spectrum. The expected number of νμ CC events (referred to events with the vertex contained in the LAr active volume) obtained using the LIPARI MC code are: 26.6 events/day in the QE channel, 21.8 events/day in the RES channel and 118.5 events/day in the DIS channel, for a total of 166.9 events/day. Using GENEVE MC code the number of QE νμ CC events is expected to be 25.2 events/day (in agreement with LIPARI code result).

401

10

2

Num. of QE Events

νμ νε νμ bar νε bar

6

flux (ν/m /0.5GeV/10 POT)

Feasibility study for a measurement of the QE νμ CC cross-section etc.

2

10

10

3

10

2

10

1

1

0

1

2

3

4

5

6

7

8

9

10

relative error (%)

Eν (GeV)

-1

10

10

-2

10

0

2

4

6

8

10

12

14

16

18

20

1

0

Eν (GeV)

Fig. 1

1

2

3

4

5

6

7

8

9

10

Eν (GeV)

Fig. 2

Fig. 1. – NuMI on-axis beam energy spectrum. Fig. 2. – Top: QE νμ CC events energy distribution (GENEVE Monte Carlo). Bottom: relative statistical error (bin size 0.5 GeV).

Assuming a run period of 180 days (i.e. the time needed to collect 1.4 × 1020 POT), the QE νμ CC events distribution (GENEVE MC) as a function of incident neutrino energy has been calculated (fig. 2, top). About 4700 QE νμ CC interactions are expected in the ArgoNeuT sensitive volume. Notice (fig. 2, bottom) that in the energy region between 1 and 4 GeV the relative statistical error is reduced to the level of 4–5%, below the NuMI Beam systematics. The QE cross-section, as a function of the incident neutrino energy, can be directly measured combining the experimental information from the final-state reconstructed kinematics with the neutrino beam profile. We implemented a GEANT4 MC simulation (particle level) of QE events generated (GENEVE MC) with the on-axis NuMI beam, including the geometry of the ArgoNeuT detector (see fig. 3) as designed in the CAD project. In fig. 4 the experimental QE cross-section distribution is shown assuming that all the collected events are somehow fully reconstructed. Due to the limited dimensions of the detector, only in a small fraction of the events the muon and proton tracks are fully contained in the LAr sensitive volume. In 54% of the QE events with the vertex in ArgoNeuT the proton is completely cointained in LAr, while 86% of the muons escape the detector. 47% of the QE events have the proton completely contained and the muon entering the immediately downstream MINOS ND. ArgoNeuT will profit from the MINOS energy reconstruction capability to recover these events. 5. – Conclusions One of the main uncertainties for the next generation of long-baseline neutrino oscillation experiments is given by the neutrino-nucleus interaction cross-section in the few GeV region, where the dominant reaction is the QE CC. The QE νμ cross-section is

M. Antonello on behalf of the ArgoNeuT Collaboration

σ 10-38 (cm2)

402

1.4

1.2

1

0.8

0.6

0.4

0.2

0

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

5

Eν (GeV)

Fig. 3

Fig. 4

Fig. 3. – ArgoNeuT geometry imported in the GEANT 4 simulation as designed in the CAD project. The first Iron Plate of the MINOS ND is also reported. Fig. 4. – Experimental QE cross-section distribution, expected from MC simulation (histogram, GENEVE MC). Complete reconstruction of all the events and full detector efficiency are assumed. Error bars refer to the statistical error and full dots indicate the theoretical cross-section value in the corresponding bin.

presently known with 20–30% errors. The ArgoNeuT experiment will measure the QE νμ cross-section in LAr with a precision of 4–5%. The detector is now under construction at Fermilab and will be exposed on-axis to the NuMI beam. The expected number of QE νμ CC events in a 180 days run is about 4700. REFERENCES Bleve C. et al., Astroparticle Phys., 16 (2001) 145. Lipari P., Lusignoli M. and Sartogo F., Phys. Rev. Lett., 74 (1995) 4384. Amerio S. et al., Nucl. Instrum. Methods Phys. Res. A, 527 (2004) 329. Cavanna F. and Palamara O., Nucl. Phys. B Proc. Suppl., 112 (2002) 265. ArgoNeuT: Mini LArTPC Exposure to Fermilab’s NuMI Beam; http://t962.fnal.gov. Kopp S., arXiv:physics/0508001v1, 30 Jul 2005; Kopp S., arXiv:0709.2737v1, 18 Sep 2007. Fleming B. T. et al., A Proposal for a New Experiment Using the Booster and NuMI Neutrino Beamlines: MicroBooNE, 15 Oct 2007; http://www-microboone.fnal.gov. [8] Rameika R. et al., LAr5 - A Liquid Argon Neutrino Detector for Long Baseline Neutrino Physics, DRAFT Letter of Intent, 13 Mar 2008, http://www.fnal.gov/directorate/ program planning/Mar2008PACPublic/LAr5 LOI.pdf. [9] Cavanna F. and Palamara O., Nucl. Phys. B Proc. Suppl., 112 (2002) 183. See also ICARUS Proposal LNGS-94/99, Vol. I.

[1] [2] [3] [4] [5] [6] [7]

DOI 10.3254/978-1-60750-038-4-403

Search for ββ decay modes at LNGS by DAMA experiment F. Cappella on behalf of DAMA Collaboration Dipartimento di Fisica, Universit` a “La Sapienza” Roma and INFN, Sezione di Roma I - Italy

Summary. — In this paper a short summary of results achieved by the DAMA experiment in the investigation of double-beta decay modes in various isotopes is presented.

1. – Introduction The DAMA experiment (working at LNGS of the INFN) has investigated several double-beta decay modes in various isotopes using and developing low-background scintillators. In particular, the double-beta decay modes of 40 Ca [1], 46 Ca [1], 48 Ca [2], 64 Zn [3], 106 Cd [4], 108 Cd [5], 114 Cd [5], 130 Ba [6], 136 Ce [7], 138 Ce [7], 142 Ce [7], 134 Xe [8] and 136 Xe [8] have been studied exploiting either the active or the passive source technique. Such searches allowed to improve (sometimes of several orders of magnitude) the limits set by previous experiments or to set new limits on unexplored isotopes or decay modes. It is worth noting that DAMA has obtained the best experimental limit on double-beta plus decay modes, investigating the 22ν decay mode of 40 Ca [1], and one of the highest experimental limits for double-beta minus decay modes studying the 2β − 0ν of 136 Xe (T1/2 > 1.2 × 1024 y, 90% C.L. [8]). Figure 1 shows a summary of the T1/2 limits achieved by DAMA on ββ decay (red bars) and by previous experiments (blue bars). 2. – Search for ββ decay with DAMA/LXe set-up The DAMA/LXe set-up (6.5 kg, i.e., 2 litres of liquid-xenon pure scintillator), its radiopurity and its performances have been described in detail in ref. [9]; here, we briefly mention only some main points. The inner vessel, which contains the liquid xenon, is made of OFHC low radioactive copper. The scintillation light is collected by three EMI photomultipliers (PMTs) with MgF2 windows working in coincidence. The PMTs are housed in the insulation vacuum and are fully surrounded by low radioactive Cu. They collect the scintillation light through three windows (3 in diameter) made of special cultured crystal quartz (total transmission of the LXe ultraviolet scintillation light is c Societ`  a Italiana di Fisica

403

404

F. Cappella on behalf of DAMA Collaboration

Fig. 1. – (Colour online) Summary of the T1/2 limits achieved by DAMA on ββ decay (red bars in colour or light gray in black and white printing) and by previous experiments (blue bars in colour or dark bars in black and white printing) on various double-beta decay processes and candidate isotopes.

≈ 80%). The passive shield is composed of 5–10 cm of low radioactive copper inside the vacuum insulation vessel, 2 cm of steel (wall of the insulation vacuum vessel), 5–10 cm of low radioactive copper, 5 cm of Polish lead and 10 cm of Boliden lead, 1 mm cadmium and ≥ 10 cm polyethylene. The whole set-up is enclosed in a sealed plexiglas box maintained in a high purity nitrogen atmosphere. The cryogenic and vacuum system is described in detail in ref. [9]. For each event the shape of the sum pulse is recorded by a LeCroy transient digitizer. The data collected over 8823.54 hours with 6.5 kg Kr-free xenon containing 17.1% of 134 Xe and 68.8% of 136 Xe (statistics of 1.1 kg × y for the 134 Xe and of 4.5 kg × y for the 136 Xe) have been analysed to investigate the 134 Xe and the 136 Xe ββ decay modes [8]. In particular, a joint analysis of the ββ0ν decay mode in 134 Xe and in 136 Xe has been carried out as suggested in ref. [10]; in principle, this kind of analysis could improve the information obtained when separately studying the two isotopes. In the case of the 134 Xe ββ0ν(0+ − 0+ ) decay mode the limit T1/2 > 5.8 × 1022 y at 90% C.L. is obtained, while in the case of the 136 Xe ββ0ν(0+ − 0+ ) decay mode the limit is: T1/2 > 1.2 × 1024 y at 90% C.L. The last one represents one of the highest experimental limits for doublebeta minus decay modes and allowed to set an upper limit on effective light Majorana neutrino mass, mν , ranging from 1.1 to 2.9 eV depending on the adopted model [8]. Other decay modes have been also studied (see ref. [8] and fig. 1). 3. – Search for ββ decay with DAMA/R&D set-up The DAMA/R&D installation is a low background set-up used for measurement on low-background prototype scintillators and PMTs, realized in various R&D efforts

Search for ββ decay modes at LNGS by DAMA experiment

405

with industries. It is regularly used to perform small-scale experiments also in collaboration with INR Kiev. The used detectors in each experimental measurement are surrounded by low-radioactive Cu bricks and sealed in a low-radioactive air-tight Cu box continuously flushed with high-purity nitrogen gas to avoid presence of residual environmental radon. The Cu box is surrounded by a passive shield made of high-purity Cu, 10 cm of thickness, 15 cm of low radioactive lead, 1.5 mm of cadmium and 4 to 10 cm of polyethylene/paraffin to exclude the external background. The shield is contained inside a plexiglas box, also continuously flushed by high-purity nitrogen gas. In the following we briefly summarize some of the results obtained with DAMA/R&D set-up in the search for ββ decay processes. An experiment to study the ββ decay processes in 106 Cd has been performed using a low-background set-up with two large low-background NaI(Tl) crystals and cadmium samples (total mass 154 g), enriched in 106 Cd at 68% (passive source technique) [4]. The β + /EC and β + β + processes would manifest themselves by the simultaneous emission of two or four 511 keV γ rays. Therefore, the two low-background NaI(Tl) scintillators placed around the 106 Cd source in DAMA/R&D are well suitable to measure these γ-rays in coincidence. New limits on the half-lives for the different decay channels in 106 Cd have been obtained. They are in the range (0.3–4)×1020 y at 90% C.L. [4], which is significantly higher (by a factor 6 to 60) than those previously published for this nuclide. The development of highly radiopure CaF2 (Eu) crystal scintillators has been performed aiming at a substantial sensitivity enhancement of the 2β decay investigation of Ca isotopes. Two CaF2 (Eu) crystals (each 370 g mass) developed with Bicron company were used in ref. [1] to study ββ processes in 40 Ca and 46 Ca. The locations and amounts of the radioactive contaminations have been estimated and a background model has been used to estimate half-life limits for the double EC capture of 40 Ca and the ββ0ν decay of 46 Ca [1]. This experiment allowed to obtain the best experimental limit on doublebeta plus decay modes, investigating the 22ν decay mode of 40 Ca: T1/2 > 5.9 × 1021 y at 90% C.L. [1]. The performances of a CeF3 crystal scintillator with a mass of 49.3 g have been investigated in ref. [7]. In particular, the α/β light ratio, the possibility of a pulse-shape discrimination between α particles and γ quanta and the radioactive contamination of the crystal have been studied. The application of the obtained results in the search for the two-neutrino double-electron capture in 136 Ce and 138 Ce allowed to obtain new T1/2 limits for these processes (see ref. [7] and fig. 1). The potentiality of the coincidence technique to search for ββ decay processes in 130 Ba has been studied [6]. A BaF2 crystal scintillator with a mass of 3615 g and two low-background NaI(Tl) detectors have been used for this purpose. The performances of the BaF2 crystal scintillator have preliminarily been investigated, in particular: i) the α/β light ratio; ii) the pulse shape discrimination capability between α and β particles; iii) the main radioactive contaminations of the crystal. As a result, new limits (90% C.L.) on the lifetimes of double-beta decay processes in 130 Ba have been determined (see ref. [6] and fig. 1). The new experimental limits obtained for the 0ν(0+ → 0+ ) decay modes represent a significant improvement with respect to those previously available for this

406

F. Cappella on behalf of DAMA Collaboration

isotope, while those involving excited levels were set there for the first time. The potentiality of the β-γ coincidence technique has also been exploited in the search for the ordinary highly forbidden β decay, for the lepton number violating ββ0ν(0+ −2+ ) decay and for the ββ2ν(0+ − 2+ ) decay of 48 Ca [2]. For this purpose, a 1.11 kg CaF2(Eu) detector partially surrounded by low-background NaI(Tl) detectors has been used [2]. A low-background experiment to search for double-electron capture and electron capture with positron emission in 64 Zn was carried out over 1902 h by using a ZnWO4 scintillation detector with mass of 117 g [3]. New improved limits were set for different modes of double-beta decay of 64 Zn by analyzing the energy distribution measured with the ZnWO4 detector (see ref. [3] and fig. 1). In particular, the 2K2ν and β + 2ν processes were restricted at the level of T1/2 > 6.2 × 1018 y and T1/2 > 2.1 × 1020 y at 90% C.L., respectively. The positive indication on the β + (2ν + 0ν) decay of 64 Zn suggested in [11] is discarded by this experiment [3]. Finally, a search for ββ processes in 108 Cd and 114 Cd has been realized by using data of a low-background experiment with CdWO4 crystal scintillator (434 g mass) [5]. New improved half-life limits on double-beta processes were established (see ref. [5] and fig. 1). The obtained values are higher than those reached in the previous experiments and demonstrate the possibility of a scintillation experimental technique to search for double-beta processes in 108 Cd and 114 Cd. At present an experiment to further investigate ββ2ν decay of 100 Mo to the first 100 excited 0+ Ru is in progress using a 1 kg sample enriched in 100 Mo at 95.5% 1 level of and 4 low-background HPGe detectors [12]. Moreover, purification of enriched 106 Cd is in progress towards the construction of 106 CdWO4 low background scintillator [13]. Other small-scale experiments are in preparation in collaboration with INR Kiev and IIT Kharagpur. REFERENCES [1] Belli P. et al., Nucl. Phys. B, 563 (1999) 97; Bernabei R. et al., Astropart. Phys., 7 (1997) 73. [2] Bernabei R. et al., Nucl. Phys. A, 705 (2002) 29. [3] Belli P. et al., Phys. Lett. B, 658 (2008) 193. [4] Belli P. et al., Astropart. Phys., 10 (1999) 115. [5] Belli P. et al., Eur. Phys. J. A, 36 (2008) 167. [6] Cerulli R. et al., Nucl. Instrum. Methods Phys. Res. A, 525 (2004) 535. [7] Belli P. et al., Nucl. Instrum. Methods Phys. Res. A, 498 (2003) 352; Bernabei R. et al., Nuovo Cimento A, 110 (1997) 189. [8] Bernabei R. et al., Phys. Lett. B, 546 (2002) 23; ibidem, 527 (2002) 182. [9] Bernabei R. et al., Nucl. Instrum. Methods Phys. Res. A, 482 (2002) 728. [10] Simkovic F. et al., hep-ph/0204278. [11] Bikit I. et al., Appl. Radiat. Isot., 46 (1995) 455. [12] Belli P. et al., in Current Problems in Nuclear Physics and Atomic Energy (INR-Kiev) 2006, p. 479. [13] Belli P. et al., preprint ROM2F/2008/17, to be published in Proceedings of the II International Conference NPAE, June 2008, Kiev, Ukraine.

DOI 10.3254/978-1-60750-038-4-407

Development of nuclear emulsions for the OPERA experiment E. Carrara INFN, Sezione di Padova and Universit` a di Padova - Padova, Italy

Summary. — The ambitious aim of the OPERA experiment is to detect for the first time the appeareance of tauonic neutrinos out of an artificial beam of pure muonic neutrinos. This is achieved with the mature nuclear emulsion technique, greatly improved by the R&D of the OPERA collaboration both in quality and analisys speed. The huge number of emulsions (over 9 million sheets) of the OPERA experiment requires a completely automated development facility, able to perform photographic development process on up to 3000 emulsion sheets per working day. I will present the project of the development facility and report on the current status.

1. – The OPERA experiment OPERA (Oscillation Project with Emulsion-tRacking Apparatus) [1] is a long-baseline experiment designed primarily to make a conclusive test of the νμ → ντ oscillation hypothesis by means of the direct observation of ντ in an initially pure νμ beam. The beam is produced at CERN, in Geneva, and fired towards the OPERA detector, which is located in the Hall C of the Gran Sasso Underground Laboratory, 730 km away [2]. The average energy of the neutrinos is well above the τ lepton production threshold, in the oscillation parameter region indicated by atmospheric neutrino experiments. OPERA is a hybrid detector made of electronic subdetectors and lead/nuclear emulsion target. The c Societ`  a Italiana di Fisica

407

408

E. Carrara

Table I. – The CNGS beam main characteristics. νμ (m−2 /pot) νμ CC events/pot/kton Eνμ (GeV) νe /νμ ν¯μ /νμ ν¯e /νμ

7.36 × 10−9 5.05 × 10−17 17 0.8% 4% 0.07%

target is composed of Emulsion Cloud Chambers (ECC), whose unit is called brick. The total nominal mass of the experiment exceeds 1.5 kton, which is required to reach the desired sensitivity in the parameters to be measured. When a neutrino hits the detector, the electronics show in which brick the event occurred. The brick is then removed from the experiment target, the emulsions are chemically developed and sent to the scanning laboratories for interaction vertex analysis. The scanning stations use high-performance automated microscopes for the identification of the tracks inside the emulsions. . 1 1. The CNGS neutrino beam. – The CNGS [2] neutrino beam was designed and optimized for the study of νμ → ντ oscillations in appearance mode, by maximizing the number of charged current (CC) ντ interactions at the LNGS site (see table I). The average neutrino energy at the LNGS location is 17 GeV. The ν¯μ contamination is 4%, the νe and ν¯e contaminations are lower than 1%, while the number of prompt ντ from Ds decay is negligible. The average L/Eν ratio is 43 km GeV−1 . Assuming a CNGS beam intensity of 4.5 × 1019 pot per year and a five year run, about 31000 charged current (CC) plus neutral current (NC) neutrino events will be collected by OPERA from interactions in the lead-emulsion target. Out of them 148 (214) CC ντ interactions are expected for Δm2 = 2.5×10−3 eV2 (3×10−3 eV2 ) and sin2 2θ23 = 1. Taking into account the overall τ detection efficiency, the experiment should gather 12–15 signal events with a background of less than one event. 2. – Emulsion cloud chambers The ντ appearance search is based on the observation of τ − events produced by CC interactions, with the τ − decaying in all possible decay modes: (1a)

τ − → e− ντ ν e ,

(1b)

τ − → μ− ντ ν μ ,

(1c)

τ − → h− ντ (nπ 0 ),

(1d )

τ − → 3πντ .

Given the τ lifetime of ∼ 3 × 1013 s, hence a typical path of ∼ 1 mm, and the small expected event rate, it is crucial to efficiently separate the ντ CC events from all the

Development of nuclear emulsions etc.

409

other flavor neutrino events, and to keep the background at a very low level. The basic structure of the emulsion detector is called Emulsion Cloud Chamber (ECC) and is made of ECC bricks. Each brick consists of 57 emulsion sheets; in order to have large mass (1.3 kton) and high granularity, the emulsion sheets are interleaved with 1 mm thick lead plate. The emulsions used to build ECC are 44 μm-thick layers placed at the upper and bottom surfaces of a 205 μm-thick plastic base. The dimensions of a brick are 12.5 × 10.2 × 7.5 cm3 , the weight is 8.3 kg each. In terms of radiations length, a brick corresponds to a thickness of 10X0 which is long enough to allow the identification of electrons by electromagnetic showers and to measure momentum by multiple Coulomb scattering following the tracks in consecutive emulsion sheets [4]. . 2 1. Emulsion development. – Emulsions suspected to contain neutrino interactions are developed with photographic technique. The so-called latent image impressed in the emulsion is made visible by the development process. In chemical development, silver ions are provided from the silver halide crystals containing the latent image center. If silver halide solvents, such as sulphite, are present in the chemical developer, some physical development may occur, in which silver ions are provided from the developer solution. A deeper understanding of the development processes is given by the quantitative methods of electrochemistry [5]. The developers generally used for nuclear emulsions are combined chemical and physical developers, sulphite and bromide are solvents of the silver halides. The conventional photographic processing steps are: Presoak; Development; Stop; Fixation; Wash; Dry. In the OPERA experiment, standard procedures need to be modified due to the great thickness of the emulsions and by the requirement of the development to be as uniform as possible and the resulting emulsion must be distortion-free [6]. 3. – Development facility The core of the development facility of the OPERA experiment are the development lines, 6 robots which perform the necessary steps for emulsion development. Their goal is to provide high and uniform quality films to the scanning laboratories worldwide. Up to 5 bricks are handled simultaneously by each machine, with a possible overall rate of over 3000 emulsions per day, making it a hardware and software challenge. The mechanical structure of the lines is made of aluminum rods, which are approximately 4.5 meters long, 80 cm wide and 1.2 m high, each one is equipped with 8 inox steel tanks, 5 of which have a capacity of 30 liters, the remaining 3 have a capacity of 45 liters. A mechanical arm, mounted on an aluminum bridge, can slide horizontally forth and back for the whole length of the line. The arm can slide vertically along the bridge, and is equipped with a jaw which allows to carry the film holders containing the emulsions and deposit them into the tanks. The machines are connected by cables to racks that contain the higher level logics of the machines and the power supplies. The racks offer

410

E. Carrara

an interface to the remote control computer through a collection of Field Point modules. The Field Points are then connected with an ethernet cable to the control PC, which runs the scheduling program, that automatically executes the full development procedure, without the operator intervention. The control software relies on middle-ware component, provided by National Instruments, which is a OPC (OLE for Process Control, where OLE stands for Object-Linking and Embedding) server, to communicate seamlessly with the Field Points. The program is internally structured in different layers, which are independent of each other. The lowlevel library is a collection of classes(1 ) written in C# that provides a direct interface to the available hardware. The high-level layer of the software takes care of the scheduling of processes to be performed. It adapts at the current status of the development line, reschedules tasks in case of clashes and manages different priorities of the operations. Currently the control software is able to handle an arbitrary number of processes simultaneously on any number of development lines, and operate in the so-called set & forget mode, where the operator feeds the machine with a bunch of emulsions, and hours later retrieves the developed films. In conclusion the development facility of the OPERA experiment is able to provide high-quality emulsions at a sustained rate that can cope with the OPERA expected extraction rate. The emulsions are then sent to the scanning laboratories where the neutrino interactions are reconstructed. The discovery of the ντ appearance ultimately and doubtlessly will prove the neutrino oscillation hypothesis suggested by several experiments in the last decades. ∗ ∗ ∗ I deeply thank professors L. Stanco and R. Brugnera for their priceless support and guidance. This work is dedicated to the dear memory of my grandparents Regina and Antonio. REFERENCES [1] OPERA Collaboration, Guller M. et al., OPERA experiment proposal, CERN-SPSC2000-028. [2] Acquistapace G. et al., The CERN neutrino beam to Gran Sasso (CNGS), Conceptual Technical Design (CERN 98-02 and INFN/AE-98/05) 1998. [3] OPERA Collaboration, Guller M. et al., CNGS project CERN-SPSC-2001-025. [4] Arrabito L. et al., Nucl. Instrum. Methods Phys. Res. A, 568 (2006) 578. [5] Barkas W. H., Nuclear Research Emulsion (Academic Press, New York and London) 1963. [6] Sirignano C., R&D on OPERA ECC: studies on emulsion handling and event reconstruction techniques, PhD Thesis (Salerno University) 2005.

(1 ) In object-oriented programming, a class is a language construct used to group related fields and methods.

DOI 10.3254/978-1-60750-038-4-411

First events from the OPERA detector at Gran Sasso D. Di Ferdinando and G. Sirri INFN, Sezione di Bologna - Bologna Italy

Summary. — OPERA is a long-baseline experiment designed to be the conclusive proof of the νμ → ντ oscillation hypothesis by means of the direct observation of ντ in an initially pure νμ beam. The detector is located at the underground Gran Sasso laboratory, 730 km from CERN, on the CNGS neutrino beam. It consists of a lead/emulsion film target complemented by magnetic spectrometers and electronic detectors. We give a report on the OPERA detector and we show the first neutrino events detected in the emulsions.

1. – The OPERA experiment In the last decades, several disappearance experiments [1-5] using neutrinos coming from cosmic rays and then by accelerators have shown a deficit in the measured νμ neutrino flux with respect to the predicted one. This behavior was explained by the neutrino oscillation hypothesis which requires neutrino mixing and mass. The Oscillation Project with Emulsion tRacking Apparatus (OPERA) was built in hall C of the Gran Sasso National Laboratory (LNGS) to prove without any doubt the neutrino oscillation by the appearance of ντ in a pure νμ beam (CNGS) coming from CERN . The average neutrino energy is about 17 GeV. This optimizes the number of ντ CC interactions in the detector for values of Δm2 ∼ 2.5 × 10−3 eV2 indicated by the atmospheric neutrinos experiments. The prompt ντ contamination is negligible; the ν¯μ contamination is ∼ 4%; the total νe and ν¯e contamination is below 1%. The commissioning of the CNGS beam started in July 2006 and was completed at low intensity c Societ`  a Italiana di Fisica

411

412

D. Di Ferdinando and G. Sirri

Fig. 1. – Schematic view of the OPERA detector. The neutrino beam arrives from the left side.

on August 2006, when the first 319 neutrinos interactions were detected by OPERA at LNGS [6]. The first physics run with real bricks (October 2007) allowed to test the whole strategy of the experiment, from the electronic detector triggers to the neutrino vertex interactions fully reconstructed in the emulsions. 2. – The detector The OPERA detector is 10 m × 10 m × 20 m and with a target mass of 1.35 kton. To satisfy the requirements of high tracking capabilities (the short τ decay length is O(1 mm)) and large target mass (small ν interaction cross-section) the technique of the Emulsion Cloud Chamber (ECC) is used. The basic ECC element of the OPERA detector is the brick composed of a sequence of 57 nuclear emulsion films interleaved with 56 1 mm-thick lead plates packaged in a light tight and high mechanical precision way. Each emulsion, that acts as sub-micrometric resolution tracker, is composed of two 44 μm sensitive layers deposited onto a 205 μm plastic base and has an area of 12.7 × 10.2 cm2 . The thickness of the whole brick is about 7.5 cm, corresponding to ∼ 10 radiation lengths. The 150000 bricks of the OPERA detector are arranged in two identical supermodules, each one composed of a target section and a muon spectrometer fig. 1. The target section is composed of vertical structures with transverse size ∼ 6.6×6.7 m2 (walls). Each wall is a matrix 52 × 51 bricks, organized in horizontal trays; the bricks are moved by the Brick Manipulator System (BMS) for insertion and extraction. The 29 brick walls are interleaved with planes of plastic scintillator strips (690 cm × 2.6 cm × 1 cm) and readout by WaveLength-Shifting fibers (WLS) and multi-anode 64-pixel PMTs at both ends. The Target Tracker (TT) provides the trigger and identifies the brick where the event vertex should be found. The detection efficiency of each plane is ∼ 99%. More information about the TT is provided in [7]. The spectrometer is an instrumented dipolar magnet (∼ 8.75 × 8 m2 ) made of two magnetized iron walls producing a field of 1.52 T in the tracking region with vertical lines of opposite directions in the two walls. The 12 iron slabs of magnet walls are interleaved with planes of bakelite RPCs (2.9 × 1.1 m2 ) that provide the range of stopping charge particles and crude tracking information inside

First events from the OPERA detector at Gran Sasso

413

Fig. 2. – Left: detector display of the first event registered in the OPERA target. Right: reconstruction of the neutrino interaction inside the triggered ECC brick.

the magnet [8, 9]. Six planes of precision drift tubes with 38 mm diameter and 8 m length, placed in pairs in front, behind and between magnet walls measure the charge and momentum of the muons [10]. Planes of glass RPCs are placed in front of the apparatus to tag the interactions occurring in the upstream rock [11]. 3. – Strategy for ν event location The CNGS beam provides 2 fast extractions of 10.5 μs duration separated by 50 ms per cycle and two cycles per super-cycle of the SPS. Two GPS, one located at CERN and the other at LNGS, allow the time correlation between the beam and the events recorded in the detector. The TT data provide the trigger and the event reconstruction; this in turn fixes the bricks with the highest probability to host the event; these bricks are promptly removed from the target for further analysis. Before disassembling the extracted brick, the presence of the event is validated by matching the tracks reconstructed in the TT with those located in a doublet of emulsion films, called Changeable Sheets (CS) [12], attached on the downstream surface of each brick. The validated brick is exposed to cosmic rays, to have a precise reference frame for film-to-film alignment [13]. The brick is then dismounted, in an automated developing chain and sent to the scanning laboratories. By using custom-made microscopes [14-16], the tracks measured in the CS are connected to the brick and followed back film by film up to the interaction point. A volume scan around this point is used for full event reconstruction, decay topology validation and kinematic analysis (using momentum measurement by multiple Coulomb scattering [17], electron-pion identification and energy reconstruction [18, 19]). 4. – First physics run The first OPERA physics run was held in October 2007. At that time about 40% of the target was installed for a total mass of 550 tons. Due to failures of ventilation control units of the proton target, caused by high radiation level in the area were electronic was installed, the beam was available only for few days with a global intensity of 0.79 ×

414

D. Di Ferdinando and G. Sirri

1018 pot. In a few hours the first neutrino interactions were successfully located and reconstructed. 38 events (29 CC and 9 NC) were registered in the OPERA target to be compared with (32 ± 6) expected. Figure 2 shows the first located event, as detected by the elctronic (left) and as reconstructed in emulsions (right). Despite of its short duration the run allowed a successful testing of the electronic detectors, data acquisition and brick finding algorithms, proved the ability of the matching between the target tracker and the bricks and validated the full scanning strategy. 5. – Conclusions The first neutrino interactions in the OPERA target were recorded in the 2007 short run and the strategy of the experiment was successfully tested. The target is now complete and the beam is expected to reach the detector during this summer. The expected number of interactions in the OPERA target in 2008 is about 2200. ∗ ∗ ∗ To the memory of Romolo Diotallevi who left us while we were attending this School. His technical competence in emulsion development and overall sincere humanity represent an unbridgeable loss for all who had the luck and joy to share moments with him. REFERENCES [1] Ambrosio M. et al., Phys. Lett. B, 434 (1998) 451; 566 (2003) 35; Eur. Phys J. C, 36 (2004) 323. [2] Allison W. W. M. et al., Phys. Lett. B, 449 (1999) 137. [3] Fukuda J. et al., Phys. Rev. Lett., 81 (1998) 1562; Hosaka J. et al., Phys. Rev. D, 74 (2006) 032002; Abe K. et al., Phys. Rev. Lett., 97 (2006) 171801. [4] Ahn M. H. et al., Phys. Rev. D, 74 (2006) 072003. [5] Michael D. G. et al., Phys. Rev. Lett., 97 (2006) 191801. [6] Acquafredda R. et al., New. J. Phys., 8 (2006) 303. [7] Adam T. et al., Nucl. J. Phys., 8 (2006) 303. [8] Bergnoli A. et al., Nucl. Phys. B (Proc. Suppl.), 158 (2006) 35. [9] Adinolfi Falcone R. et al., Nucl. Phys. Conf. Suppl., 172 (2007) 165. [10] Zimmermann R. et al., Nucl. Instrum. Methods Phys. Res. A, 555 (2005) 435; 557 (2006) 690. [11] Candela A. et al., Nucl. Instrum. Methods Phys. Res. A, 581 (2007) 206. [12] Anokhina A. et al., JINST, 3 (2008) P07002; P07005. [13] Barbuto E. et al., Nucl. Instrum. Methods Phys. Res. A, 525 (2004) 485. [14] De Serio M. et al., Nucl. Instrum. Methods Phys. Res. A, 554 (2005) 247. [15] Armenise N. et al., Nucl. Instrum. Methods Phys. Res. A, 551 (2005) 261. [16] Nakano T., Automated Emulsion Read-out System, in III International Workshop on Nuclear Emulsion Techniques, 24-25 January 2008, Nagoya, Japan. [17] De Serio M. et al., Nucl. Instrum. Methods Phys. Res. A, 512 (2003) 539. [18] Kodama K. et al., Rev. Sci. Instrum., 74 (2003) 53. [19] Arrabito L. et al., JINST, 2 (2007) P02001.

DOI 10.3254/978-1-60750-038-4-415

Automated scanning of OPERA emulsion films D. Di Ferdinando and G. Sirri INFN, Sezione di Bologna - Bologna, Italy

Summary. — Large neutrino experiments with an accuracy of better than 1 micron are possible thanks to the recent improvements in the nuclear emulsion detectors. The European Scanning System (ESS) is a fast automatic system developed for the mass scanning of the emulsions of the OPERA experiment. Improvements in the automatic scanning technique and performance of ESS are reported.

1. – Introduction Nuclear emulsion is the detection technique with the best known position resolution (< 1 μm). This technique is connected to many early particle physics discoveries despite the huge scanning effort and the consequent limited mass of the experiments. The development of fast automated scanning systems have made possible the use of nuclear emulsion in large scale experiments like OPERA at the INFN Gran Sasso Underground Laboratories (LNGS). OPERA is a long-baseline experiment [1-3] designed to search for νμ → ντ oscillations as suggested by atmospheric neutrino experiments [4-6]. The aim is to observe the appearance of ντ through the identification of the τ leptons created in their CC interactions in a pure νμ beam produced by the CNGS facility at CERN [7]. This requires track position and angular measurements with accuracies of ∼ 1 μm and a few milliradiants, respectively. c Societ`  a Italiana di Fisica

415

416

D. Di Ferdinando and G. Sirri

Fig. 1. – Exploded view of the OPERA lead/emulsion target.

2. – Nuclear emulsions. OPERA target Nuclear emulsions are composed of microcrystals of silver halides (AgBr) dispersed in a gelatin layer. The energy released by ionizing particles to the crystals produces the so-called latent image. After a chemical development process the particle trajectory is visible as a sequence of black silver grains about 0.5 μm in size [8]. Nuclear emulsions are ideal for the detection of short-lived particles (like τ decay); they provide i) threedimensional spatial information, ii) excellent resolution (< 1 μm, < 5 mrad), iii) high hit density (∼ 300 hits/mm for a minimun ionizing particle). OPERA is an hybrid apparatus with electronic detectors and a massive lead-emulsion target. The OPERA target is segmented into ∼ 150000 bricks (fig. 1). A brick is a sequence of 56 lead plates interleaved with 57 emulsion films with an area of 12.7×10.2 cm2 and satisfies the need of both a large-mass and a high-precision tracking capability. OPERA emulsions are used as thin films: pairs of emulsion layers (44 μm thick) are mounted on both sides of a plastic base (205 μm thick) [9]. In 5 years data taking ∼ 1000 emulsion films per day will be (totally or partially) scanned in order to find and analyze the neutrino interations. In total, ∼ 6000 cm2 per day have to be analyzed with sub-micrometric precision. 3. – Automatic scanning system New fast automatic scanning systems have been developed for OPERA: the European Scanning System (ESS) [10] and the S-UTS in Japan [11]. The Japanese S-UTS system uses a dedicated hardware while the ESS (fig. 2) is based on the use of commercial hardware components. The ESS, described further, is able to scan an emulsion volume of 44 μm thickness with a speed of 20 cm2 /h (10 times more than past scanning systems [12, 13]). By adjusting the focal plane of the objective, the whole 44 μm emulsion thickness is spanned and a sequence of 15 tomographic images of each field of view, taken at equally

Automated scanning of OPERA emulsion films

417

Fig. 2. – Schematic layout of the European Scanning System microscope (left). A photograph of one of the microscopes of the European Scanning System (right).

spaced depth levels (3 μm), is obtained. Emulsion images are digitized, converted into a grey scale of 256 levels, sent to a vision processor board and analyzed to recognize sequences of aligned grains. The three-dimensional structure of a track in an emulsion layer is reconstructed by combining clusters belonging to images at different levels and searching for geometrical alignments. Tracks are then reconstructed in the entire brick, after film-to-film alignment. (fig. 3). 4. – Scanning performances Several test exposures at pions beams were performed to estimate the scanning performances. The scanning systems are successfully running with high efficiency (> 90% in the [0, 400] mrad angular range), good purity (∼ 2 fake tracks/cm2 /[angle < 0.4 rad])

Fig. 3. – Track reconstruction: for each field of view, several emulsion images are taken by moving the optical axis and track segments are found by connecting aligned grains (left). Tracks are reconstructed by linking both sides of the emulsion film (center) and then all films of the entire brick (right).

418

D. Di Ferdinando and G. Sirri

and the design speed of 20 cm2 /h. Position and angular resolutions at small incident angles are σposition = 1 μm and σangle = 2 mrad [14]. 5. – Conclusions The features and performances of the European Scanning System (ESS) have been described. The resulting tracking efficiencies have been evaluated to be above 90% in the [0, 400] mrad angular range with resolutions of ∼ 1 μm and ∼ 2 mrad for vertical tracks. The ESS has reached the speed of ∼ 20 cm2 /h in an emulsion volume 44 μm thick. This represents an improvement of more than an order of magnitude with respect to the systems developed in the past. The scanning performances satisfy the requirements of the OPERA experiment. About 25 ESSs have been installed in European laboratories collaborating in the OPERA experiment. Eight more have been installed at the Gran Sasso Laboratory (LNGS). ∗ ∗ ∗ This paper is dedicated to the memory of our friend Romolo Diotallevi. REFERENCES [1] Eskut E. et al., Nucl. Instrum. Methods Phys. Res. A, 401 (1997) 7. [2] Kodama K. et al., Phys. Lett. B, 504 (2002) 218. [3] Acquafredda R. et al., New J. Phys., 8 (2006) 303; Anokhina A. et al., JINST, 3 (2008) P07002; P07005. [4] Fukuda Y. et al., Phys. Rev. Lett., 81 (1998) 1562; Ashie Y. et al., Phys. Rev. Lett., 93 (2004) 101801. [5] Ambrosio M. et al., Phys. Lett. B, 434 (1998) 451; 566 (2003) 35; Eur. Phys. J. C, 36 (2004) 323. [6] Allison W. W. M. et al., Phys. Lett. B, 449 (1999) 137; Phys. Rev. D, 72 (2005) 052005. [7] Bailey R., CERN-SL/99-034 (DI) Geneva (1999) http://proj-cngs.web.cern.ch. [8] Powell C. F. et al., The Study of Elementary Particles by the Photographic Method (Pergamon, New York) 1959; Barkas W. H., Nuclear Research Emulsions (Academic Press, New York and London) 1963. [9] Nakamura T. et al., Nucl. Instrum. Methods Phys. Res. A, 556 (2006) 80. [10] D’Ambrosio N. et al., Nucl. Phys. B Proc. Suppl., 125 (2003) 22. [11] Nakano T., Automated Emulsion Read-out System, in III International Workshop on Nuclear Emulsion Techniques, 24-25 January 2008, Nagoya, Japan. [12] Rosa G. et al., Nucl. Instrum. Methods Phys. Res. A, 394 (1997) 357. [13] Aoki S., Nucl. Instrum. Methods Phys. Res. A, 473 (2001) 192. [14] Armenise N. et al., Nucl. Instrum. Methods Phys. Res. A, 551 (2005) 261; Arrabito L. et al., Nucl. Instrum. Methods Phys. Res. A, 568 (2006) 578; JINST, 2 (2007) P05004; Kreslo I. et al., JINST, 3 (2008) P04006.

DOI 10.3254/978-1-60750-038-4-419

The GERDA experiment and first results from phase-I detector operation in LAr/LN2 A. di Vacri for the GERDA Collaboration INFN, Laboratori Nazionali del Gran Sasso - Assergi (AQ), Italy

Summary. — GERDA (GERmanium Detector Array) is designed to search for the neutrinoless double-beta (0νββ) decay of 76 Ge. The experiment is being installed in Hall A of the INFN-Laboratori Nazionali del Gran Sasso. Aiming at a background index of 10−3 counts/(kg y keV) at the Qββ value of 2039 keV, GERDA will operate bare high-purity germanium detectors enriched in 76 Ge immersed directly in the liquid Argon (LAr). The discovery potential of the GERDA experiment will be presented together with the first results from the operation of natural HPGe detectors directly immersed in LAr.

1. – GERmanium Detector Array at LNGS The GERDA experiment [1] searches for 0νββ decay of 76 Ge. High-Purity Germanium (HPGe) detectors, isotopically enriched in 76 Ge (∼ 86%), are operated naked in LAr, which acts both as the cooling medium for the detectors and as a shield against γ radiation. Moreover, the cryostat is surrounded by a stainless-steel tank containing ultra-pure water providing an additional shield against external background. The experiment aims to reduce the background at the level of 10−3 counts/(kg y keV) and energy resolution ≤ 4 keV at the Qββ (2039 keV). The layout of the experiment follows the idea proposed several years ago [2] and is similar to the GENIUS [3] and GEM [4] proposals. c Societ`  a Italiana di Fisica

419

420

A. di Vacri for the GERDA Collaboration

2. – 0νββ searches with HPGe detectors: experimental considerations Germanium spectrometry is an established technology adopted since the ’60 to search for 0νββ of 76 Ge. The parameters determining the sensitivity of such an experiment are the mass of the candidate isotope M , the measurement time t, the background index b, the energy resolution R, the efficiency  and the fraction a of isotope enrichment. The kinetic energy spectrum of the two electrons is measured and the number of events in 0ν the region of the Qββ is counted. In case of non-zero background, the T1/2 corresponding to the minimal number of detectable events above background at a given confidence 

t level varies as a M bR . Germanium is considered as a good choice since: it can be used both as source and detector assuring a high efficiency; the natural abundance of 76 Ge is 7.44%, but it can be successfully enriched up ∼ 85%; it is characterized by high intrinsic purity and excellent energy resolution can be achieved with HPGe detectors; Ge density is 5.3 g cm−3 allowing compact setup; Ge has low atomic mass (1 kg of 76 Ge equal 7.9 · 1024 nuclei).

3. –

76

Ge 0νββ decay: present status

Evidence for 76 Ge neutrinoless double-beta decay has been claimed by the group of Klapdor-Kleingrothaus, at 4.2σ based of the data of the Heidelberg-Moscow (HdM) experiment [5] at LNGS. The total achieved exposure was 72 kg y, with b = 0ν 0.11 cts/(kg keV y) before pulse shape analysis and R = 3.27 keV, producing T1/2 = 25 1.2 · 10 y. Still no positive indication has been achieved from the IGEX experiment [6] at Canfranc laboratory with an exposure of 8.9 kg y and b = 0.2 cts/(kg keV y) before pulse shape analysis (0.1 cts/(kg keV y) after pulse shape analysis). The derived limit on 0ν the half-life is T1/2 > 1.57 · 1025 y corresponding to mee < 0.33–1.3 eV, depending on the assumed nuclear matrix element calculation. The first purpose of the GERDA experiment is to confirm or to reject with high statistical significance the claim for evidence of 0νββ decay. 4. – GERDA phases and discovery potential GERDA experiment is foreseen to proceed in two phases: I) In the GERDA phase I, eight reprocessed enriched (∼ 85%) HPGe detectors from the past HdM [7] and IGEX [8] experiments with a total mass of ∼ 18 kg and six reprocessed natural HPGe detectors (∼ 15 kg) from the Genius Test-Facility [9] will be deployed in strings. The goal is to achieve b ∼ 10−2 cts/(kg keV y) in the Qββ range. Assuming an exposure of ∼ 15 kg y and R ∼ 3.6 keV, if no event is observed, 0ν the limit on the half-life will be T1/2 > 3 · 1025 y (90% C.L.) resulting in an upper limit of mee < 270 meV [10]. II) In the GERDA phase II, new diodes, able to discriminate between single-site (typical of 0νββ decay) and multi-site events, will be added to reach a total mass of

The GERDA experiment and first results from phase-I detector etc.

421

Ge of ∼ 40 kg. Reducing in such a way the background index of a further order of magnitude, the resulting limit on the half-life, with an exposure of about 120 kg y, 0ν is expected to be T1/2 > 1.5 · 1026 y (90% C.L.) with mee < 110 meV [10]. 76

III) A possible experiment on 1 ton scale on worldwide collaboration is considered. In case the HdM signal was 0νββ decay, this would produce in about 1 year of GERDA phase I data taking (∼ 15 kg y) 7 counts above background of 0.5 counts, but if no event is observed, the claim would be ruled out with 99.6% C.L. [1]. 5. – GERDA phase-I prototype detectors Natural Ge detectors are operated in a GERDA underground facility at LNGS (GDL) to investigate the effect of the phase-I detector assembly (low-mass holder (80 g) made of low-activity copper, PTFE and silicon), the protocol of detector handling and the refurbishment technology on long-term stability and spectroscopy performance. Three natural p-type HPGe detectors are available at LNGS. They differ by their passivation layer design: prototype 1 (1.6 kg) has a passivation layer that covers all the borehole side, prototype 2 (2.5 kg) has a passivation layer limited to the groove, prototype 3 (2.5 kg) has no passivation layer. The investigations started on prototype 1 and it has been observed that γ-irradiation from 60 Co of the detector in LAr resulted in a reversible increase of the leakage current (LC). In particular, after the expected spontaneous increase of the bulk current when the source is inserted (Ibulk = 2.95C E eV/e− , where C is the counting rate (Hz), E is the average energy deposited in the HPGe and 2.95 eV is the energy necessary to produce an e− -hole pair in Ge at 80 K) a continuous increase depending on the ionization rate in the LAr volume facing the detector borehole side, is observed. Typical value is 40 pA/d, for the source placed in such a way to produce a LAr ionization rate of ∼ 2 kHz in the volume facing the passivation layer (Monte Carlo estimation). The process is totally reversible: LC recovers at few pA value after irradiating without HV and after warming cycles. Prototype 2 and 3 have been irradiated in LAr to check geometrical influences of the passivation layer and measurements with prototype 1 have been repeated in LN2 : – prototype 2 (passivation layer only in the groove) in LAr shows a LC increase rate lower (1.4 pA/d) than the case of prototype 1; – prototype 3 (no passivation layer) does not show any increase of LC; – prototype 1 operated in LN2 does not show any increase. The most likely interpretation of such an increase is that ionization of the LAr volume facing the passivation layer, due to γ irradiation, produces pairs Ar+ /e− . The diode bias electric field dispersed in LAr (numerically calculated by the Maxwell 2D code [11]) drifts both Ar+ and e− toward the passivation layer (along their path e− are eventually

422

A. di Vacri for the GERDA Collaboration

trapped by electro-negative species like O2 and CO2 ). Charge collected on the passivation layer induces a decrease of resistivity (ΔR = 1014 Ω for ΔI = 40 pA and HV = 4 kV), causing an increase of the detector surface LC. The rate of the increase depends on the charge collection rate, on the density of trapped charge and on the starting value of the passivation layer resistivity. As concerns the cure of the detector by irradiation without HV, this can be explained either by γ-ray ionization in the passivation layer itself or by effect of the UV (128 nm) scintillation light of the LAr. 6. – Conclusions GERDA experiment is in construction at LNGS. It will operate HP 76 Ge detectors naked in LAr, deployed in strings. After two years of operation of bare HPGe detectors in LN2 /LAr (3 prototype detectors with different passivation layer designs) we conclude that the detector assembly has been successfully tested: energy resolution in LN2 with warm electronics and a 40 cm long cable is FWHM = 2.2 keV at 1330 keV (same resolution in LAr), while energy resolution measured in GDL in LAr with warm electronics and an 80 cm long cable is FWHM = 3 keV at 1330 keV; the detector handling protocol has been defined (more than 50 cooling/warming cycles) and the detector parameters are stable over long-term measurement and not deteriorated after one year of continuous operation in LAr. The results of the one year deep and extensive investigation on the effect of γ irradiation on the detector LC are that irradiation results in an increase of the leakage current (LC) in detectors having PL. The increase depends both on the ionization rate of LAr volume facing the borehole side of the detector and on the design of passivation layer. The radiation-induced LC is reversible by γ irradiation with HV off. From measurements, we have indications that UV light (LAr scintillation light) can de-trap the charge, restoring the LC at the initial value. Reducing the size of the passivation layer strongly suppresses γ radiation-induced LC. GERDA will be able to calibrate about once a week for several minutes with a negligible increase of LC during the experiment live-time (< 10 pA). REFERENCES [1] GERDA Collaboration, Proposal 2004 http://www.mpi-hd.mpg.de/GERDA/proposal.pdf. [2] Heusser G., Annu. Rev. Nucl. Part. Sci., 45 (1995) 543. [3] Klapdor-Kleingrothaus H. V. et al., hep-ph/9910205 and Baudis L. et al., Nucl. Instrum. Methods Phys. Res. A, 426 (1999) 425 [4] Zdesenko Yu. G. et al., J. Phys. G, 27 (2001) 2129. [5] Klapdor-Kleingrothaus H. V. et al., Phys. Lett. B, 586 (2004) 198. [6] Aalseth C. E. et al., Phys. Rev. D, 65 (2002) 092007. [7] Balysh C. et al., Phys. Rev. D, 66 (1997) 54. [8] Aalseth C. E. et al., Phys. At. Nuclei, 63 (2000) 1225. [9] Klapdor H. V. et al., Nucl. Instrum. Methods Phys. Res. A, 481 (2002) 149. [10] Rodin V. A. et al., Nucl. Phys. A, 766 (2006) 107. [11] See web page http://www.ansoft.com/maxwell.

DOI 10.3254/978-1-60750-038-4-423

MARE-1: A next-generation calorimetric neutrino mass experiment E. Ferri on behalf of the MARE Collaboration University of Milano-Bicocca and INFN Milano-Bicocca - Milano, Italy

Summary. — The only model-independent experiments dedicated to neutrino mass determination are the kinematic ones from single β-decay. In this context an international collaboration is growing around the project of Microcalorimeter Arrays for a Rhenium Experiment (MARE) for a direct calorimetric measurement of the neutrino mass with sub-electronvolt sensitivity. MARE is divided into two phases. The first phase consists of two independent experiments using the presently available detector technology to reach a sensitivity of the order of 1 eV, and to improve the understanding of the systematic uncertainties specific of the microcalorimetric technique. The two experiments are: MARE-1 in Milan, in collaboration with NASA/GSFG and the University of Wisconsin at Madison, and MARE-1 in Genoa. The goal of the second phase (MARE-2) is to achieve a sub-electronvolt sensitivity on the neutrino mass. The Milan MARE-1 arrays are based on semiconductor thermistors and dielectric silver perrhenate absorbers, AgReO 4 . To optimize the detector performance, crystals of silver perrhenate have been glued to the thermistors with different epoxy resins in order to determine the best thermal coupling. Now a 72 channel measurement is starting. To identify a shielding configuration that minimizes radioactivity background in the energy region of the 187 Re β spectrum, a preliminary study of the cryogenic laboratory environmental background has been performed. Using a planar germanium detector for the energy range below 10 keV, different shielding configurations have been realized to find the best thickness and material to shield the microcalorimeter arrays.

1. – Introduction Neutrino oscillation experiments have shown that neutrinos are massive particles, but they are not able to determine the absolute neutrino mass scale. Therefore, the neutrino mass is still an open question in elementary particle physics. Nowadays the only modelindependent experiments dedicated to neutrino mass determination are the kinematic c Societ`  a Italiana di Fisica

423

424

E. Ferri on behalf of the MARE Collaboration

ones based on the measurement of momentum and energy of electrons from single βdecay. The most stringent results come from electrostatic spectrometers on tritium decay (E0 = 18.6 keV). The Mainz/Troitsk collaboration has reached mν ≤ 2 eV/c2 [1]. The next-generation experiment KATRIN is designed to reach a sensitivity of mν ≤ 0.2 eV/c2 . To scrutinize the current and future results of Mainz/Troitsk and KATRIN, an entirely different method to determine the neutrino mass from single β-decay has been investigated. Thermal microcalorimeters measure the temperature rise induced by the energy deposition of the β-electron in a low heat capacity absorber. This method uses the nuclide with the lowest known end-point energy: 187 Re (E0 = 2.47 keV). It has been demonstrated in the past that observing the β-decay spectrum of 187 Re provides a suitable method to determine the mass of the anti-neutrino from the Kurie-plot end-point. At the beginning, a sensitivity of mν ≤ 15 eV/c2 was achieved with the experiments MIBETA in Milan and MANU in Genoa [2]. The MANU and MIBETA results together with the constant advance in the performance of low-temperature detectors open the door to a new large-scale experiment able to explore the sub-eV neutrino mass range. In this context, an international collaboration is growing around the project of Microcalorimeter Arrays for a Rhenium Experiment (MARE) for a direct calorimetric measurement of the neutrino mass with sub-electronvolt sensitivity. 2. – MARE MARE is divided into two phases. The first phase consists of two independent experiments using the presently available detector technology to reach a sensitivity of the order of 1 eV and to improve the understanding of the systematic uncertainties specific of the microcalorimetric technique. The two experiments are: MARE-1 in Milan, in collaboration with NASA/GSFG and the University of Wisconsin at Madison, and MARE-1 in Genoa. The goal of the second phase is to achieve a sub-electronvolt sensitivity on the neutrino mass. The Milan MARE-1 arrays (288 detectors) are based on semiconductor thermistors coupled to dielectric silver perrhenate (AgReO4 ) absorbers. These arrays, provided by the NASA/Goddard group, consist of 6 × 6 implanted Si:P thermistors with a size of 300 × 300 × 1.5 μm3 . An energy resolution of 2 eV for the Mn Kα line has been obtained with these thermistors. On their top single crystals of AgReO4 are glued with epoxy resins. The crystals, the mass of which is around 500 μg, are cut in regular shape of 600 × 600 × 250 μm3 . To realize a defined thermal coupling between the thermistor and the rather large absorber, silicon pieces of 300 × 300 × 10 μm3 are glued between them. With all 288 detectors with an energy and time resolution of about 25 eV and of 250 μs, respectively, a sensitivity of 3.3 eV at 90% CL on the neutrino mass will be reached within 3 years. This corresponds to a statistics of about 7 × 109 decays [3]. The read-out electronics of MARE-1 in Milan is characterized by two stages: the preamplifier cold stage, based on JFETs which work at about 135 K, and the amplifier stage at room temperature. To electrically connect the cold electronics to the detectors with low thermal conductance wires, microbridges are fabricated by the ITC-irst in Trento, Italy. The microbridges are thin wires (thickness around 200 nm) made of Ti or

MARE-1: A next-generation calorimetric neutrino mass experiment

425

Al deposited onto polyamid. The microbridges provide thermal decoupling between detectors and JFETs, but they do not guarantee mechanical stability. Therefore, materials with very low thermal conductivity are used as mechanical support, namely Kevlar and Vespel. Ti microbridges and Kevlar are used in order to thermally decouple the detectors from the JFET holder (4 K) and Al microbridges and Vespel to thermally decouple the JFET box from the JFETs. The cryogenic setup is mounted in the Kelvinox KX400 dilution refrigerator located in the Cryogenic laboratory in the Physics Departement of Milano-Bicocca University. The dilution unit is equipped with a copper rod which is used to hold the structure of the JFET electronics at 4.2 K, very close to the arrays at 35 mK. The energy calibration system is located between the detector holder and the JFETs boxes. The calibration system consists of four fluorescence sources with 10 mCi of 55 Fe as a primary source movable in and out of a lead shield [4]. The fluorescence targets are made of Al, Ti, CaF2 and NaCl to allow a precise energy calibration around the end-point of 187 Re with the Kα X-rays at about 1.49, 1.74, 2.31, 2.62 and 3.69 keV. 3. – Detector performance To optimize the detector performance we have equipped a test array to determine the best thermal coupling between Si thermistors and AgReO4 absorbers. Therefore different kinds of glues were tested to attach silicon spacers on the thermistors and AgReO4 crystals on the spacers, respectively. The masses and the resins combinations are listed in table I together with the baseline and the energy resolution achieved near the 187 Re end-point [5]. The results of table I indicate that the combination Araldit R/Araldit R is favourable over the other glue combinations, but this epoxy resin deteriorates during the years and probably also due to thermal cycling. Therefore, the ST2850 has to be used to glue AgReO4 absorbers on the silicon spacers. We would like to point out that MIBETA also used ST2850 to directly glue the AgReO4 crystals onto the thermistors; no spacers were needed in that experiment. Currently the last test is ongoing, in order to evaluate the crystal quality. In spring 2009, the 72 channel measurement is expected to start. 4. – Enviromental background To identify the best shielding approach that minimizes radioactivity background in the energy region of the 187 Re β spectrum, a preliminary study of the Cryogenic laboratory environmental background was performed. Using a planar germanium detector for the energy range below 10 keV, we have set up different shielding configurations to find the ideal thickness and the best material to shield the microcalorimeter arrays. The detector, characterized by an energy resolution of 195 eV at 5.9 keV, is covered by a very thin Be window, the thickness of which is around 0.127 mm. The detection threshold is around 1 keV. The background spectrum shows peaks at the position of Pb Kα1 , Kα2 and Kβ1 . These peaks rise above a continuous background. In order to reduce the environmental

426

E. Ferri on behalf of the MARE Collaboration

Table I. – Listed are different absorber masses and their respective resin combinations. The first resin is between the thermistor and the silicon spacer and the second one between silicon spacer and AgReO4 absorber. (Araldit R = Araldit Rapid and Araldit N = Araldit Normal). The asterisk marks the same detector as the first line but measured two years later. AgReO4 mass (μg)

resin

baseline (eV)

ΔEFWHM (eV)

402 388 456 470 406 442 506 430 390 386 273 300 427 ∗ 402

Araldit R/Araldit R Araldit R/Araldit R Araldit R/ST2850 Araldit R/ST2850 ST1266/ST2850 ST1266/ST2850 ST2850/ST2850 ST2850/ST2850 SU8/ST2850 SU8/ST2850 Araldit R/Araldit R Araldit R/Araldit R Araldit N/Araldit N Araldit R/Araldit R

14 28 21 33 22 30 113 132 131 190 18 12 36 35

28 36 37 38 38 41

22 17 44 36

background, we have built different shields around the germanium detector made of lead, copper and lead plus copper (like “onion” shielding). It turned out that the best configuration is a lead shield. But in the past, background spectra acquired in the MIBETA experiment have shown that a shield made of lead increases the background due to escape peaks resulting from the interaction of the Pb X-rays with Ag and Re atoms in the AgReO4 absorbers. Therefore, since copper is better than lead for shielding, we have studied the background reduction due to a copper shield [2]. We have shielded the Germanium detector putting a copper cup with variable thickness. With a thickness of around 40 mm, the maximum space in the cryostat, we achieve a reduction of 70%. To investigate the background suppression in the microcalorimeters inside the cryostat, a Monte Carlo simulation has been performed. Simulating the two detector types and the incoming X-rays it is possible to compare the respective detection efficiences for X-rays for energies from 0 to 19 keV. From these Monte Carlo simulations it can be said that the background reduction in microcalorimeters should be even more efficient than in the germanium detector. REFERENCES [1] [2] [3] [4] [5]

Angrik J., Katrin design report 2004. Sisti M. et al., Nucl. Instrum. Methods Phys. Res. A, 520 (2004) 125. Nucciotti A., J. Low Temp. Phys., 151 (2008) 597. Schaeffer D. et al., J. Low Temp. Phys., 151 (2008) 623. Kraft-Bermuth S. et al., J. Low Temp. Phys., 151 (2008) 619.

DOI 10.3254/978-1-60750-038-4-427

Different approaches to CUORE background analysis L. Gironi, M. A. Carrettoni, C. G. Maiano and L. M. Pattavina Dipartimento di Fisica “G. Occhialini”, Universit` a di Milano-Bicocca and INFN, Sezione di Milano-Bicocca - Milano, Italy

Summary. — Neutrino oscillation experiments have unequivocally demonstrated that neutrinos have mass and that neutrino mass eigenstates mix. One possible way to determine the scale of the neutrino mass and its nature is to investigate the neutrinoless double-beta decay(0νdbd). The CUORE experiment is designed with a sensitivity capable of probing all but a small portion of the Majorana electron neutrino effective mass range. CUORE is an array of 988 TeO 2 bolometers. The signal of neutrinoless double-beta decay for 130 Te would be a sharp peak at 2530 keV. The rarity of the process under consideration makes its identification very difficult. The main task in 0νdbd searches is to understand and to diminish the background as much as possible. In order to reach this goal, different techniques are employed: Monte Carlo simulations, alpha-spectroscopy and pulse shape discrimination.

1. – Introduction - 0νdbd Although the existence of neutrino oscillations (and consequently of massive neutrinos) seems now to be well proved, several properties of the neutrino family have still to be fixed. Measuring the masses, the mixing angles (and phases) as well as accessing the Dirac/Majorana nature of neutrinos will be the goal of the next-generation experiments. In this scenario an important role is played by neutrinoless double-beta decay searches c Societ`  a Italiana di Fisica

427

428

L. Gironi, M. A. Carrettoni, C. G. Maiano and L. M. Pattavina

which will probe the Majorana nature of neutrinos (as foreseen by the majority of theories) allowing in the meantime to obtain information on the neutrino mass hierarchy and scale. The challenge of these experiments is the realization of a large mass (of the order of tons) counting facility with extremely low background. 2. – Double-beta decay with TeO2 bolometers Natural tellurium contains about 33.8% of the isotope 130 Te that, given its high Qββ value (2530 keV) and its favorable nuclear factor of merit, is one of the most interesting candidates for study. To scale sensitivity toward the next-generation experiment frontier (approximately tens of meV) a favorable candidate is not enough: a technique that guarantees large operating masses, high energy resolution and low achievable background is indeed mandatory. The so-called “source ⊆ detector” configuration, where the candidate nuclei are contained within the active mass of the detector, makes mass scaling toward high values easy and natural. In this configuration the decay signal would appear in the background spectrum of the detector as a peak at the Qββ value of the decay and the sensitivity is determined on one side by the detector mass and energy resolution and on the other by the background level. CUORE (Cryogenic Underground Observatory for Rare Events) is a proposed tightly packed array of 988 TeO2 bolometers [1], each being a 5 × 5 × 5 cm3 cube with a mass of 750 g operating at 8–10 mK. The CUORE know-how is based on the experience gained in almost 25 years by the Milano group in bolometers technology [2] and culminated in CUORICINO experiment [3]. CUORE detector array will consist of 19 vertical towers, each divided into 13 layers of 4 crystals. 3. – Coincidences and pulse shape analysis The array is designed in order to have the most compact structure reducing to a minimum the distance between the crystals and the amount of inert material interposed between them. This will maximize the efficiency of the anticoincidence cut in order to reduce the background produced by degraded alphas present on the crystal surfaces. An important role in the recognition of these coincidences patterns is played by the high sensitivity of bolometers to any energy depositions which offers, for example, the possibility to discard surface contamination by identifying the nucleus recoil on a crystal and the emitted alpha in another one. Such powerful detection efficiency is at the same time a disadvantage of the bolometric approach: any physical process, such as cryostat instabilities or vibrations, may cause a temperature rise that can trigger the acquisition. All these spurious signals can be difficult to recognize, expecially in the lower part of the spectrum, where the signal-to-noise ratio is low. Since the shape discrimination of these low-energy pulses is so crucial, each acquired event will be processed with an optimum filtering technique, in order to maximise the signal-to-noise ratio. This technique has been fully tested and used during Cuoricino analysis, showing a strong noise reduction.

Different approaches to CUORE background analysis

429

After the filtering, a set of shape-sensitive parameters are computed from the acquired signals. This procedure takes advantage from another feature of bolometers: the rise time of particle-induced signals is proportional to the sound velocity in the crystal and to the interface between the absorber and the thermistor used for temperature-to-voltage conversion, while the decay time depends mainly on the effective thermal impedance of the link with the thermal bath. This implies that the particle signals shape depends mainly on the structure of the crystal and on the detector assembly and it is independent, at least at the first order of magnitude, of the incident energy. This offers the possibility to identify regions in the parameters space where good signals show similar structures. 4. – CUORE Background The possibility of studying rare events such as 0νdbd is strongly influenced by the background in the region of interest of the energy spectrum. In a deep underground laboratory the background is ascribed to different sources such as environmental γ radioactivity, cosmic rays, neutrons, radon and contamination of materials with which detectors and their shielding are made. The reduction of these background sources is possible by the construction of shields and placing the experiment in a deep underground laboratory. For this reason CUORE will be located in the underground hall A of Laboratori Nazionali del Gran Sasso (LNGS) at a depth of ∼ 3400 m.w.e. In order to shield the detectors from environmental γ radioactivity (the most energetic γ is 208 Tl line at 2615 keV) about 25 cm of lead are planned to be placed outside the cryogenic apparatus to shield the detector from the bottom and from the sides radiations. An equivalent shielding from the up-coming radiation has to be placed inside the cryostat, a 30 cm thick lead disk. A lead ring-shaped shield closes the gap between the lead disk above the detector and the 6 cm internal lead layer positioned near the sides and near the bottom of the detector. In order to define and optimize the shielding for CUORE, different Monte Carlo simulations were carried out with the GEANT4 code, which is able to simulate transport and interaction of particles in matter. The results of these analyses have allowed also to evaluate the maximum levels of contamination acceptable for the cryostat and for the shielding itself, imposing limits on the choice of construction materials and geometry of shielding. Outside the lead shield an 18 cm polyethylene shield will be placed in order to thermalize environmental neutrons that will be then absorbed by the 2 cm of boric acid located between the lead and the polyethylene itself. Monte Carlo simulations indicate that such shield will be able to limit neutron-induced background to a rate far below the required level for CUORE. 5. – Surface contaminations and recontaminations Previous studies of the background, like Cuoricino’s one, allow to state that surface alpha contamination is the predominant source of avoidable background, even in the

430

L. Gironi, M. A. Carrettoni, C. G. Maiano and L. M. Pattavina

0νdbd region. An accurate identification and localization of α contamination seems to be mandatory. With SBD (Silicon Barrier Detectors) it is possible to perform a detailed screening of the materials which are candidates to be employed for CUORE. The SBD are semiconductor detectors suitable for charged-particle radiation: they are made of a thin dead layer (few tens of nm) and semiconductor surface area of 1200 mm2 and active layer of about hundreds of microns. They offer an energy resolution of about 30 keV at 5 MeV. The study of the surface contamination is made mainly out of three steps: – Calibration and identification of the alpha counts and peaks. This is the most difficult part of the analysis because we have to deal with low background measurements, about 10−7 Bq/cm2 . – Comparison between different sample spectra in order to estimate the detector background and identify the effective material contamination. SBD are always faced to some inert material (the chamber in which the measure is performed), so a thorough analysis is required to recognize the detector internal contaminations. – Evaluation of the contamination depth exploiting Monte Carlo simulations. Once chosen and applied the best cleaning technique, recontaminations caused by the exposure to the natural atmosphere (during shipment and storage) is still possible. In fact, as it is well known, the environment is rich of 238 U and of its daughters which are the major components of natural radioactivity. One of the elements in the 238 U decay chain is 222 Rn which is a gas; this can diffuse through the atmosphere and through different materials. The radon decays and it becomes 210 Pb with a half-life of 22.3 years, this is much longer than all the others 222 Rn daughters. This radioactive element, with such a long half-life, will affect the radiopurity of the experiment since it will be present in the experimental set-up for many τ (210 Pb). 210 Po is a 210 Pb daughter that decays emitting a 5.3 MeV alpha particle. Now, if the polonium is implanted in the materials then the alphas may lose part of their energy in the materials and this energy loss can produce some counts in the 0νdbd region. In order to keep under control any possible radon contamination, a thorough analysis of these possible recontaminations is carried out, taking into account radon/polonium diffusion profile related to the time exposure of the different CUORE materials. REFERENCES [1] Ardito R. et al. (The CUORE Collaboration), arXiv:hep-ex/0501010 (2005). [2] Fiorini E. and Niinikoski T., Nucl. Instrum. Methods, 224 (1984) 83. [3] Arnaboldi C. et al. (The Cuoricino Collaboration), arXiv:hep-ex/0802.3439v1 (2008) and references therein.

DOI 10.3254/978-1-60750-038-4-431

Intermediate-energies π-induced reactions studied with a streamer chamber I. Gnesi on behalf of PAINUC Collaboration Centro studi e Ricerche “E. Fermi” - Roma, Italy Dipartimento di Fisica Generale, Universit` a di Torino e INFN, Sezione di Torino - Torino, Italy Joint Institute for Nuclear Research - Dubna, Russia

Summary. — The interaction with two charged particles in the final states between negative pions at 106 MeV and helium nuclei has been studied with the Self Shunted Streamer Chamber at the Joint Institute for Nuclear Research in Dubna. In the neutron knockout channel we observed the first evidence of Δ− excitation. In the channel with the emission of a γ we observed a γ energy spectrum that is in good agreement with a Planck black-body radiation distribution at a temperature of 14 MeV. A Monte Carlo simulation of inflight pion decays, within our chamber, has been performed to study the possibility of upgrading the upper limit of the muon neutrino mass; at 90% c.l. we obtained a prevision of Mν < 7 MeV.

1. – Introduction Experimental studies on the various π ±4 He interaction channels are important for undestanding the pion-nucleus dynamics and for addressing unresolved issues about the nuclear structure, which is far from being understood. The optical model [1] was the first attempt for modeling πp scattering while subsequent studies were dedicated to the description of complexes of nucleons (see [2]). Later, the effects of the so-called “nuclear matter” were observed in elastic and inelastic pion-nucleus scattering. Excitation of the Δ resonance in elastic reactions was found to be mass-dependent and angle-dependent (see ref. [3]) in agreement with the hypothesis of a collective isobaric resonance activation. The inelastic channels revealed the existence of several nuclear medium effect; among them, clustering effects, multiple scattering effects, pion absorption on multiple nucleon systems (see ref. [4]) provided information about the quasi-deuteron and quasi-helium substructure of nuclei, highlighted c Societ`  a Italiana di Fisica

431

432

I. Gnesi on behalf of PAINUC Collaboration

the activation of resonances, also in inelastic reactions, and allowed the study of Coulomb barrier effects [5]; but, nevertheless, there actually exists no comprehensive model. The investigation on π ±4 He interaction at energies below the QCD transition phase [6] (on which much effort is focused, at present) and in the region where the hadron-gas state transition is expected in heavy nuclei (see [7]) should reveal effects about this intermediate state of nuclear matter in light and deeply bound nuclei, such as 4 He. The most recent experimental studies (see ref. [8] and references therein) of pion interactions performed at energies in the region of and below the Δ(1232) resonance have provided high-statistics information on various multinucleon pion absorption and charge exchange reaction channels. Although a semiclassical pick-up model was applied in these recent works to explain the observed knockout and breakup reaction channels, no agreement with experimental data was achieved. Nowadays, the field of experimental low-energy nuclear physics is of interest for measuring the mass of neutrinos, which are fundamental quantities for the completion of SM. 2. – Brief description of the experimental apparatus The experimental apparatus we used is a magnetic spectrometer with a Self Shunted Streamer Chamber (SSSC) placed in a magnetic field of 0.65 T. The streamer chamber serves simultaneously as a low-density target and a triggerable track detector (as well as a vertex detector), thus combining the useful features of the visualizing techniques and of electronic detectors (such as MWPC). The chamber consists of a 470 × 600 × 160 mm3 fiducial volume filled with 4 He at atmospheric pressure. The triggering system based on 7 scintillators selects the events occurring within the fiducial volume. The electronics controls a high-voltage power generator (250 kV). The emitted light from the discharge channels along the particle tracks is captured by a high-resolution and sensitivity stereoscopic CCD system. Data acquisition system provides digitized CCD videoimages of nuclear events, that can be handled on-line during experimental runs. The triggering signal was driven by pions or protons with energies 6 MeV and 18 MeV, respectively. We detected the particles scattered within [20,160] degrees with respect to the incident pions direction. The experimental apparatus is described in detail elsewhere [9]. It must be stressed that in the present study advantage is taken of the following: with the DUBTO streamer chamber filled with a gas at atmospheric pressure a complete kinematical analysis of nuclear reactions involving very low-energy short-ranged charged secondaries is possible. Thus, the path range of a 5.0 MeV α-particle in 4 He at atmospheric pressure exceeds 20 cm, resulting in a readily measurable track. 3. – Experimental results Analysing π ±4 He interaction at T = 106 MeV we obtained the first evidence for the existence of π ± (4 He, 4 He)π ± γ channel in which a high-energy γ is produced. In fig. 1, upper-right plot, the differential cross-sections for π ± (4 He, 4 He)π ± and π ± (4 He, 4 He)π ± γ channels are shown: the emission of the γ is nearly isotropic. The upper-left plot shows the γ energy distributions, both for π + and π − fitted with a Planck black-body radiation

Intermediate-energies π-induced reactions studied with a streamer chamber

433

Fig. 1. – (Colour on-line) Recent PAINUC collaboration results (see text).

curve. The isotropic γ emission, their energies (higher than the 4 He binding energy) and the high branching ratio of the channel are well explained with a black-body model,

434

I. Gnesi on behalf of PAINUC Collaboration

revealing a temperature T = 14–16 MeV for the 4 He nucleus when excited with a T = 106 MeV pion beam (see ref. [10]). The π − (4 He, 3 He)π − n knockout channel shows a bimodal θn3 He outgoing angle distribution, plotted in fig. 1, second row, left plot, in contradiction with the expected phase-space (green curve). The event at intermediate angles (red area) gives a resonant π − n invariant mass distribution, with Mπ− n ∼ 1160 MeV and Γ/2 ∼ 20 MeV. The mass spectra is shown in fig. 1, second row, right plot, red curve. This is the first esperimental evidence for Δ− in medium excitation and the left shift of the mass w.r.t. the free Δ− mass (1232 MeV) can be explained with a collective isobaric resonance excitation (see refs. [3] and [11]). The collaboration has also analysed π + (107 Ag, 105 Ag)π − pp and π + (107 Ag, 103 Ag) π − ppnn DCX reactions on nuclear photoemulsion (ref. [12]). The π − pp spectrum, shown in fig. 1, third row, left plot, is a confirmation of the existence of a dybarionic resonance, J P = 0− , B = 2 and mass M = 2050 MeV, called d . The π + nn spectrum obtained with the SSSC in π + (4 He, pp)π + nn reaction channel is shown in fig. 1, third row, right plot and confirms previous results on nuclear photoemulsion. The lower-left plot in fig. 1 shows the image of a p ¯20 Ne annihilation event with a + + + + complete π → μ νμ , μ → e ν¯μ νe decay chain. From such event an upper limit of mν (μ) < 2.2 MeV at 90% of c.l. has been obtained (see ref. [13]). A study has been performed to evaluate the possibility of increasing the limit measuring π ± decays in SSSC, with the possibility of observing both νμ and ν¯μ . All the error sources have been taken into account, and the influences of the hypothetical ν mass and measurement error have been studied. In fig. 1, lower-right plot, the νμ mass upper limit vs. the given confidence level is shown. At 90% of c.l., it is mν (μ) < 7 MeV, half of the recently published bound by MINOS collaboration with a 734 km baseline experiment ν beam TOF measurement. The collaboration is studying the possibility to increase the momentum resolution of the SSSC, in order to obtain a new upper limit for the muon neutrino mass. REFERENCES [1] [2] [3] [4] [5] [6] [7] [8] [9] [10] [11] [12] [13]

Fernbach S., Serber R. and Taylor T. B., Phys. Rev., 75 (1949) 1352. Budagov Yu. A. et al., Sov. Phys. JETP, 15 (1962) 824. Balestra F. et al., Nuovo Cimento A, 55 (1980) 273. Balestra F. et al., Nucl. Phys. A, 340 (1980) 372. Balestra F. et al., Lett. Nuovo Cimento, 12 (1975) 351; 13 (1975) 673; Balestra F. et al., Nuovo Cimento A, 78 (1983) 331. Rapp R. and Wambach J., Adv. Nucl. Phys., 25 (2000) 1. Viola V. et al., Nucl. Phys. A, 734 (2004) 487. Alteholz T. et al., Nucl. Instrum. Methods Phys. Res. A, 373 (1998) 374; Mateos A. O. et al., Phys. Rev. C, 58 (1998) 942. Andreev E. M. et al., Nucl. Instrum. Methods Phys. Res. A, 489 (2002) 99. Angelov N. et al., Nuovo Cimento B, 121 (2006) 771. Angelov N. et al., Eur. Phys. J. A, 34 (2007) 255269. Batusov Yu. A. et al., Eur. Phys. J. A, 28 (2006) 11. Angelov N. et al., Nucl. Phys. A, 780 (2006) 78.

DOI 10.3254/978-1-60750-038-4-435

Features of SN signal for massive neutrinos using LVD simulated events A. A. Machado CNPq - Brasilia, Brazil INFN, Laboratori Nazionali del Gran Sasso - Assergi (AQ), Italy

G. Pagliaroli University of L’Aquila - L’Aquila e INFN, Laboratori Nazionali del Gran Sasso Assergi (AQ), Italy

F. Vissani INFN, Laboratori Nazionali del Gran Sasso - Assergi (AQ), Italy

W. Fulgione Istituto Nazionale di Astrofisica, IFSI - Torino e INFN, Sezione di Torino - Italy

Summary. — We consider the neutrino signal from a future core collapse supernova detected by the LVD experiment at the Gran Sasso National Laboratory. We generate a sample of Monte Carlo events accounting for the detector response. The effect of neutrino masses on the expected signal will be studied for a supernova exploding at different distances.

1. – The LVD experiment The Large Volume Detector (LVD), located in the INFN Gran Sasso National Laboratory, at the depth of 3600 m.w.e., is a 1 kt liquid scintillator detector whose major purpose is to study neutrino bursts from a Gravitational Stellar Collapse (GSC) in our Galaxy [1]. In spite of the lack of a standard model of GSC, the correlated neutrino emission appears to be well established. At the end of its burning phases a massive star (M > 8M ) explodes into a Supernova (SN), originating a neutron star which emits a large amount of neutrinos that carry away 99% of the binding energy EB ∼ 3 × 1053 ergs. The largest part of this energy, almost equipartitioned among neutrino and antineutrino c Societ`  a Italiana di Fisica

435

436

Fig. 1 Fig. 1. – LVD efficiency.

A. A. Machado, G. Pagliaroli, F. Vissani and W. Fulgione

Fig. 2

Fig. 2. – The integrated rate of background events on LVD.

species, is emitted in the cooling phase: Eν¯e ∼ Eνe,μ,τ ∼ EB /6. The energy spectra are approximate Fermi-Dirac distributions with different temperatures. The experiment has been taking data since 1992. LVD consists of an array of 840 scintillator counters, 1.0 × 1.0 × 1.5 m3 each one. The whole array is divided into three identical towers with independent high-voltage power supply, trigger and data acquisition. Since 2005, all the LVD counters are operating at the same energy thresholds (EH = 4 MeV and EL ∼ 1 MeV). The LVD counter energy resolution has been studied by comparing the energy spectra obtained by different sources (γ from (n, p) capture, μ-decay electrons, γ’s from (n, Ni) capture) with the Monte Carlo simulation. The following function represents the best approximation of the single counter energy resolution in terms of σE /E: (1)

σE /E = 0.07 + 0.23 × (E/MeV)−0.5 ,

that means FWHM/MAX = 0.33 for 10 MeV electrons(1 ). The observation of neutrinos is made mainly through the inverse beta decay reaction of electron anti-neutrinos on scintillator protons ν¯e + p → n + e+ which gives two detectable signals: the prompt one due to the e+ (visible energy Evis = Eν¯e − 0.8 MeV) followed by the neutron capture n + p → d + γ (Eγ = 2.2 MeV), mean Δt = 185 μs. The efficiency function η(E) used in the MC simulations, and displayed in fig. 1, reaches 90% at Evis = 7 MeV, and 95% at Evis = 10 MeV. (1 ) Because of its geometry and dimensions, the energy counter response in not uniform and spectra are not symmetric.

Features of SN signal for massive neutrinos using LVD simulated events

437

Fig. 3 Fig. 4 Fig. 3. – Number of events as a function of the distance considering the two threshold energy at 7 and 10 MeV. The Galactic Center is located at 7.7 kpc and the Large Magellanic Cloud at 50 kpc of distance. Fig. 4. – Signal and background simulated events for a SN collapse at the Galactic Center.

The expected signal event rate from a SN as a function of the distance is given by (2)

dN (D) = Np × σIBD (Eν ) × Φν (Eν , t, D) × η(E), dEν dt

where Np is the number of target protons, σIBD is the inverse beta decay cross-section, η(E) is the LVD efficiency, and Φν (Eν , t, D) is the ν¯e flux constructed following the analysis reported in [2]. The number of expected events is obtained by integrating this function in energy and time. The integrate rate of background events is shown in fig. 2. For a time interval of 20 s, Evis ≤ 50 MeV and a distance D = 20 kpc, we obtain 4 events for Evis ≥ 7 MeV and 0.5 for Evis ≥ 10 MeV. The functions that give the number of expected events in LVD (scaled by 10 kpc) are  2 10 Nevents (D) = 226.7 × (3) + 4, for Eth = 7 MeV, D  2 10 (4) + 0.5, for Eth = 10 MeV. Nevents (D) = 213.5 × D In fig. 3 we can see these two functions, where the upper line corresponds to a 7 MeV threshold and the lower line at 10 MeV. The detector sensitivity decreases in the dark region of the figure, namely for D > 50 kpc. 2. – Events simulation We generated a sample of Monte Carlo events accounting for the experiment response for a SN collapse in the Galactic Center (GC). The distance of GC was calculated by different authors, see [3] for a review. We adopted the value 7.7 kpc for the simulation displayed in fig. 4. Background events are contained in the region between the two

438

A. A. Machado, G. Pagliaroli, F. Vissani and W. Fulgione

Fig. 5 Fig. 6 Fig. 5. – MC events at D = 20 kpc for mν = 0, 1, 3 and 5 eV. Fig. 6. – MC events at D = 7.7 kpc for mν = 0, 3, 5 and 7 eV.

energy threshold values (7 and 10 MeV) and the neutrino burst is concentred in a time window of 14 s. . 2 1. Time delay. – The shape of the neutrino signal can be affected by the delay time correlated to different mass values. The delay time written as  m 2  E −2 D ν (5) Δt(mν , E) = 0.51 s eV MeV 10 kpc was taken into account to construct the flux of ν¯e in eq. (2). In order to analyze this effect, we generated two samples of events, one at 20 kpc (the distance for which LVD still have good sentitivity), and one at 7.7 kpc. For a distance of 20 kpc, the Monte Carlo produced 57 events on average. Using mass values of 0, 1, 3 and 5 eV, we observe a variation in the distribution of signals in the low-energy region see fig. 5. The same effect is seen, in a bigger sample (368 events), when the distance is 7.7 kpc. In the latter case, the neutrino masses considered were 0, 3, 5 and 7 eV, see fig. 6. A more accurate analysis in the low-energy range is underway. 3. – Conclusions We showed, through a Monte Carlo simulation, the possibility to detect by LVD experiment the correlation between energy, arrival times of the signals and ν mass values for a GSC at different distances. The presence of a finite neutrino mass produces a distortion of ν¯e spectra as a consequence of the delay time introduced in eq. (5) that is a function of the ν energy. REFERENCES [1] LVD Collaboration, Nuovo Cimento A, 105 (1992) 1793; Agafonova N. Yu. et al., Astroparticle Phys., 28 (2008) 516; Porta A., Ph.D. Thesis, Torino University (2005) and INAF IFSI-TO, Int. Rep. n. 15/2007. [2] Pagliaroli G. et al., Astroparticle Phys., 31 (2009) 163. [3] Groenewegen M. A. T., Udalski A. and Bono G., Astron. Astrophys., 481 (2008) 441.

DOI 10.3254/978-1-60750-038-4-439

Minimal renormalizable SO(10) splits supersymmetry M. Nemevˇ sek, B. Bajc and I. Dorˇ sner Joˇzef Stefan Institute - Jamova cesta 39, 1000 Ljubljana, Slovenia

Summary. — We have revisited the minimal renormalizable supersymmetric grand unified theory (MSGUT) based on the group SO(10) with two Higgs superfields, 10 and 126, responsible for the masses of the fermions. The model has previously been shown to be inconsistent with current data on fermion masses. After a careful analysis, taking into account the calculated spectrum of all the heavy particles which influence the running of the gauge and Yukawa couplings, we find out that the overall scale of neutrino mass is an order of magnitude too small, when unification takes place in the low SUSY regime. However, if one allows for the splitting between the masses of sfermions and the other SUSY partners, preliminary results show that one is able to obtain a fit of all the light fermion masses, including the large enough neutrino mass scale. This step also eliminates the dangerous contribution of d = 5 proton decay operator which in turn leaves us with a clear prediction of the proton decay rate mediated by the d = 6 operator and a nonzero Ue3 .

1. – Minimal renormalizable supersymmetric SO(10) We have addressed the viability of the minimal renormalizable supersymmetric grand unified theory (MSGUT) model in the context of SO(10) gauge group [1]. The theory is attractive because it contains the right-handed neutrino in the spinorial 16F representation and an SU (2)L triplet in the 126H , which gets a small vacuum expectation value, therefore neutrinos naturally receive a small mass via type I+II seesaw. c Societ`  a Italiana di Fisica

439

440

M. Nemevˇ sek, B. Bajc and I. Dorˇ sner

The model is dubbed minimal due to the small number of couplings in the superpotential and although large representations are employed, the model is predictive. The superpotential consists of all renormalizable terms with Higgs representations 10H , 126H , 126H and 210H : (1)

W = 16F (Y10 10H + Y126 126H )16F λ M η m 126H 126H + 126H 210H 126H + 2102H + 2103H + 4! 4! 5! 5! 1 +mH 10H 2 + 210H 10H (α126H + α126H ). 4!

This superpotential has been carefully studied and after a fine-tuning which is required to have two light Higgs doublets, we are left with only eight real parameters in the Higgs sector: (2)

m,

α,

α,

|λ|,

|η|,

φ = arg(λ) = − arg(η),

x = Re(x) + i Im(x).

The whole mass spectrum of the heavy Higgses has been given in [2] and we have determined the one loop beta coefficients and masses of the gauge bosons in terms of the above parameters. Thus we can calculate the running of gauge couplings, fermion masses and mixing angles from MZ to MGUT including all the threshold corrections. The matter fermions in 16F are coupled to only two Higgses, namely 10H and 126H , therefore the Yukawa matrices Y10 and Y126 in eq. (1) are not independent in contrast to the standard (or MSSM) model. They are complex symmetric matrices and their dependence can be conveniently expressed using a sum rule for charged fermions: (3)

Mu =

Nu tan β[Md + ξ(Md − Me )] Nd

and also for neutrino masses (4)

v sin2 β α Mn = m cos β

:

|λ| Nu2 [mI fI + mII fII ]. |η| Nd

Here Nu,d and fI,II are functions of the parameters (2) and mI,II are mass matrices from type I and II contributions (exact expressions are given in [3]). To count the number of free parameters in the Yukawa sector, we use a congruent transformation to go to the basis where one of the matrices is diagonal and real and therefore has 3 real parameters and the other is complex symmetric with 12 real parameters. The issue at hand is whether one can satisfy the above relations with these 15 parameters and accommodate all the masses and mixing angles of charged and neutral fermions in a perturbative unified theory with a slow enough proton decay rate. Since the above relations are valid at the GUT scale, such an analysis is further complicated by a system of nonlinear differential equations describing the running, therefore our approach is

Minimal renormalizable SO(10) splits supersymmetry

441

numerical. For each set of parameters we run the gauge couplings to the GUT scale and if they unify, we use the central values of fermion masses and mixing angles in our fit to determine the validity of the above relations. 2. – The overall neutrino scale and proton decay lifetime The main issue concerning this model is the connection between the proton decay rate and the overall scale of neutrino masses. One can think of neutrino masses coming from d = 5 Weinberg operator yeff (LH)(LH)/Λ and it turns out that the cutoff is around 1014 GeV for Yukawas of order one and neutrino masses of 0.1 eV. The role of Λ in this particular model is realized by the only mass parameter m in eq. (4). However, the heavy gauge bosons are proportional to the same parameter, which is therefore directly connected to the proton decay rate. The bound on d = 6 operator coming from p → π 0 e+ decay channel is around 1016 GeV and this creates a tension between the proton decay rate and the neutrino mass scale. As it was argued in [3], this tension is a serious issue, unless one is able to find a cancellation in type I case or one tries to find the solution for mass fits near singular points of fI,II , enhancing the overall scale. This has been investigated [4, 5] and the conclusion was that either neutrino mass is too low, or unification does not take place. We show how this tension is realized in the low SUSY regime, therefore eliminating this part of the parameter space and then we solve the problem by splitting the masses of gauginos and sfermions. 3. – MSSM vs. split supersymmetry The only “fast” parameter in the theory is the complex parameter x, meaning that the masses of gauge and Higgs bosons vary rapidly with it. By setting λ = η = α = α = 1, we find that the region in the complex x-plane where unification takes place does not coincide with any of the singular points of fI , therefore pure type I dominance is excluded. We further focus on type II and find regions where neutrino mass is enhanced, but the overall scale is roughly two orders of magnitude too small, when unification takes place. We further proceed by taking into account the variation of all the superpotential parameters to enhance the overall scale and we scan the complex x-plane for a good fit with different values of tan β. We are able to obtain good fits, however the mass of the heaviest neutrino is still a factor of 6 too small. We therefore conclude that, although our approach of neutrino scale maximization in terms of superpotential parameters (and not some special singular points) gives an improvement of more than one order of magnitude, the minimal theory still fails to accommodate neutrino masses and mixing angles with a low-SUSY spectrum. We can get out of this impasse by considering a split between gauginos and sfermions, setting the former at around TeV and the latter at 1012 GeV. By using the appropriate equations for running, we repeat the above procedure and preliminary results give good solutions with a low χ2 and large enough neutrino masses with a dominant type II

442

M. Nemevˇ sek, B. Bajc and I. Dorˇ sner

Fig. 1. – Split-SUSY scenario results with a good fit and large enough neutrino mass scale is shown for three different values of tan β. Scattered points correspond to different values of x.

contribution, as shown in fig. 1. The benefit of heavy sfermions is that our analysis is not affected by finite threshold corrections to fermion masses and moreover the dangerous d = 5 proton decay operator is suppressed. Therefore only the d = 6 operator is present, which depends on the masses of heavy gauge bosons and mixing matrices resulting from the fit. We also present the nonzero value of sin θ13 = 0.1 ± 0.01, the only parameter in the PMNS mixing matrix yet to be measured. ∗ ∗ ∗ ´ for discussions and encouragements. This It is a pleasure to thank G. Senjanovic work has been supported by the Slovenian Research Agency (B.B. and M.N.) and by the Marie Curie International Incoming Fellowship within the 6th European Community Framework Program (I.D.). REFERENCES [1] Bajc B., Dorˇ sner I. and Nemevˇ sek M., JHEP, 0811 (2008) 007 (arXiv:hepph/0809.1069) [2] Bajc B., Melfo A., Senjanovic G. and Vissani F., Phys. Rev. D, 70 (2004) 035007 (arXiv:hep-ph/0402122). [3] Bajc B., Melfo A., Senjanovic G. and Vissani F., Phys. Lett. B, 634 (2006) 272 (arXiv:hep-ph/0511352). [4] Aulakh C. S. and Garg S. K., Nucl. Phys. B, 757 (2006) 47 (arXiv:hep-ph/0512224). [5] Bertolini S., Schwetz T. and Malinsky M., Phys. Rev. D, 73 (2006) 115012 (arXiv:hepph/0605006).

DOI 10.3254/978-1-60750-038-4-443

Absolute neutrino mass from helicity measurements C. C. Nishi Institute of Physics “Gleb Wataghin”, University of Campinas, UNICAMP 13083-970, Campinas, SP, Brasil

Summary. — The possibility to access the absolute neutrino mass scale through the measurement of the wrong helicity contribution of charged leptons is investigated in pion decay. Through this method, one may have access to the same effective mass m2β extractable from the tritium beta decay experiments for electron neutrinos as well as the analogous effective mass (m2νμ )eff for muon neutrinos. In the channel π − → e− ν¯, the relative probability of producing an antineutrino with left helicity is enhanced if compared with the naive expectation (mν /2Eν )2 .

1. – Introduction After the confirmation that neutrinos have non-null masses and non-trivial mixing among the various types, the knowledge of the absolute scale of neutrino masses is one of the most urgent questions in neutrino physics. In recent times, the greatest advances in the understanding of neutrino properties were boosted by neutrino oscillation experiments which are only capable of accessing the two mass-squared differences and, in principle, three mixing angles and one Dirac CP -violating phase of the Maki-NakagawaSakata (MNS) leptonic mixing matrix. Too large masses for the light active neutrinos may alter significantly the recent cosmological history of the Universe. Indeed, the most stringent bounds for the value of c Societ`  a Italiana di Fisica

443

444

C. C. Nishi

the sum of neutrino masses come from Cosmology [1]: 

(1)

mν < 0.17 eV.

ν

Despite of the stringent bound (1) coming from cosmological analyses, terrestrial direct search experiments establish much looser bounds [2]: (2)

mνe ≤ 2 eV,

mνμ ≤ 190 keV,

mντ ≤ 18.2 MeV.

These bounds are based on ingeniously planned experiments [3], but their intrinsic difficulties rely on the fact that they should probe, essentially, the kinematical effects of tiny neutrino masses. Nevertheless, it is always desirable to have a direct measurement of neutrino masses because cosmological bounds may be quite model dependent. For the electron neutrino, there are ongoing experiments planning to reduce the respective bound to 0.2 eV [4]. The main goal of this note is to investigate the possibility of accessing the absolute neutrino mass scale through one of the most natural consequences of massive fermions, i.e., the dissociation of chirality and helicity. Consider the pion decay π − → μ− ν¯μ . Since the pion is a spin-zero particle, in its rest frame, the decaying states should have the following form from angular momentum conservation: (3)

←

→

→

←

|π → |μ :←|¯ ν :→ + δ|μ :←|¯ ν :→,

where the arrows represent the momentum direction (longer arrow) and the spin direction (shorter arrow). The normalization of the state is arbitrary and the coefficient δ is of the order of mν /Eν , which will be calculated in sect. 2. Thus, by measuring the wrong helicity contribution of the charged lepton, it is possible to have access to the neutrino mass. Such possibility was already suggested in ref. [5] but we intend here a focused reanalysis of the possibility considering the present experimental bounds. Further analyses such as the precision in the polarization measurement necessary to extract the wrong helicity can be found in ref. [6]. The possibility to constrain scalar/pseudoscalar interactions in two-Higgs-doublet models is also investigated in the same reference. It is interesting to notice that 50 years have passed since the first measurement of the helicity of the electron neutrino [7]. At that time the primary concern was to confirm the V -A theory of weak interactions. Nowadays, we can try to invert their roles to obtain new information about the neutrinos from the well-established weak interaction part of the Standard Model (SM). 2. – Pion decay − Pion decay π − → l√ ¯j can be effectively described by the four-point Fermi interaction i ν Lagrangian, LCC = 2 2GF ¯li γ μ LUij νj Jμ + h.c., where L = 12 (1 − γ5 ), {Uij } denotes the MNS matrix while Jμ = Vud u ¯L γμ dL for pion decay.

445

Absolute neutrino mass from helicity measurements

The amplitude for π(p) → li (q)νj (k), i, j = 1, 2, gives ¯li (q) pLUij vνj (k), −iM(π → li ν¯j ) = 2GF Fπ Vud u

(4)

√ by using 0|¯ uγ5 γμ d|π −  = ipμ 2Fπ , where Fπ ≈ 92 MeV is the pion decay constant. Let ˜ ij = u us denote the spinor-dependent amplitude as M ¯li (q) pLUij vνj (k). The amplitude squared summed over all spins yields (5)



˜ ij |2 = 4(p · qi )(p · kj )−2p2 (qi · kj ) = Mi2 (Mπ2 − Mi2 )+ m2j (Mπ2 + 2Mi2 − m2j ). |M

spins

We can calculate the amplitude squared, summed over the neutrino spin, but depenˆ of the charged lepton in its rest frame dent on the polarization n (6)

Pij (ni ) ≡



˜ ij |2 = M 2 [qi · kj + Mi (kj · ni )]+2M 2 m2 + m2 [qi · kj − Mi (kj · ni )], |M i i j j

νj spin

  ˆ )ˆ ˆ = hi q ˆ , we − 1 (ˆ n·q q . For the particular directions n single out the positive (hi = 1) and negative (hi = −1) helicity for the charged lepton. For the pion at rest we obtain

where nμi =

(7)



q·ˆ n ˆ Mi , n



+

Eli Mi

Pij (hi = 1) = Mi2 (Mπ2 − Mi2 ) + O(m2j ),

Pij (hi = −1) = m2j

Mπ4 + O(m4j ). Mπ2 − Mi2

Considering numerical values for Mi = Mμ and Mi = Me , respectively, the ratio between the squared amplitudes for left-handed (h = −1) and right-handed (h = 1) helicities is (8)

Rμj =

m2j × 4.92 × 10−6 , (100 keV)2

Rej =

m2j × 3.83 × 10−6 . (1 eV)2

Considering the actual direct bounds for the neutrino masses in eq. (2), we need a precision of 10−6 in the helicity measurement to reach those bounds either in the case of muons or electrons. Therefore, the coefficient δ in eq. (3) has exactly the modulus (9)

If we rewrite |δμj | =

|δμj |2 = Rμj = m j Mπ 2Eνj Mμ ,

where Eνj =

m2j Mπ4 . Mμ2 (Mπ2 − Mμ2 )2 2 Mπ2 −Mμ 2Mπ

+O(m2j ), we see that |δμj | is modified

π by the factor M Mμ when compared to the naive estimate mν /2Eν . We can also conclude that for the channel π → e¯ ν the real factor is enhanced considerably (∼ 274×).

446

C. C. Nishi

Considering the leptonic mixing, the measurement of the wrong helicity for muons probes (10)

|M(π → μ¯ ν : hμ = −1)|2 = |C|2

Mπ4 (m2 )eff , Mπ2 − Mμ2 νμ

 where C ≡ 2GF Fπ Vud and (m2νμ )eff ≡ j |Uμj |2 m2j , is an effective mass for the muon neutrino, analogous to m2β [3] inferred from the tritium beta decay experiments for the electron neutrino. In fact, m2β can be extracted from π − → e− ν¯ by measuring the electron with negative helicity. REFERENCES [1] Seljak U., Slosar A. and McDonald P., J. Cosmol. Astropart. Phys., 0610 (2006) 014 (arXiv:astro-ph/0604335). [2] Eidelman S. et al. (Particle Data Group), Phys. Lett. B, 592 (2004) 1. [3] Giunti C., Acta Phys. Polonica B, 36 (2005) 3215 (arXiv:hep-ph/0511131). [4] Bornschein L. (KATRIN Collaboration), KATRIN: Direct measurement of neutrino masses in the sub-eV region, in Proceedings of 23rd International Conference on Physics in Collision (PIC 2003), Zeuthen, Germany, 26-28 Jun 2003, pp FRAP14 (arXiv:hepex/0309007). [5] Shrock R. E., Phys. Lett. B, 96 (1980) 159; Phys. Rev. D, 24 (1981) 1232. [6] Nishi C. C., Mod. Phys. Lett. A, 24 (2009) 219. [7] Goldhaber M., Grodzins L. and Sunyar A. W., Phys. Rev., 109 (1958) 1015.

DOI 10.3254/978-1-60750-038-4-447

First year of Borexino data acquisition: Background analysis P. Risso(∗ ) on behalf of the Borexino Collaboration Dipartimento di Fisica, Universit` a di Genova and INFN, Sezione di Genova - Italy

Summary. — Borexino is a large-scale real-time detector for sub-MeV solarneutrino spectroscopy. It is located underground at the Laboratori Nazionali del Gran Sasso, LNGS. Its main application is the flux measurement of mono-energetic (862 keV) 7 Be neutrinos as well as pp and CNO solar-neutrino fluxes. The detection mechanism is neutrino-electron elastic scattering, ES, in ultra-pure organic liquid scintillator. Internal, external, and cosmogenic backgrounds are under detailed analysis by means of energy and position reconstruction with techniques like shape analysis of scintillation light and fast-coincidences tagging.

1. – Introduction Borexino has been built by a collaboration of 80 physicists of 14 different Institutions, coming from Italy, France, Germany, Poland, Russia and USA. The idea of studying realtime solar neutrinos, with energies below 2 MeV was born in 1990. First feasibility studies indicated a required radio-purity of materials of the order of 10−16 g/g to be sensitive at 2 MeV thresholds. After some years spent in R&D of purification procedures, the collaboration built at LNGS a prototype detector, named Counting Test Facility (CTF). This detector showed that in principle extreme radio-purity levels were achievable. In 1996 the Borexino project was approved. 2. – Physics of Borexino In spite of the extensive investigation carried on by experiments like SuperKamiokande or SNO, many issues concerning solar neutrinos still remain unsolved. Rel(∗ ) E-mail: [email protected] c Societ`  a Italiana di Fisica

447

448

P. Risso on behalf of the Borexino Collaboration

ative rates at which various nuclear reactions in the Sun produce neutrinos are in many cases theoretically uncertain at a level of 10% or greater. Moreover, neutrinos with E < 2 MeV, that constitute ∼ 99% of the solar ν flux and are so critical for neutrino oscillations, have been observed only in radiochemical experiments, not in a real time data taking experiments. Low-energy neutrinos have an oscillation wavelength much smaller than the Sun core, so their observation probability is of the order of 57%. For the high-energy ones there are no oscillation phenomena, as MSW effect explains, and their probability is of the order of 31%. The neutrino fluxes dominating in the transition region around 2 MeV, between vacuum oscillations and MSW effects, are coming from 7 Be and pep. Until May 2007, when Borexino started taking data, no experiment had been able to inspect this region and reduce these uncertainties. 3. – Borexino detector The main challenge [1] is the suppression of the background derived not only from the surrounding environment but also from the detector materials and the scintillator itself. Its design is based on a gradual shielding, with inner shells of increasing radio-purity. In fig. 1 a schematic view of the detector is shown. The detection mechanism is based on the elastic scattering of ν on electrons in the scintillator. The induced photons carry energy information but lose the directional one. For instance, mono-energetic 7 Be ν’s of 0.862 MeV produce a Compton-like edge with recoil electrons of 0.665 MeV. The liquid scintillator adopted is PC/PPO because of elevate scintillation yield (104 photons/MeV), high transparency (mean free path is of the order of 10 m) and fast decay time (3 ns). The latter is critical since it allows the distinction between scintillation caused by α vs. β/γ events. The inner vessel (IV) is made of a 125 μm thick nylon layer, of 4.2 m radius, chosen for its good optical clearance, mechanical strength and high radio-purity. It separates the scintillating liquid from the buffer liquid, a mixture of PC and DMP, a light quencher. The presence of another nylon vessel in the buffer region, placed at a radius of 6 m, acts as former barrier, to prevent inner diffusion of radioactive contaminants coming from Stainless Steel Sphere (SSS), and the PMTs. The total mass of the liquid scintillator inside the IV is of the order of 280 ton. To increase rejection from natural radioactivity, we chose to analyse data spatially reconstructed in an inner sphere of 3 m of radius, called Fiducial Volume, FV. Its mass is equal to 100 ton. 2212 PMTs are uniformly distributed over the inner surface of the sphere, 384 of them are installed without a light concentrator. Gran Sasso rock leads to a 106 reduction of muon rate, but still high-energy μ can reach the detector, with a daily rate of 4 × 103 . The sphere is surrounded by a water tank that acts as Cherenkov detector, with 208 PMTs, same model as in the SSS, installed. Combining information coming from this outer muon detector and from the inner one, we reach a muon rejection efficiency bigger than 99.5%.

First year of Borexino data acquisition: Background analysis

Fig. 1

449

Fig. 2

Fig. 1. – Borexino view. Fig. 2. – Energy spectrum of data.

4. – Background components The 7 Be ν event rate in the 100 ton FV is expected to be of the order of 50 events/day. Since scintillation phenomena do not permit to distinguish between neutrino signal and background, we evaluated the most important radio contaminants with detailed studies a priori via CTF. The background levels measured in the detector are in general better than expected. 232 Th family background, investigated by the 212 Bi-212 Po (τ = 433 ns) sequence, assuming a secular equilibrium and excluding nylon IV surface-emanated 220 Rn events, indicates an intrinsic scintillator contamination of (6.8 ± 1.5)10−18 g/g. 238 U family contaminations have been investigated by detecting the coincidence 214 214 Bi- Po (τ = 236 μs). Restricting the analysis to the FV region, minimizing the pollution from IV emanation and assuming secular equilibrium, the contamination is (1.6 ± 0.3)10−17 g/g. 222 Rn belongs to this radioactive chain but it is also a common gas, present also in LNGS cavern. It is impossible, up to now, to distinguish its contribution to pollution from a complete 238 U chain, so results are kept together. Since now 210 Po is decaying matching the half-life of about 200 days; these results support the hypothesis that the mother nuclide 210 Bi contamination should be very small. It is difficult to estimate its concentration, so its value is kept like a free parameter of the fit of the 7 Be spectrum. 85 Kr, an obstacle for low-energy solar ν spectroscopy, is studied directly via 85 Kr85 mRb-85 Rb, (τ = 1.46 ns, BR = 0.43%). Our best estimation for the total activity of 85 Kr is (29 ± 14) counts/(day·100 ton). 14 C (β − Q = 156 keV) is present in the detector coming from the organic scintillator solvent. Its decay is useful to study detector energy response and to calibrate spatial reconstruction, however it limits the detection of neutrinos with energies less than 200 keV. 11 C (β + Q = 1.98 MeV) is created by residual cosmic rays under Gran Sasso Mountain

450

P. Risso on behalf of the Borexino Collaboration

Fig. 3

Fig. 4 210

Po.

Fig. 4. – Energy spectrum without

210

Fig. 3. – Energy spectrum with

Po.

and is identified with the three-fold coincidence with the muon parent, the associated neutron emission/capture and the β + decay. 5. – Data analysis and results Now we show the energy spectrum of data [2]. The X-axis unit is Borexino charge, the number of photo-electrons that constitute a scintillation event. To fit the spectrum in the energy window of 2 MeV, the following restrictions were applied: removal of all muons and all events within a time window of 2 ms after; inclusion of events belonging to a unique cluster, to avoid pile-up; removal of all events coming from 222 Rn daughters; events must be reconstructed within the FV to reject external gamma background and the z-coordinate satisfy |z| < 1.7 m, to remove background near the poles of the IV. Figure 2 shows the effect of the above criteria starting from the total raw spectrum, “no cuts” line. The curve “after μ cut” shows the subtraction of the muons and their correlated activities, while the last one shows the effects of FV cuts and of removal of 238 U/222 Rn daughters. The shape distribution is in remarkable agreement with what we can expect from the most important signal and unavoidable background: 7 Be ν, 14 C, 11 C. Below 100 p.e., or 200 keV, the spectrum is dominated by 14 C intrinsic to the scintillator, and the peak at 200 p.e. is due to the 210 Po. Prominent features of the spectrum are the Compton-like edge due to 7 Be solar neutrinos (300–350 p.e.) and the spectrum of 11 C. 85 Kr component was constrained in the region between the 14 C end-point and the 210 Po peak. The submitted analysis of 192 days of lifetime is focused on the 7 Be region. The shoulder in the spectrum between 560 and 800 keV was fitted considering the expected

First year of Borexino data acquisition: Background analysis

451

Compton-like shape of the electron-recoil spectrum. The pep neutrino components were fixed to the expected SSM/LMA value and the contributions from CNO solar neutrino and from 210 Bi were taken as a single free parameter in the fit. No other background component was included in the final fit because they were found negligible (fig. 3). A second fit was performed with the α statistical subtraction, via the α/β discrimination based upon the Gatti parameter (reference in parentheses) (fig. 4). Our results, for the solar neutrinos from the electron-capture decay of 7 Be neutrinos, is (49 ± 3 stat ± 4 sys) counts/(day·100 ton), outcome fully compatible with MSW-LMA scenario. The statistical error is determined by the χ2 profile, the systematic errors are mostly dominated by the uncertainty in the FV mass definition as by software cut and the uncertainty in the detector response function. 6. – Future perspectives To improve the measure, Borexino goal is to reduce the global systematic uncertainty to values below ±5% (1σ), performing a deployment of known radiation sources, inside the inner vessel, to calibrate position reconstruction algorithms and to study the in-depth detector energy response function. In addition to the 7 Be flux, we entrust our ability to measure also the pep, CNO and 8 B fluxes: the main problem for the study of these two fluxes is the production, of μ-induced 11 C nuclides within the scintillator. Also pp flux could be studied because the 14 C spectrum ends well below 200 keV. Another subject concerns the search for anti-ν from the Sun, Earth (geoneutrinos) and nuclear reactors. We expect 7–17 events per year for geoneutrinos, depending on the Earth models. The background due to nuclear reactors is particularly favourable at Gran Sasso, since they are absent in Italy. Borexino is also a good observatory for a Supernova explosion in our Galaxy. It is almost unique for measuring ν-p elastic scattering. Due to quenching, the p is pushed toward the low energies and, to detect it, a very low threshold is needed. REFERENCES [1] Borexino Collaboration, The Borexino detector at the Laboratori Nazionali del Gran Sasso, arXiv:0806.2400 [physics.ins-det]. [2] Borexino Collaboration, New results on solar neutrino fluxes from 192 days of Borexino data, arXiv:0805.3843 [astro-ph].

This page intentionally left blank

International School of Physics “Enrico Fermi” Villa Monastero, Varenna Course CLXX 17–27 June 2008

“Measurements of Neutrino Mass” Directors Fernando FERRONI Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-49914613 Fax: ++39-06-4957697 [email protected] Francesco VISSANI Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-437-205 Fax: ++39-0862-437-570 [email protected]

Scientific Secretary Chiara BROFFERIO Dipartimento di Fisica Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-6448-2426 Fax: ++39-02-6448-2463 [email protected] c Societ`  a Italiana di Fisica

Lecturers Flavio GATTI INFN, Sezione di Genova e Dipartimento di Fisica Universit` a di Genova Via Dodecaneso 33 16146 Genova Italy Tel.: ++39-010-3536280/461 Fax: ++39-010-3536499 [email protected] Andrea Ernesto Guido GIULIANI INFN, Sezione di Milano-Bicocca e Dipartimento di Fisica e Matematica Universit` a dell’Insubria Via Valleggio 11 22100 Como Italy Tel.: ++39-031-238-6217 Fax: ++39-031-238-6119 [email protected] Sergio PASTOR IFIC-Instituto de Fisica Corpuscular Edificio Institutos de Investigaci´ on Apartado de Correos 22085 E-46071 Valencia Spain Tel. ++34-963543510 [email protected] 453

454

´ Goran SENJANOVIC ICTP-The International Centre for Theoretical Physics High Energy, Cosmology and Astroparticle Physics Section Strada Costiera 11, Miramare 34014 Trieste Italy Tel. ++39-040-2240303 Fax ++39-040-2240304 [email protected] Alessandro STRUMIA Dipartimento di Fisica “E. Fermi” Universit` a di Pisa Largo B. Pontecorvo 3 56127 Pisa Italy Tel.: ++39-050-2214905 Fax: ++39-050-2214887 [email protected] Petr VOGEL Mail Stop 106-38 Kellogg Radiation Laboratory and Physics Department California Institute of Technology Caltech 1200 E. California Blvd Pasadena, CA 91125 USA Tel.: ++1-626-395-4303 Fax: ++1-626-564-8708 [email protected] Christian WEINHEIMER Institut f¨ ur Kernphysik Westf¨alischen Wilhelms-Universit¨ at M¨ unster Wilhelm-Klemm-Strasse 9 D-48149 M¨ unster Germany Tel: ++49-251-833-4970 Fax ++49-251-8334962 [email protected]

Elenco dei partecipanti

Seminar Speakers Alessandro BETTINI INFN, Sezione di Padova e Dipartimento di Fisica “G. Galilei” Universit` a di Padova Via F. Marzolo 8 35131 Padova Italy Tel.: ++39-049-8277090 Fax: ++39-049-8277102 [email protected] Paolo DE BERNARDIS Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-49914271 Fax: ++39-06-4957697 [email protected] Ettore FIORINI Dipartimento di Fisica “G. Occhialini” Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-64482424/2340 Fax: ++39-02-64482463 [email protected] Dieter FREKERS Institut f¨ ur Kernphysik Westf¨alischen Wilhelms-Universit¨ at M¨ unster Wilhelm-Klemm Strasse 9 D-48149 M¨ unster Germany Tel.: ++49-251-833-4996 Fax: ++49-251-833-4962 [email protected]

455

Elenco dei partecipanti Alfredo POVES Departamento de F´ısica Te´orica Universidad Aut´ onoma de Madrid Carretera Colmenar Viejo km. 15,500 E-28049 Madrid Spain Tel.: ++34-91-497-4883 Fax: ++34-91-497-3936 [email protected] Antonio RIOTTO INFN, Sezione di Padova e Dipartimento di Fisica “G. Galilei” Universit` a di Padova Via F. Marzolo 8 35131 Padova Italy Tel.: ++39-049-8277256 Fax: ++39-049-8277102 [email protected] Alexei SMIRNOV ICTP-The International Centre for Theoretical Physics High Energy, Cosmology and Astroparticle Physics Section Strada Costiera 11, Miramare 34014 Trieste Italy Tel.: ++39-040-2240413 Fax: ++39-040-2240304 [email protected] [email protected]

Students Mario Andres ACERO ORTEGA Dipartimento di Fisica Universit` a di Torino Via Giuria 1 10125 Torino Italy Tel.: ++39-011-6707066 [email protected]

Maddalena ANTONELLO Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-437517 Fax: ++39-0862-437-570 [email protected]

Daniela BAGLIANI INFN, Sezione di Genova e Dipartimento di Fisica Universit` a di Genova Via Dodecaneso 33 16146 Genova Italy Tel.: ++39-010-3536333 Fax: ++39-010-3536499 [email protected]

Fabio BELLINI Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-49914338 Fax: ++39-06-4463158 [email protected]

Adam BRYANT Lawrence Berkeley National Laboratory 1 Cyclotron Rd Mail Stop 50R5008 Berkeley, CA 94720-8185 USA Tel.: ++1-510-4865017 Fax: ++1 510 4866738 adam [email protected]

456

Fabio CAPPELLA Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-72594825 [email protected]

Enrico CARRARA Dipartimento di Fisica “G. Galilei” Universit` a di Padova Via F. Marzolo 8 35131 Padova Italy [email protected]

Marco Andrea CARRETTONI Dipartimento di Fisica Universit` a di Milano-Bicocca e INFN, Sezione di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-6448-2463 [email protected]

Matteo DE GERONE INFN, Sezione di Genova e Dipartimento di Fisica Universit` a di Genova Via Dodecaneso 33 16146 Genova Italy Tel.: ++39-010-3536333 Fax: ++39-010-3536499 [email protected]

Elenco dei partecipanti Sergio DI DOMIZIO INFN, Sezione di Genova e Dipartimento di Fisica Universit` a di Genova Via Dodecaneso 33 16146 Genova Italy Tel.: ++39-010-3536468 Fax: ++39-010-314218 [email protected]

Donato DI FERDINANDO INFN, Sezione di Bologna Viale Berti Pichat 6/2 40127 Bologna Italy Tel.: ++39-051-2095230 Fax: ++39-051-22095269 [email protected]

Assunta DI VACRI Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-437532 Fax: ++39-0862-437-570 [email protected]

Michelle DOLINSKI Department of Physics University of California 94720 Berkeley, CA USA Tel.: ++1-510-2823523 Fax: ++1-510-4866738 [email protected]

457

Elenco dei partecipanti Elena FERRI Dipartimento di Fisica Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-64482463 [email protected]

Eike FRANK Laboratorium fur Hochenergiephysik Universit¨ at Bern Sidlerstrasse 5 3012 Bern Switzerland Tel.: ++41-31-6314064 Fax: ++41-31-6314487 [email protected]

Ivan GNESI Dipartimento di Fisica Universit` a di Torino Via Giuria 1 10125 Torino Italy Tel.: ++39-011-6707049 Fax: ++39-011-6707269 [email protected]

Pawin ITTISAMAI ICTP-The International Centre for Theoretical Physics High Energy, Cosmology and Astroparticle Physics Section Strada Costiera 11, Miramare 34014 Trieste Italy [email protected]

Andrea GIACHERO Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-437318 Fax: ++39-0862-437570 [email protected]

Laura KOGLER Lawrence Berkeley National Laboratory 1 Cyclotron Rd Mail Stop 50B5239 94720 Berkeley, CA USA Tel.: ++1-510-4865017 Fax: ++1-510-4866738 [email protected]

Luca GIRONI Dipartimento di Fisica Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-64482463 [email protected]

Conradin LANGBRANDTNER MPI f¨ ur Kernphysik Saupfercheckweg 1 69117 Heidelberg Germany Tel.: ++49-6221-516472 Fax: ++49-6221-516802 [email protected]

458

Jing LIU MPI M¨ unchen Room 114, Fohringer Ring 6 80805 Munchen Germany Tel.: ++49-89-32354415 [email protected]

Ana Amelia MACHADO Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-4203 Fax: ++39-0862-437570 [email protected]

Elenco dei partecipanti Celso Chikahiro NISHI Departamento de Raios C´osmicos e Cronologia Instituto de Fisica Gleb Watagin Universitdade Estadual de Campinas 13083-970 Campinas, SP Brazil Tel.: ++55-19-3521-5270 [email protected] Filippo ORIO Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-49914338 Fax: ++39-06-4463158 [email protected]

Cecilia Giovanna MAIANO Dipartimento di Fisica Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-64482435 Fax: ++39-02-64482463 [email protected]

Giulia PAGLIAROLI Istituto Nazionale di Fisica Nucleare Laboratori Nazionali del Gran Sasso Strada Statale 17/bis, km. 18+910 67010 Assergi (AQ) Italy Tel.: ++39-0862-437499 Fax: ++39-0862-437570 [email protected]

Miha NEMEVSEK Jozef Stefan Institute Jamova cesta 39 1000 Ljubljana Slovenia Tel.: ++386-1-4773334 Fax: ++386-1-4773900 [email protected]

Luca Maria PATTAVINA Dipartimento di Fisica Universit` a di Milano-Bicocca Piazza della Scienza 3 20126 Milano Italy Tel.: ++39-02-64482435 Fax: ++39-02-64482463 [email protected]

459

Elenco dei partecipanti Marisa PEDRETTI INFN, Sezione di Milano-Bicocca e Dipartimento di Fisica e Matematica Universit` a dell’Insubria Via Valleggio 11 22100 Como Italy Tel.: ++39-031-2386233 Fax: ++39-031-2386209 [email protected]

Paolo RISSO INFN, Sezione di Genova e Dipartimento di Fisica Universit` a di Genova Via Dodecaneso 33 16146 Genova Italy [email protected]

Vladimir TELLO ICTP-The International Centre for Theoretical Physics High Energy, Cosmology and Astroparticle Physics Section Strada Costiera 11, Mirama¡re 34014 Trieste Italy [email protected] Marco VIGNATI Dipartimento di Fisica “G. Marconi” Universit` a di Roma “La Sapienza” P.le Aldo Moro 2 00185 Roma Italy Tel.: ++39-06-49914338 Fax: ++39-06-4463158 [email protected]

Observers Chiara SALVIONI INFN, Sezione di Milano-Bicocca e Dipartimento di Fisica e Matematica Universit` a dell’Insubria Via Valleggio 11 22100 Como Italy Tel.: ++39-031-2386245 Fax: ++39-031-2386209 [email protected]

Gabriele SIRRI INFN, Sezione di Bologna Viale Berti Pichat 6/2 40127 Bologna Italy Tel.: ++39-051-2095228 Fax: ++39-051-2095269 [email protected]

Philip M. GORE 629 Country Club Lane 37205 Nashville, TE USA Tel.: ++1-615-3566470 [email protected] Elisabeth F. JONES 629 Country Club Lane 37205 Nashville, TE USA Tel.: ++1-615-3568848 [email protected] Xavier-Francois NAVICK Centre d’Etudes de Saclay CEA/IRFU/SEDI bat534 91191 Gif sur Yvette France Tel.: ++33-16908-9442 Fax: ++33-16908-024 [email protected]

This page intentionally left blank

PROCEEDINGS OF THE INTERNATIONAL SCHOOL OF PHYSICS “ENRICO FERMI”

Course I (1953) Questioni relative alla rivelazione delle particelle elementari, con particolare riguardo alla radiazione cosmica edited by G. Puppi Course II (1954) Questioni relative alla rivelazione delle particelle elementari, e alle loro interazioni con particolare riguardo alle particelle artificialmente prodotte ed accelerate edited by G. Puppi Course III (1955) Questioni di struttura nucleare e dei processi nucleari alle basse energie edited by C. Salvetti Course IV (1956) Propriet` a magnetiche della materia edited by L. Giulotto Course V (1957) Fisica dello stato solido edited by F. Fumi Course VI (1958) Fisica del plasma e relative applicazioni astrofisiche edited by G. Righini Course VII (1958) Teoria della informazione edited by E. R. Caianiello

Course XIII (1959) Physics of Plasma: Experiments and Techniques ´n edited by H. Alfve Course XIV (1960) Ergodic Theories edited by P. Caldirola Course XV (1960) Nuclear Spectroscopy edited by G. Racah Course XVI (1960) Physicomathematical Aspects of Biology edited by N. Rashevsky Course XVII (1960) Topics of Radiofrequency Spectroscopy edited by A. Gozzini Course XVIII (1960) Physics of Solids (Radiation Damage in Solids) edited by D. S. Billington Course XIX (1961) Cosmic Rays, Solar Particles and Space Research edited by B. Peters Course XX (1961) Evidence for Gravitational Theories edited by C. Møller

Course VIII (1958) Problemi matematici della teoria quantistica delle particelle e dei campi edited by A. Borsellino

Course XXI (1961) Liquid Helium edited by G. Careri

Course IX (1958) Fisica dei pioni edited by B. Touschek

Course XXII (1961) Semiconductors edited by R. A. Smith

Course X (1959) Thermodynamics of Irreversible Processes edited by S. R. de Groot

Course XXIII (1961) Nuclear Physics edited by V. F. Weisskopf

Course XI (1959) Weak Interactions edited by L. A. Radicati

Course XXIV (1962) Space Exploration and the Solar System edited by B. Rossi

Course XII (1959) Solar Radioastronomy edited by G. Righini

Course XXV (1962) Advanced Plasma Theory edited by M. N. Rosenbluth

Course XXVI (1962) Selected Topics on Elementary Particle Physics edited by M. Conversi Course XXVII (1962) Dispersion and Absorption of Sound by Molecular Processes edited by D. Sette Course XXVIII (1962) Star Evolution edited by L. Gratton Course XXIX (1963) Dispersion Relations and their Connection with Casuality edited by E. P. Wigner Course XXX (1963) Radiation Dosimetry edited by F. W. Spiers and G. W. Reed Course XXXI (1963) Quantum Electronics and Coherent Light edited by C. H. Townes and P. A. Miles Course XXXII (1964) Weak Interactions and High-Energy Neutrino Physics edited by T. D. Lee Course XXXIII (1964) Strong Interactions edited by L. W. Alvarez Course XXXIV (1965) The Optical Properties of Solids edited by J. Tauc Course XXXV (1965) High-Energy Astrophysics edited by L. Gratton

Course XLI (1967) Selected Topics in Particle Physics edited by J. Steinberger Course XLII (1967) Quantum Optics edited by R. J. Glauber Course XLIII (1968) Processing of Optical Data by Organisms and by Machines edited by W. Reichardt Course XLIV (1968) Molecular Beams and Reaction Kinetics edited by Ch. Schlier Course XLV (1968) Local Quantum Theory edited by R. Jost Course XLVI (1969) Physics with Intersecting Storage Rings edited by B. Touschek Course XLVII (1969) General Relativity and Cosmology edited by R. K. Sachs Course XLVIII (1969) Physics of High Energy Density edited by P. Caldirola and H. Knoepfel Course IL (1970) Foundations of Quantum Mechanics edited by B. d’Espagnat Course L (1970) Mantle and Core in Planetary Physics edited by J. Coulomb and M. Caputo Course LI (1970) Critical Phenomena edited by M. S. Green

Course XXXVI (1965) Many-body Description of Nuclear Structure and Reactions edited by C. L. Bloch

Course LII (1971) Atomic Structure and Properties of Solids edited by E. Burstein

Course XXXVII (1966) Theory of Magnetism in Transition Metals edited by W. Marshall

Course LIII (1971) Developments and Borderlines of Nuclear Physics edited by H. Morinaga

Course XXXVIII (1966) Interaction of High-Energy Particles with Nuclei edited by T. E. O. Ericson

Course LIV (1971) Developments in High-Energy Physics edited by R. R. Gatto

Course XXXIX (1966) Plasma Astrophysics edited by P. A. Sturrock

Course LV (1972) Lattice Dynamics and Forces edited by S. Califano

Course XL (1967) Nuclear Structure and Nuclear Reactions edited by M. Jean and R. A. Ricci

Course LVI (1972) Experimental Gravitation edited by B. Bertotti

Intermolecular

Course LVII (1972) History of 20th Century Physics edited by C. Weiner

Course LXXII (1977) Problems in the Foundations of Physics edited by G. Toraldo di Francia

Course LVIII (1973) Dynamics Aspects of Surface Physics edited by F. O. Goodman

Course LXXIII (1978) Early Solar System Processes and the Present Solar System edited by D. Lal

Course LIX (1973) Local Properties at Phase Transitions ¨ller and A. Rigamonti edited by K. A. Mu Course LX (1973) C*-Algebras and their Applications to Statistical Mechanics and Quantum Field Theory edited by D. Kastler

Course LXXIV (1978) Development of High-Power Lasers and their Applications edited by C. Pellegrini Course LXXV (1978) Intermolecular Spectroscopy and Dynamical Properties of Dense Systems edited by J. Van Kranendonk

Course LXI (1974) Atomic Structure and Mechanical Properties of Metals edited by G. Caglioti

Course LXXVI (1979) Medical Physics edited by J. R. Greening

Course LXII (1974) Nuclear Spectroscopy and Nuclear Reactions with Heavy Ions edited by H. Faraggi and R. A. Ricci

Course LXXVII (1979) Nuclear Structure and Heavy-Ion Collisions edited by R. A. Broglia, R. A. Ricci and C. H. Dasso

Course LXIII (1974) New Directions in Physical Acoustics edited by D. Sette

Course LXXVIII (1979) Physics of the Earth’s Interior edited by A. M. Dziewonski and E. Boschi

Course LXIV (1975) Nonlinear Spectroscopy edited by N. Bloembergen

Course LXXIX (1980) From Nuclei to Particles edited by A. Molinari

Course LXV (1975) Physics and Astrophysics of Neutron Stars and Black Hole edited by R. Giacconi and R. Ruffini

Course LXXX (1980) Topics in Ocean Physics edited by A. R. Osborne and P. Malanotte Rizzoli

Course LXVI (1975) Health and Medical Physics edited by J. Baarli

Course LXXXI (1980) Theory of Fundamental Interactions edited by G. Costa and R. R. Gatto

Course LXVII (1976) Isolated Gravitating Systems in General Relativity edited by J. Ehlers

Course LXXXII (1981) Mechanical and Thermal Behaviour of Metallic Materials edited by G. Caglioti and A. Ferro Milone

Course LXVIII (1976) Metrology and Fundamental Constants edited by A. Ferro Milone, P. Giacomo and S. Leschiutta

Course LXXXIII (1981) Positrons in Solids edited by W. Brandt and A. Dupasquier

Course LXIX (1976) Elementary Modes of Excitation in Nuclei edited by A. Bohr and R. A. Broglia

Course LXXXIV (1981) Data Acquisition in High-Energy Physics edited by G. Bologna and M. Vincelli

Course LXX (1977) Physics of Magnetic Garnets edited by A. Paoletti

Course LXXXV (1982) Earthquakes: Observation, Theory and Interpretation edited by H. Kanamori and E. Boschi

Course LXXI (1977) Weak Interactions edited by M. Baldo Ceolin

Course LXXXVI (1982) Gamow Cosmology edited by F. Melchiorri and R. Ruffini

Course LXXXVII (1982) Nuclear Structure and Heavy-Ion Dynamics edited by L. Moretto and R. A. Ricci

Course CII (1986) Accelerated Life Testing and Experts’ Opinions in Reliability edited by C. A. Clarotti and D. V. Lindley

Course LXXXVIII (1983) Turbulence and Predictability in Geophysical Fluid Dynamics and Climate Dynamics edited by M. Ghil, R. Benzi and G. Parisi

Course CIII (1987) Trends in Nuclear Physics edited by P. Kienle, R. A. Ricci and A. Rubbino

Course LXXXIX (1983) Highlights of Condensed Matter Theory edited by F. Bassani, F. Fumi and M. P. Tosi

Course CIV (1987) Frontiers and Borderlines in ManyParticle Physics edited by R. A. Broglia and J. R. Schrieffer

Course XC (1983) Physics of Amphiphiles: Micelles, Vesicles and Microemulsions edited by V. Degiorgio and M. Corti Course XCI (1984) From Nuclei to Stars edited by A. Molinari and R. A. Ricci Course XCII (1984) Elementary Particles edited by N. Cabibbo Course XCIII (1984) Frontiers in Physical Acoustics edited by D. Sette Course XCIV (1984) Theory of Reliability edited by A. Serra and R. E. Barlow Course XCV (1985) Solar-Terrestrial Relationship and the Earth Environment in the Last Millennia edited by G. Cini Castagnoli

Course CV (1987) Confrontation between Theories and Observations in Cosmology: Present Status and Future Programmes edited by J. Audouze and F. Melchiorri Course CVI (1988) Current Trends in the Physics of Materials edited by G. F. Chiarotti, F. Fumi and M. Tosi Course CVII (1988) The Chemical Physics of Atomic and Molecular Clusters edited by G. Scoles Course CVIII (1988) Photoemission and Absorption Spectroscopy of Solids and Interfaces with Synchrotron Radiation edited by M. Campagna and R. Rosei

Course XCVI (1985) Excited-State Spectroscopy in Solids edited by U. M. Grassano and N. Terzi

Course CIX (1988) Nonlinear Topics in Ocean Physics edited by A. R. Osborne

Course XCVII (1985) Molecular-Dynamics Simulations of Statistical-Mechanical Systems edited by G. Ciccotti and W. G. Hoover

Course CX (1989) Metrology at the Frontiers of Physics and Technology edited by L. Crovini and T. J. Quinn

Course XCVIII (1985) The Evolution of Small Bodies in the Solar System ˇ Kresa `k edited by M. Fulchignoni and L.

Course CXI (1989) Solid-State Astrophysics edited by E. Bussoletti and G. Strazzulla

Course XCIX (1986) Synergetics and Dynamic Instabilities edited by G. Caglioti and H. Haken

Course CXII (1989) Nuclear Collisions from the Mean-Field into the Fragmentation Regime edited by C. Detraz and P. Kienle

Course C (1986) The Physics of NMR Spectroscopy in Biology and Medicine edited by B. Maraviglia

Course CXIII (1989) High-Pressure Equation of State: Theory and Applications edited by S. Eliezer and R. A. Ricci

Course CI (1986) Evolution of Interstellar Dust and Related Topics edited by A. Bonetti and J. M. Greenberg

Course CXIV (1990) Industrial and Technological Applications of Neutrons edited by M. Fontana and F. Rustichelli

Course CXV (1990) The Use of EOS for Studies of Atmospheric Physics edited by J. C. Gille and G. Visconti

Course CXXIX1 (1994) Observation, Prediction and Simulation of Phase Transitions in Complex Fluids edited by M. Baus, L. F. Rull and J. P. Ryckaert

Course CXVI (1990) Status and Perspectives of Nuclear Energy: Fission and Fusion edited by R. A. Ricci, C. Salvetti and E. Sindoni

Course CXXX (1995) Selected Topics in Nonperturbative QCD edited by A. Di Giacomo and D. Diakonov

Course CXVII (1991) Semiconductor Superlattices and Interfaces edited by A. Stella Course CXVIII (1991) Laser Manipulation of Atoms and Ions edited by E. Arimondo, W. D. Phillips and F. Strumia

Course CXXXI (1995) Coherent and Collective Interactions of Particles and Radiation Beams edited by A. Aspect, W. Barletta and R. Bonifacio Course CXXXII (1995) Dark Matter in the Universe edited by S. Bonometto and J. Primack

Course CXIX (1991) Quantum Chaos edited by G. Casati, I. Guarneri and U. Smilansky

Course CXXXIII (1996) Past and Present Variability of the SolarTerrestrial System: Measurement, Data Analysis and Theoretical Models edited by G. Cini Castagnoli and A. Provenzale

Course CXX (1992) Frontiers in Laser Spectroscopy ¨nsch and M. Inguscio edited by T. W. Ha

Course CXXXIV (1996) The Physics of Complex Systems edited by F. Mallamace and H. E. Stanley

Course CXXI (1992) Perspectives in Many-Particle Physics edited by R. A. Broglia, J. R. Schrieffer and P. F. Bortignon

Course CXXXV (1996) The Physics of Diamond edited by A. Paoletti and A. Tucciarone

Course CXXII (1992) Galaxy Formation edited by J. Silk and N. Vittorio

Course CXXXVI (1997) Models and Phenomenology for Conventional and High-Temperature Superconductivity edited by G. Iadonisi, J. R. Schrieffer and M. L. Chiofalo

Course CXXIII (1992) Nuclear Magnetic Double Resonsonance edited by B. Maraviglia Course CXXIV (1993) Diagnostic Tools in Atmospheric Physics edited by G. Fiocco and G. Visconti Course CXXV (1993) Positron Spectroscopy of Solids edited by A. Dupasquier and A. P. Mills jr. Course CXXVI (1993) Nonlinear Optical Materials: Principles and Applications edited by V. Degiorgio and C. Flytzanis Course CXXVII (1994) Quantum Groups and their Applications in Physics edited by L. Castellani and J. Wess Course CXXVIII (1994) Biomedical Applications of Synchrotron Radiation edited by E. Burattini and A. Balerna 1 This

Course CXXXVII (1997) Heavy Flavour Physics: a Probe of Nature’s Grand Design edited by I. Bigi and L. Moroni Course CXXXVIII (1997) Unfolding the Matter of Nuclei edited by A. Molinari and R. A. Ricci Course CXXXIX (1998) Magnetic Resonance and Brain Function: Approaches from Physics edited by B. Maraviglia Course CXL (1998) Bose-Einstein Condensation in Atomic Gases edited by M. Inguscio, S. Stringari and C. E. Wieman Course CXLI (1998) Silicon-Based Microphotonics: from Basics to Applications edited by O. Bisi, S. U. Campisano, L. Pavesi and F. Priolo

course belongs to the NATO ASI Series C, Vol. 460 (Kluwer Academic Publishers).

Course CXLII (1999) Plasmas in the Universe edited by B. Coppi, A. Ferrari and E. Sindoni

Course CLIV (2003) Physics Methods in Archaeometry edited by M. Martini, M. Milazzo and M. Piacentini

Course CXLIII (1999) New Directions in Quantum Chaos edited by G. Casati, I. Guarneri and U. Smilansky

Course CLV (2003) The Physics of Complex Systems (New Advances and Perspectives) edited by F. Mallamace and H. E. Stanley

Course CXLIV (2000) Nanometer Scale Science and Technology edited by M. Allegrini, N. Garc´ıa and O. Marti

Course CLVI (2003) Research on Physics Education edited by E.F. Redish and M. Vicentini

Course CXLV (2000) Protein Folding, Evolution and Design edited by R. A. Broglia, E. I. Shakhnovich and G. Tiana

Course CLVII (2003) The Electron Liquid Model in Condensed Matter Physics edited by G. F. Giuliani and G. Vignale

Course CXLVI (2000) Recent Advances in Metrology and Fundamental Constants edited by T. J. Quinn, S. Leschiutta and P. Tavella

Course CLVIII (2004) Hadron Physics edited by T. Bressani, U. Wiedner and A. Filippi

Course CXLVII (2001) High Pressure Phenomena edited by R. J. Hemley, G. L. Chiarotti, M. Bernasconi and L. Ulivi

Course CLIX (2004) Background Microwave Radiation and Intracluster Cosmology edited by F. Melchiorri and Y. Rephaeli

Course CXLVIII (2001) Experimental Quantum Computation and Information edited by F. De Martini and C. Monroe

Course CLX (2004) From Nanostructures to Nanosensing Applications edited by A. D’Amico, G. Balestrino and A. Paoletti

Course CXLIX (2001) Organic Nanostructures: Science and Applications edited by V. M. Agranovich and G. C. La Rocca Course CL (2002) Electron and Photon Confinement in Semiconductor Nanostructures ´dran, A. Quatedited by B. Deveaud-Ple tropani and P. Schwendimann Course CLI (2002) Quantum Phenomena in Mesoscopic Systems edited by B. Altshuler, A. Tagliacozzo and V. Tognetti Course CLII (2002) Neutrino Physics edited by E. Bellotti, Y. Declais and P. Strolin Course CLIII (2002) From Nuclei and their Constituents to Stars edited by A. Molinari, L. Riccati, W. M. Alberico and M. Morando

Course CLXI (2005) Polarons in Bulk Materials and Systems with Reduced Dimensionality edited by G. Iadonisi, J. Ranninger and G. De Filippis Course CLXII (2005) Quantum Computers, Algorithms and Chaos edited by G. Casati, D. L. Shepelyansky, P. Zoller and G. Benenti Course CLXIII (2005) CP Violation: From Quarks to Leptons edited by M. Giorgi, I. Mannelli, A. I. Sanda, F. Costantini and M. S. Sozzi Course CLXIV (2006) Ultra-Cold Fermi Gases edited by M. Inguscio, W. Ketterle and C. Salomon Course CLXV (2006) Protein Folding and Drug Design edited by R. A. Broglia, L. Serrano and G. Tiana

Course CLXVI (2006) Metrology and Fundamental Constants ¨nsch, S. Leschiutta, A. edited by T. W. Ha J. Wallard and M. L. Rastello

Course CLXVIII (2007) Atom Optics and Space Physics edited by E. Arimondo, W. Ertmer, W. P. Schleich and E. M. Rasel

Course CLXVII (2007) Strangeness and Spin in Fundamental Physics edited by M. Anselmino, T. Bressani, A. Feliciello and Ph. G. Ratcliffe

Course CLXIX (2007) Nuclear Structure far from Stability: New Physics and New Technology edited by A. Covello, F. Iachello, R. A. Ricci and G. Maino

This page intentionally left blank