Lecture Notes in Mathematics A collection of informal reports and seminars Edited by A. Dold, Heidelberg and Bo Eckmann, Z0rich
161 James Stasheff The Institute for Advanced Study Princeton / NJ / USA
H-Spaces from a Homotopy Point of View
$ Springer-Verlag Berlin-Heidelberg • New York 1970
This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar meac~s,and storage in data banks. Under §.54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to he determined by agreement with the publisher. © by Springe~r-VerlagBerlin. Heidelberg 1970. Library of Congress Catalog Card Number 71-154651 Printed in Germany. Title No. 3318
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of G e o r g e
Yuri Rainich
to m e t h e d e e p s i g n i f i c a n c e of a s s o c i a t i v i t y
Preface
T h e s e n o t e s h a v e t h e i r o r i g i n in a c o u r s e g i v e n a t P r i n c e t o n U n i v e r s i t y in t h e f a l l of 1968; I a m m o s t g r a t e f u l t o P r i n c e t o n f o r p r o v i d i n g t h e o p p o r t u n i t y to g i v e s u c h a c o u r s e a n d to t h o s e i n s t i t u t i o n s w h i c h p r o v i d e d s u p p o r t d u r i n g the p r e p a r a t i o n of t h e s e n o t e s :
P r i n c e t o n , t h e U n i v e r s i t y of N o t r e D a m e ,
The
I n s t i t u t e for A d v a n c e d Study, the A l f r e d P. Sloan F o u n d a t i o n and NSF G r a n t GP-9590.
T h e c o u r s e i t s e l f w a s p r e s a g e d b y a l e c t u r e at t h e M i c h i g a n
C o n f e r e n c e on the T o p o l o g y of M a n i f o l d s [ S t a s h e f f ] .
State
The p r e s e n t a r r a n g e m e n t
of t o p i c s o w e s m u c h t o a s h o r t c o u r s e g i v e n a t B o s t o n C o l l e g e in t h e f a l l of 1969.
F i n a l l y , m y d e e p g r a t i t u d e to M r s .
A n n G o s l i n g of P r i n c e t o n U n i v e r s i t y
a n d M i s s E v e l y n L a u r ~ n t of T h e I n s t i t u t e of A d v a n c e d S t u d y f o r t h e i r f i n e p r e p a r a t i o n of p r e l i m i n a r y
and final t y p e s c r i p t s
of t h e s e n o t e s .
An a t t e m p t h a s b e e n m a d e to b r i n g t h e s e n o t e s up to d a t e , b u t c u r r e n t a c t i v i t y is s u c h t h a t t h e d a t e in q u e s t i o n is at b e s t t h e e a r l y spring of 1970. It is h o p e d t h a t m o r e r e c e n t r e s u l t s w i l l b e c o v e r e d a t t h e C o n f e r e n c e on H - s p a c e s to b e h e l d a t the U n i v e r s i t y of N e u c h a t e l in A u g u s t , 1970, f o r w h i c h t h e s e n o t e s should provide adequate background. Bibliographic references
a r e g i v e n in t h e f o r m [Hopf].
Where a given
a u t h o r h a s m o r e t h a n one e n t r y in the b i b l i o g r a p h y , the v a r i o u s e n t r i e s a r e d i s t i n g u i s h e d by u n d e r l i n i n g s ,
Princeton,
e.g.,
[Hopf] v s .
[_Hopf].
N e w J e r s e y and
Lansdale, Pennsylvania
S p r i n g , 1970
TABLE
OF
CONTENTS
Chapter PREFACE
...............................................
INTRODUCTION
..........................................
THE
HOPF
THE
PROJECTIVE
MAPS
CONSTRUCTION
INTO
iNVERSES,
AN
PLANE H-SPACE:
OTHER
4
ASSOCIATIVITY:
5
H-SPACES
6
THE
7
HOMOTOPY
8
MAPS
9
SPACES
3
.................................
7
ALGEBRAIC
SPACES
ARE
FINITE
CONSTRUCTION
H-SPACES INDUCED
I0
DLFFERENTIAI~
Ii
A
-SPACES
AND
STRUCTURE, ETC ................ TOPOLOGICAL
COMPLEXES.
SPECTRAL
ASSOCIATIVITY
OF
I
................................
MULTIPLICATIONS, LOOP
WHICH
BAR
V
GROUPS
. . 14
.................
SEQUENCE
.............
...............................
.....................................
BY
H-MAPS
IN T H E
BAR
10
................
..........................................
23 27 31
............................. CONSTRUCTION
20
38 44
• • • • 48
n
IZ
MASSEY
13
HOMOTOPY
14
STRUCTURE
15
INFINITE
16
OPERATIONS
IN I T E R A T E D
REFERENCES
............................................
PRODUCTS
AND
GENERALIZED
COMMUTATIVITY ON LOOP
BAR
CONSTRUCTION..
59
..............................
65
B x ...................................... SPACES
................................... LOOP
SPACES
...................
71 75 81 89
H-SPACES
FROM
A HOMOTOPY
POINT OF VIEW
by J a m e s Stasheff
The concept of H-space
e v o l v e d f r o m t h a t of t o p o l o g i c a l g r o u p .
w a s Hopf [Hopf] w h o f i r s t c a l l e d a t t e n t i o n to m a n i f o l d s cations,
and many basic
It
with continuous multipli-
i d e a s i n t h e f i e l d a r e d u e to h i m .
The
H
in H-space
m a y b e t a k e n in h i s h o n o r . The concept of H-space as a significant generalization results
is valuable both because
of its p a r e n t
and because
in t o p o l o g i c a l g r o u p s w h i c h a r e n o t a c c i d e n t s
in the c a s e of L i e g r o u p s , This course
it occurs
in n a t u r e
it h e l p s to e l u c i d a t e
of the e x t r a a l g e b r a
or,
the extra analyticity. is a survey
homotopy point of view.
of the c u r r e n t
s t a t u s of H - s p a c e s
Homology or cohomology,
ordinary
from a
or extraordinary,
w i l l b e u s e d a s a t o o l , b u t w e a r e n o t i n t e n t o n t h e t h e o r y of, f o r e x a m p l e , algebras
per se.
ing s p a c e s
We w i l l b e p a r t i c u l a r l y
and their
as
concerned
with loop spaces,
Hopf
classify-
iterates.
Let us begin.
D e f i n i t i o n 1.
An H-space
that for some point for
e
consists
we have
of a s p a c e
e x = x = x e.
X
and a map
m : X × X-~ X
[Where reasonable,
we write
such x7
m(x,y). ] Several
of "topological and existence
comments
group"
a r e in o r d e r .
That " H-space"
is a generalization
is obvious; we have dropped the conditions on associativity
of i n v e r s e s .
S i n c e w e a r e a d o p t i n g t h e p o i n t o f v i e w of h o m o t o p y t h e o r y ,
it w o u l d
be natural and
to require
m IX × e
only a homotopy unit,
be homotopic
i.e. , require
to the identity rel
has the homotopy extension property, can be deformed
then m'
X
to one with precise
has the homotopy
with exact unit
e'
t y p e of
= I
e.g. , the category
will say means
"X
is
CW"
X'
extending
W e i n t e n d to o p e r a t e nice,
of s p a c e s
For
to indicate
a similar
the s e t of p a t h c o m p o n e n t s
with homotopy unit e
i s c l o s e d in
m
has
e
where
spaces
are at least this
on s p a c e s
of greater
locally is
out elsewhere
in t h e C W - c a s e ,
this
A comparable
generality
we will often assume
[We
Essentially
and r u l e out l o c a l p a t h o l o g y .
can be studied,
X,
as homotopy unit.
X belongs to this category.]
reason,
X)
as a branch X
of
is connected;
as a discrete
set
operation.
From is o f t e n i r r e l e v a n t ,
t h i s h o m o t o p y p o i n t of v i e w , as we shall see,
will play a significant
any such additional structure, general.
(X × X , X v
which can be given a multiplication
to h o m o t o p y t h e o r y b u t is c a r r i e d
point set topology.
homotopy,
if
if
if
m Ie × X
of the h o m o t o p y t y p e of C W - c o m p l e x e s .
s t u d y of c o n t i n u o u s m u l t i p l i c a t i o n s
with a binary
More directly,
-- XeUoI m,
However,
a multiplication
in a c a t e g o r y
we f o c u s on g l o b a l p r o p e r t i e s
less appropriate
unit.
(e,e}.
that the maps
the existence
but associativity,
of h o m o t o p y i n v e r s e s
b o t h s t r i c t a n d up to
role in our development.
Before
considering
we look at what can be said about H-spaces
in
THE HOPF
Geometrically, the Hopf construction. famous
fibratfons=
D e f i n i t i o n 1.1. H
in
the outstanding
S 3 - + S 2, S 7 - ~ S 4 a n d
of t h e m u l t i p l i c a t i o n
l i k e t h i s to p r o d u c e
is
his
S 15-~ S 8.
m : X X Y -* Z, t h e H o p f c o n s t r u c t i o n
is the map given by
join : X × I × Y / R
consequence
H o p f [Hopf] u s e d s o m e t h i n g
Given a map
: XsY-~ SZ
CONSTRUCTION
where
R
(x,t,y)-~
(t,xy).
is t h e r e l a t i o n
[Here
X~Y
is t h e
{(x, 0, y) ~ (x, 0 , y ' ) ,
(x, t , y )
(x, ,1,y)} Theorem
1. 2. [ S u g a w a r a ] .
If (X, m )
i s a CW H - s p a c e ,
then
H
is a q u a s i m
fibration,
i.e.
'
H
: ~ri{X~X, H
m ~
- l ( b ) ) -~ wi(SX, b)
m
is a n i s o m o r p h i s m
for any
be SX. Rather
than prove this theorem,
we study an alternate
f o r m of t h e
Hopf construction. Definition 1.3.
Given
H(ml : X × CY~JZ-~ m Theorem
1.4.
equivalence
SY
Proof.
y, t h e n Since
5.
If p :
If X = Z
H(m)
m(
and
,y}
Y.
is a w e a k h o m o t o p y
Z-~ # are qnasifihrations
follows from fundamental
P I : P - l ( U ) -~ U, p I : P - I ( V ) -~ V sois
and
of q u a s i f i b r a t i o n s
E-~ B
and
Of X ~ Y o n t o
is a q u a s i f i b r a t i o n .
X × CY -~ CY
the theorem
T h o m on t h e c o n s t r u c t i o n Theoreml.
is i n d u c e d b y p r o j e = t i o n
[D_old a n d L a s h o f ] .
for each
fact, bundles),
m : X X Y -~ Z , t h e H o p f c o n s t r u c t i o n
B = U~.JV and
theorems
(in
of D o l d a n d
[Dold and Thorn]: where
p I : P-l(U~V)
U, V
are openin
-~ U ( - ~ V
are
B
andif
q. f. s
p.
Theorem
1.6.
If p : E - - B D A
exist deformations
Dt : E-~ E
and and
p] : p ' l ( A ) dt : B-~ B
: D -~ A such that
is a
q. f a n d t h e r e
then
D 1 : id, D 0(E) C D d I = id, d 0 ( B ) C A
and
d0P = p D 0
DOI . : p ' l ( b ) - . p ' l ( d o ( b ) ) then
p
is a
is a weak homotopy equivalence
q.f. T h e c o n d i t i o n on
m(
e n c e of a r i g h t u n i t b e l o n g i n g to
, y) Y.
follows for connected It a l s o h o l d s if X = Y
Y from the existis CWas
we now
see.
Theorem map:
1.7.
~ugawara].
(x, y) -~ (xy, y) Proof.
If X
is a c o n n e c t e d
H-space,
then the shearing
is a w e a k h o m o t o p y e q u i v a l e n c e . I c l a i m t h e i n d u c e d m a p of h o m o t o p y g r o u p s :
~r.1(X)~ Tri(X) -~ wi(X ) O ~ri(X) is given by 4, ~ -~ = + 6, ~, which is clearly an isomorphism.
To
verify the claim, w e use a lernrna. Lemma
1.8 [Hilton].
If X
is an H-space,
the usual operation in ~r.(X) is 1
induced by the multiplication Proof.
T h i s c a n b e p r o v e d a s in t h e u s u a l p r o o f f o r t h e c o m m u t a -
t i v i t y of lr1 of a n H - s p a c e . l o o p s p a c e of X
in X.
In f a c t , b y r e g a r d i n g
Iri+l(X)
and using the induced multiplication
as
of l o o p s ,
w1 of t h e i - t h the usual proof
applies directly. The restriction group under
"X connected"
shearing Remark.
CW H - s p a c e ,
a n d h e n c e s o is t r a n s l a t i o n
m a p : x, y - ~ x, x y By altering
m(
the shearing
, y).
is a
is c o n n e c t e d
CW.
map is a homotopy
The left unit is relevant
to t h e
in t h e a n a l o g o u s w a y .
t h e t o t a l s p a c e of H ( m )
but without changing the homotopy
type, we can obtain a map with the weak covering X
to " l r 0 ( X )
m.". Thus for a connected
equivalence
can be weakened
This follows from results
homotopy property
of D o l d if
of D o l d on t h e c o n s t r u c t i o n
of
such fibrations
[Dotd].
being c~ntent ourselves Theorem unit
1.9.
and both
X X CYUZ m
Proof.
Both spaces
sequence,
1.10.[S.ugawara].
Proof.
are simply connected.
x-~ (e,t,x). If
X
X X CYUZ
via the Meyer-
t h e f i b r e in
H(m)
is c o n t r a c t i b l e
T h i s i s in f a c t a c h a r a c t e r i z a t i o n .
is connected
CW, then
X
is an H-space
of s p a c e s
if
which are CW
of X
in
of p E
to
b y t h e s u m of ~ p
is g i v e n b y e ¢ X. and
H(m).
Map
For the converse,
X-~ ~B
X-~ ~B.
by
kx(t)=p
If t h e d i a g r a m
kt(x).
of h o m o t o p y
sequences: ,
,r. ( x )
.... Ir.(E) i
z
~ Ir.(B) i
~ ~ri - I(X)
~ i . l ( ~ E ) ~ - " ~ Tri_I{QB)
?
iri.,l(~E × X)--
•i s c o m m u t a t i v e ,
it follows that
~B
p
is a
q.f.,
@[f] = [h I S n] then
h
let
h:CS n-~ E such that
f o r a n y c h o i c e of h.
can be taken to be
In p a r t i c u l a r ,
h(t,x) =kt(x),
sothat
is t h e i d e n t i t y .
Tri_I(~B) -~ ~ri.l(X)
g : S ( S n) -~ B b e t h e a d j o i n t ,
there exists
~i_I(X)
~ri(X) -~ w i ( ~ B ) -~ ~i{X)
The most direct way to see this is to recall how f:S n-~ ~B,
] •
h a s t h e w e a k h o m o t o p y t y p e of ~ E X X.
T h e p o i n t t o c h e c k is t h a t
Given
-~
in h o m o l o g y .
is a n H - s p a c e ,
The existence
~E × X-* ~B
The map
in t h e t o t a l s p a c e .
kt be a contraction
Map
and there is a left
t y p e of X * Y .
i s t h e f i b r e of p : E - ~ B', a q u a s i f i b r a t i o n
with fibre contractible
let
Y are connected
induces an isomorphism
in t h e t o t a l s p a c e ; e. g. , v i a
and only if X
and for the time
m a p is a m a p of t r i a d s w h i c h ,
N o t i c e t h a t if X
Theorem
X and
has the weakhomotopy
induced by the shearing
Vietoris
result
with quasifibrations.
If Y = Z
e • Y, t h e n
X~Y
We will not need this stronger
is defined.
i . e . , g ( t , x ) = f(x) (t).
ph~ g if f
rel
t = 1.
comes
hlSn ;f '.
from [If p
Since
We d e f i n e f':S n-* X isa
Hurewicz
fihring,
the homotopy
then
a
h t ( k ) -- k ( t ) , Now all spaces
of ~ E
X X.
Theorem
Theorem
1.11.
If X
is realized
by a map
starting
f 0 ( ~ ) -- e e X C E . ]
at
being CW,
~ B -~ X
the loop space
1.10 c a n n o w b e c o m p l e t e d is a retract
of a n H - s p a c e
~B
given by a covering
has the homotopy
Use
type
by the following remark. Y, t h e n
X
admits
a multiplica-
tlon with unit. Proof.
of
X X X-~ Y × Y-* Y-~ X
and check on units.
THE
PROJECTIVE
The full significance most
clearly
Definition
in the mapping
2.1.
p i n g cone of H(m), i . e . ,
E.G.
to
Z. 2.
H*(XP(2))
plane
which is isomorphic
XP(2)
of a n H - s p a c e
XP(2) = RP z
X -- S 1
XP(2)
X = S3
XP(2) = QpZ
X = S7
XP(2)
= Cp 2 = SZUe
i s usually e x p l o i t e d
through
are classes
non-trivially, secondary unless
giving a proof,
[Adams].
Proof.
If u
therefore,
or extraordinary,
n = 0,1,3,7.
its cohomology. S u , S v c H v (SX) p u l l b a c k
from
S(uSv) E H*(S(X*X))
H$ ( X P (2), S X ) .
S (u'v)
2.3.
16
such that comes
Su
Theorem
is the map-
8
= Kp 2 = S8Ue
-~ H* (S (X*X) ) --,- H * ( X P ( 2 ) ) - ~
Before
(X,m)
4
S4Ue
( S u ) ~ J (Sv) ~ H # ( X P ( 2 ) ) to
shows up
C ( X x C X U X ) . W=~m )SXm
If u , v e H $ ( X ) then
of t h e H o p f f i b r a t i o n s
H(m).
X = SO
This space Theorem
of t h e e x i s t e n c e
c o n e of
The projective
PLANE
Sn
-*
Su
S u -~ Sv
let us look at the consequences.
is an H-space
generates SuUSu
-~
H * (SX)-~
Hn(sn), # 0.
one shows,
if a n d o n l y if n = 0 , 1 , 3 , 7 . Su
pulls back and
Now using operations, following Adem
S(u*u)
maps
primary,
and Adams,
SuUSu
= 0
Theorem
2.4.
sPt..)eq~.Je p+q
a r e o n e of t h e f a m i l y
(1, 3),
Most cases tions [Adams], and
in conjunction
XP(2)
(3, 5),
with
q>
can be eliminated
with Theorem
Theorem
approximation
can be defined,
2.2.
2. 2.
by using cohomology The remaining
[Hubbuck],
Following
Y -~ Y X Y
up to homotopy,
being given in barycentric
where
as
,x : y - . y × y approximation
coordinates,
can be deformed to the diagonal
on the chain level,
Applying this to
keeping
o2
opera(7, 11)
[Douglas and Sigrist].
We
induces
track
n
maps
to = 0
(t0, t z , x l x 2 )
if
t1 = 0
(t0, t 1 , x l )
if
t2 = 0
if x 1 = e
(t0, t l + t 2 , x l)
if x 2 = e
o
n
For to
on
example,
~
approximation
of t h e i d e n t i f i c a t i o n s ,
we read
note that
points
of
o2
map by taking a nice cellular consider
(first p-face) on
for
the usual
one
@ (last (n-p)-face).
X 2 ' we have induced a
a 2 × X 2 which is compatible
a diagonal
First
a
identifications:
~- ( t 0 + t l , t 2 , x 2 )
g .
we construct
Y = XP(2).
if
to a cellular
on
[Milgram],
we have the
and using the true diagonal
approximation
and hence
(p,q)
cases,
SX~.) o 2 X X 2 w h e r e ,
(t o , t l , t 2 , x I , x 2) ~ (t 1 , t 2 , x 2)
diagonal
if a n d o n l y i f
to this later.
diagonal
which,
p+l
(3, 7).
of u s i n g K - t h e o r y
Now to prove specific
(1, 7),
not listed
(7, 15), a r e d i s p o s e d
will return
is anH-space
XP(2).
with the identifications On the chain level,
off
A~(sZ @ u ® v) = (a2 ® u ® v ) @ * + (el®v)@ (al@ u) + * ® (s2 @ u®v).
w h i c h in t u r n i m p l i e s original representation
Su~.~Sv
is c a r r i e d b y
0.2 0 u @ v, c o r r e s p o n d i n g in t h e
to S(u*v).
T h e a b o v e p r o c e d u r e is t y p i c a l of m a n y r e s u l t s in the t h e o r y of H-spaces.
T h e c o m b i n a t i o n of t o p o l o g y and a l g e b r a in q u e s t i o n is u s e d to
c o n s t r u c t a n o t h e r s p a c e in w h i c h the combination.
h o m o t o p y alone r e f l e c t s the o r i g i n a l
T h i s a u x i l l i a r y s p a c e is t h e n s t u d i e d b y t h e a v a i l a b l e f u n c t o r s of
a l g e b r a i c t o p o l o g y , c o n v e r t i n g the p r o b l e m thus into a p u r e l y a l g e b r a i c one.
MAPS INTO AN H-SPACE: ALGEBRAIC
STRUCTURE,
The fact that X h o m o t o p y classes of m a p s Theorems
INVERSES,
OTHER
MULTIPLICATIONS,
ETC.
is an H - s p a c e is immediately reflected in the set of [K,X]
3.1. [Copeland].
of a space
The functor
K
into X.
[ ,X,x0]
takes values in the category
of sets with binary operation and Z-sided unit w h e n defined on a category including
~X,x0) and
~X X X, x0 z) if and only if X
unit if and only if (ilviz)~:[A × B;X] -~ [AVB;X]
is an H - s p a c e with x 0 as
is onto for all A , B
in the
category. The crucial idea is to realize that the multiplication allows us to add m a p s of A and B tion i t s e l f a p p e a r s If Theorem
into X to get a m a p of A × B and that the m u l t i p l i c a -
a s t h e s u m of t h e two p r o j e c t i o n s
K
is CW,
3. Z. [ J a m e s ] .
[K,X]
of maps
of
binary
operation
K
the set If
K
[K;X]
X
h' and
as a trivial
: K-~ X X X hw~
f hence If
structure
on
Definition
3.3.
homotopic
to
Theorem
3.4.
CW-complex,
X
hu~
X.
an algebraic
loop,
classes
i.e. , has a
identity and left and right inverses.
quasifibration.
such that
on to
t h e s e t of h o m o t o p y
forms
T h e i d e a of t h e p r o o f is to r e g a r d X X X
X X X
structure.
is a CW-complex,
into an H-space
with Z-sided
has more
of
s h' ~
Given (f,u).
the shearing
map
f, u : K -- X , t h e r e T h u s if
h'
= (h,w),
s : X X X -~
is thus a map we have
w~
u
f.
itself is CW, the inverses
come
from
the corresponding
X. A map
I : X -~ X
is a left homotopy
inverse
if
m(l
X 1)
is
e. [Sugawara,
Sibson].
left and right homotopy
If
X
has the homotopy
inverses
always
exist.
t y p e of a c o n n e c t e d If
m
is homotopy
11
associative,
left and right homotopy Proof:
(Theorem q(e,
We know the shearing
1.1); l e t
q : X × X-~ X × X
)_~ I × 1 i s a l e f t h o m o t o p y If m
homotopy
inverses
is homotopy
inverses
map
up to homotopy.
is a homotopy
be an inverse.
inverse
since
associative,
is completely
agree
A map
~
satisfying
m ( ~ × 1) i s h o m o t o p i c
the agreement
analogous
equivalence
to
e.
of l e f t a n d r i g h t
to the agreement
of s t r i c t
inverses
in a monoid. Similarly, Theorem [K,X]
3.5.
If X
is a group,
is a homotopy
natural
Regarding maps
we have the following result.
are fibrewise
associative
with respect
projections
maps.
of
to maps
Hence the shearing
i f a n d o n l y if i t i s a f i b r e h o m o t o p y
translation
(left or right) is a homotopy
X
X
(e.g.,
admits X
a numerable
K
is CW,
then
as fibrations,
map
the shearing
(left or right) is a homotopy
equivalence
equivalence.
[DoLd] w h i c h i m p l i e s
The converse
holds pro-
by sets which are nullhomotopic
in
is CW). In light of these
Theorem
covering
and
K - ~ K ~,
X × X -~ X
equivalence
vided
H-space
remarks
1.4 and in Chapters
definition of H-space
and the importance
of translation
4 a n d U, i t m a y b e a p p r o p r i a t e
to include left and/or
to amend
right translation
in the
being a homotopy
equivalence. Multiplications. Given a space others
X , if i t a d m i t s
which are not homotopic
Theorem
3.6.
multiplications
[Copeland]. is in
Proof: [KVK;X]
1-1
to
If X
is exact for any CW
K.
m,
it may admit
m. i s C W , t h e s e t of h o m o t o p y
correspondence
The sequence
a multiplication
with the loop
-~ [ S K v S K ; X ] - ~ If X
of
[XAX;X].
[K~K;X]--
is an H-space,
classes
(ilV iz)*
[K × K ; X ]
the last three
sets are
L
12
l o o p s , a n d the m a p s a r e m o r p h i s m s t h e r e o f . (ilWi2)* ' l ( x )
It f o l l o w s t h a t the i n v e r s e i m a g e s
a r e in 1-1 c o r r e s p o n d e n c e for a l l x ~ [KVK;X]. If X = K is CW, the m u l t i p l i c a t i o n i n d u c e s a s p l i t t i n g f r o m w h i c h
the t h e o r e m f o l l o w s . T h e e a s i e s t c a s e s to c o m p u t e a r e Theorem 3.7.
K ( ~ r , n ) ' s or s p h e r e s .
Up to h o m o t o p y , K(Ir, n) a d m i t s o n l y one m u l t i p l i c a t i o n .
Up to h o m o t o p y , S 3 a d m i t s
12 d i s t i n c t c l a s s e s of m u l t i p l i c a t i o n .
Up to h o m o t o p y , S 7 a d m i t s
120 d i s t i n c t c l a s s e s of m u l t i p l i c a t i o n s .
[ J a m e s , L e m m e n s ] h a v e s h o w n a l l the c l a s s e s on S 3 and S 7 c a n b e r e p r e s e n t e d in t e r m s of the s t a n d a r d m u l t i p l i c a t i o n s b y u s i n g c o m m u t a t o r s . F o r p r o d u c t s of s p h e r e s ,
[Loibel] gives a f o r m u l a which for
S 3 × S 3 is c o m p u t e d b y [Norman] to be
220 × 316 .
[ N a y l o r ] a n d [Kees] h a v e s h o w n t h a t SO(3) = RP(3) c l a s s e s of m u l t i p l i c a t i o n s .
7 and
220.
768 d i s t i n c t
[Rees] h a s f o u n d 3 0 , 7 2 0 m u l t i p l i c a t i o n s on K P ( 7 ) ,
a n d [ M i m u r a ] h a s f o u n d the n u m b e r s f o r 215- B9 " 5 "
has
B • 55.
SU(3)
a n d Sp(2)
to b e r e s p e c t i v e l y
7.
M o r e g e n e r a l l y A r k o w i t z a n d C u r j e l [A-C] h a v e i n v e s t i g a t e d the f i n i t e n e s s of this n u m b e r for f i n i t e c o m p l e x e s .
T h e y f i n d that a m o n g the
c l a s s i c a l a n d e x c e p t i o n a l L i e g r o u p the n u m b e r is f i n i t e o n l y f o r SO(n)
with
n < 16,
SU(n)
with
n < 5
n # I0, 14
m
Sp(n)
with
G 2, F 4 a n d F i n a l l y , for a space and
n < 7 E 7.
X w i t h j u s t two n o n - t r i v a l h o m o t o p y g r o u p s
~rp, p > n, the s e t of c l a s s e s of m u l t i p l i c a t i o n s c a n b e i d e n t i f i e d w i t h
HP(x~JC;~rp) w h i c h is HP((~rn, n ) A ( ~ n , n ) ;
Tr ). P
A m o r e c l a s s i c a l a p p r o a c h to c l a s s i f y i n g m u l t i p l i c a t i o n s w o u l d
n
~3
r e g a r d a s m ~ a i v a l e n t t h o s e w h i c h c o r r e s p o n d up to h o m o t o p y u n d e r a h o m o t o p y equivalence.
J a m e s s h o w s t h a t t h e r e a r e o n l y s i x s u c h c l a s s e s on S 3, b u t in
g e n e r a l the c o m p u t a t i o n s s e e m m o r e difficult. some reasonable results are available
[Cheng].
For two-stage Postnikov systems,
ASSOCIATIVITY:
Although an important
strict
SPACES
associativity
AND
groups,
be seen to be equivalent homotopy
theory.
Definition
4.1.
s e t of p a i r s
for,
from
to spaces
[Moore].
It characterizes
o u r p o i n t of v i e w ,
of l o o p s ,
the latter
the operation
~X
is an associative
GROUPS
concept,
it plays
loop spaces
topological being more
t'~X : {X:[0, r ] - ~ X I X(0) = k ( r ) = * )
(k, r ) c X R X R .
under
TOPOLOGICAL
is not a homotopy
r o l e i n t h e s t u d y of H - s p a c e s .
hence topological
monoid)
LOOP
H-space
and
groups basic
will
in
topologized
as the
(= t o p o l o g i c a l
m = + given by k , ~ -~ k + / ~
defined by
k + ~ : [0,r+s]-~
x+. In the CW category loops are essentially
the same
That loop spaces groups
was proved
for semi-simplicial Theorem
4.2.
cW complex,
complexes
[Milnor].
Proof: homotopy
If X
then there
type as
X'.
and from
~X
a homotopy
as topological
groups
p o i n t of v i e w ,
spaces
or associative
H-spaces.
of t h e h o m o t o p y
though the result
of
t y p e of t o p o l o g i c a l
was presaged
by a similar
one
d u e to [ K a n ] . has the homotopy
is a topological
First
I [r,r,+s]:t~.(t-r).
are usually
by Milnor,
X by
group
t y p e of a c o n n e c t e d
GO()
has the homotopy
We might as well assume
of the homotopy
t y p e of ~ X .
t y p e of ~ X '
if
then that
is a countable
X
X
countable
has the same
s implic ial complex. Let The equivalence {x1 . . . . .
G(X)
be defined as a quotient
relation
of a s u b s e t
of ~_)X n n
as follows:
is
x n) ~- (x 1 . . . . .
A x i .....
x n)
if x i = x i + 1 o r
x i . 1 = x i + 1.
15
GO<) i s t h e s u b s e t of t h e q u o t i e n t r e p r e s e n t e d x i, x i + 1 b e l o n g to a s i m p l e x of
x.
The group
operation
(x 1 . . . . .
x p ) (Xp+ 1, . . . .
inverse
to
(x 1 . . . . .
wise linear
linearly
shows
principal
bundle
E(X)
p o i n t , iv
The contraction
The unit is
(x 1 . . . . .
from
G(X)
Xn)
x i to
such that
of
*
and
(x n , x n _ 1 . . . . .
x 1) i s
m a y b e t h o u g h t of a s a p i e c e -
x i + 1.
i s C W a n d i s t h e f i b r e of a c o n t r a c t i b l e
obtained by removing
is a weak homotopy
homotopy
Xn)
is juxtaposition:
The n-tuple
loop running
(x 1 . . . . .
x 1 = x n = *, a c h o s e n b a s e v e r t e x
i and
Xn) = (Xl'" " . , x n ).
Xn).
Milnor
lemma
for each
by n-tuples
E(X)
the condition
gives a map
equivalence
"x
n
is the base
G ( X ) -~ f~X w h i c h b y t h e 5 -
and hence,
~X
also being CW, a
equivalence. On the other hand,
CW H-space
is a loop space.
principal
fibration
Theorem
4.3.
translation
associativity
Again the construction
will be very
[Dold-Lashof].
equivalence
of a c o n t r a c t i b l e
important. If
is a weak homotopy
weak homotopy
alone is enough to show a connected
X
is an associative
equivalence,
X-~ fib X
H-space
then there
which respects
such that right
is a space
BX
the multiplication
and a up to
homotopy. Since for any
X
Iro(~Y ) is a group for any
such that
which is not a group. equivalence
If
m(
xy ,x).
is not a group,
lr 0
since for each
ponent) such that we see that
~ro(X)
is a group, x, there
and yx
composed
multiplication;
H-space associativity
e.g. , a discrete
then right translation
is a point
y
lie in the component
On the other hand, of an associative
Y, t h e t h e o r e m
with
m(
,y).
we will see later
need not itself admit is not a homotopy
is obviously topological
e.
com-
Using the associativity,
is the identity in either that a space an equivalent invariant.
monoid
is a homotopy
(any in the "inverse" of
false
order.
of t h e h o m o t o p y associative
type
16
Theorem version
appears
4.3 is the result
in Steenrod'
s Topology
was constructed
by
Dold and Lashof
in the present
Further
[Milnor]
generalizations
of c o n s i d e r a b l e of F i b r e
Bundles.
for arbitrary
A restricted
Such a space
topological
groups
BX
and then by
generality.
are due to [Sugawara]
in detail in the associative
evolution.
and [Stasheff].
casees are due to [Milgram],
Further
variations
[Steenrod] ~nd [Fuchs].
We follow Dold and Lashof. Definition
4.4.
Given a map
[i. e. , p ( x z ) = p ( z )
for
p : E-~ B
and a fibrewise
action
z c E, x ~ X], the Dold-Lashof
D L ( E ) = X X CEI.J
E
DL(B)
B
/~ : X × E - ~ E
construction
is the map
D L (p) CE~9 P
induced by projection Theorem
4. 5.
onto the second
If p : E - ~ B
a weak homotopy
equivalence
is a quasifibration for each
The proof is essentially under
mild restrictions,
Dold' s weak covering
factor.
z, then
a n d if DL(p)
as in Theorem
one should be able to start homotopy
been done by [Fuchs]
under
property)
assumptions
p(
is
is a quasifibration.
1.4.
As remarked
with a fibration
and obtain one. including
,z) : X-~ p'l(p(z))
that
earlier,
{having
This has in fact X
has a continuous
inverse. In p a r t i c u l a r , DL(p)
is just
DL(X)
induced by
of a problem;
H(m).
there
If
if w e s t a r t w i t h ~
is associative,
x, ( y , t , z) -* (xy, t, z). are
several
solutions.
p being the unique map
X - ~ ~, t h e n
w e c a n d e f i n e a n a c t i o n of The continuity
X
on
of t h i s a c t i o n i s s o m e t h i n g
We can restrict
the category
of s p a c e s
17
involved, redefine
struction.
the product topology, or strengthen the topology on the con-
D o l d a n d L a s h o f do t h e l a t t e r .
will be the s a m e
Up to w e a k h o m o t o p y
type,
the spaces
[Stasheff], so w e prefer not to take sides.
If ~
is associative, then, w e can iterate the construction.
be the initial m a p
E-~ B
andlet
Pn+l = DL(Pn)' taking
DL(E
n
Let
) = X × CE
n
P0
~.J E ~n n
into D L ~ B n ) = C E n ~.)P n B n . Inductively, /~n+l (x' (y,t,z)) = (xy, t,z). This is well-defined since
m
is associative a n d the a b o v e r e m a r k s
on continuity continue
to a p p l y . Now let obvious inclusions.
Poo : Eo0
.=~
B~o b e t h e l i m i t of t h e m a p s
Pn
under the
A g a i n D o l d and L a s h o f use a stronger topology on
guarantee continuity of an action of X
on
E
E
00
to
, but this is not relevant to the CO
results w e are after. Theorem
4.6.
For
n <_o0, Pn
is a quasifibration if right translation m ( , x )
is a w e a k h o m o t o p y e q u i v a l e n c e . This follows from Theorem problem
for quasifibrations
4.5 for
since any map
n < Qo. Sn
f :
-~ B
P a s s i n g to the limit is no m u s t lie in s o m e finite
o0
B.. I
E Theorem
CO
4, 7.
has one crucial ~-.(E
attribute.
) = 0 for all
i.
This follows f r o m the fact that E e x a m p l e , b y the h o m o t o p y
T h e total space
h : X-~ ~B X x -~ k
where
is contractible in E n + I, for
z -~ (e,t, z) w h i c h uses the left unit.
N o w let us specialize to the case w e seek.
n
E
0o
w e call E X.
is given by the i m a g e of the m a p
P0 : X - ~ #.
B
oo
is the space
BX
T h e weak. h o m o t o p y equivalence X-~ ~SX
considered before; i.e.,
kx(t) = (t,x) ¢ S X = B I. A s before, w e see
~h~ : ~i(X) -~ wi(X)
is
X
the identity.
fore
h~
O n the other hand, @ is an i s o m o r p h i s m
is a n i s o m o r p h i s m .
since
Iri(EX) = 0, there-
18
That forming
kxy
space on
h
to k
respects the multiplications w e can see b y explicitly de+ k
x
y
within
~ B 2.
This can be done m o r e
SX~-)a 2 × X 2, w h i c h w e considered above.
edge of a 2
and
k
+ k
x
y
Here
along the other two - the h o m o t o p y
k
easily in the loop
xy
runs along one
is obvious.
Loop s p a c e s a r e a p a r t i c u l a r l y s i g n i f i c a n t c l a s s of a s s o c i a t i v e H spaces.
Up to h o m o t o p y , t h e y r e p r e s e n t a l l the e x a m p l e s w i t h h o m o t o p y
inverses.
T h e y h a v e p a r t i c u l a r l y n i c e p r o p e r t i e s w i t h r e s p e c t to o u r c o n -
structions. Theorem 4.8.
If X is CW, t h e n X h a s the h o m o t o p y type of B ~ X .
Proof.
A specific map
B ~ X -+ X w h i c h is a l w a y s a w e a k homo~opy
e q u i v a l e n c e is o b t a i n e d b y e x t e n d i n g the m a p
S ~ X -~ X g i v e n b y
(t, k) -+ k(t).
T h e i d e a is to d e f i n e A n x{~X) n ~ X by mapping
A n - ~ I in such a w a y that then evaluating
w e l l d e f i n e d m a p of B ~ X -+ X.
kl÷... +k n
on
I gives a
S p e c i f i c f o r m u l a s c a n b e g i v e n [Stasheff], b u t the
essentials are conveyed by labeling edges.
J 1
19
This means
if
k i : [0, r i ] - * X, t h e n f o r
r1 [0, rl-~r2] , t h e f a c e
t o = 0 is m a p p e d
n = 2, t h e f a c e
to
t 2 = 0 is mapped
r1 [rl--~r2,1], a n d t h e f a c e
T o s h o w t h i s m a p is a w e a k h o m o t o p y e q u i v a l e n c e , it b y
E~X-~
is g i v e n b y Similar
LX
w h i c h i s t h e i d e n t i t y on ~ X .
(t,k,p)
formulas
(s) = p ( t r s )
where
can be given for
E
p : [ 0 , r ] - * X. -* L X .
n
To begin with,
t 1 = 0 to
to [0,1].
we need only cover I × ~X × ~X-*
This induces
El-* LX.
LX
H - S P A C E S WHICH A R E F I N I T E C O M P L E X E S
T h e m o s t obvious e x a m p l e s of connected topological groups are Lie groups.
T h e positive solution of HilberV s Fifth P r o b l e m by Gleason,
M o n t g o m e r y and Zippin [ G - M - Z ] characterizes a Lie group as being a locally Euclidean topological group.
F o r s o m e time it w a s thought that a h o m o t o p y
version w a s true, i.e. , that if G
w a s a topological group of the h o m o t o p y
type of a c o m p a c t manifold, then G
w a s of the h o m o t o p y type of a Lie group,
although [Slifker] s h o w e d that it w a s too m u c h to ask the h o m o t o p y equivalence to respect the multiplication {cf. Chapter 7 and II). In fact, the conjecture w a s true for all the k n o w n H - s p a c e s except for products with S 7 or quotients thereof.
T h e first e x a m p l e of a simply con-
nected H - s p a c e manifold not of the h o m o t o p y type of a Lie group or a product with S 7 w a s due to [Hilton and Roitberg].
The e x a m p l e w a s the
w
total space of a principal S3-bundle over
$7,
Soon after, [Zabrodsky]developed techniques with which I w a s able to s h o w the Hilton-Roitberg e x a m p l e w a s of the h o m o t o p y type of a toplogical group.
Let P1UP2,
Zabrodsky' s m e t h o d is called " m i x i n g h o m o t o p y types"
P
b e the s e t of p r i m e s in the n a t u r a l n u m b e r s a n d P =
a d e c o m p o s i t i o n into d i s j o i n t s u b s e t s .
L e t CP.~
d e n o t e the c l a s s of
a b e l i a n g r o u p s of o r d e r s n o t d i v i s i b l e b y p r i m e s in P i ÷ l " Let
X, X 0 b e s i m p l y c o n n e c t e d C W - c o m p l e x e s .
T h e o r e m 5.1.
Let
exists a space
X(P1)
f : X-~ X 0 be a r a t i o n a l h o m o t o p y e q u i v a l e n c e . and a factorization X
X{P1)
f i b r e of f. h a s h o m o t o p y g r o u p s b e l o n g i n g to ~ P i "
There
X 0 of f s u c h t h a t the If f is a h o m o m o r p h i s m
1
of t o p o l o g i c a l g r o u p s , X(P1)
h a s the h o m o t o p y type of a t o p o l o g i c a l g r o u p .
21
Theorem
5. 2.
Let
X. b e s i m p l y c o n n e c t e d 1
fi : Xi-* X0 be a rational Z = Z(X1, X2)
and maps
CW-complexes
homotopy equivalence. g i : Z -* X . ( P . )1I
There
for
i = 1, 2.
Let
exists a space
such that the fibre has homotopy groups
b e l o n g i n g to l ~ P i + 1. Z
If the ingredients are topological groups and homomorphisms, has the homotopy type of a topological group. Since f is a rational equivalence, its fibre F type of a product Pe'~PFP
where
has the homotopy
Fp has p-primary homotopy only. X ( P I)
can be thought of as the subfibration of X
in which the fibre is cut down to
pc~-PiF p. A n alternate construction of X ( • I) is given in Chapter 9. If f is a h o m o m o r p h i s m
of topological groups, then X(IP I) has the
homotopy type of ~ B X ( P I) and hence of a topological group. T h e o r e m 5.2 is proved by taking Z to be the fibre product {pull back) of fi : Xi(Pi)"~ X0"
z--~
x I
(~i)
x 2 ( P 2) -- x o
If t h e i n g r e d i e n t s observed
by Browder,
to p r o d u c e
are topological groups
the construction
a classifying
space
and homomorphisms,
can also be carried
Y = Z(BX1, B X 2 ) .
o u t in t e r m s
We t h e n h a v e
Z
as of BX.
of t h e
h o m o t o p y t y p e of ~ Y
a n d h e n c e of t h e h o m o t o p y t y p e of a t o p o l o g i c a l g r o u p .
Proposition
{Xi}
5.3.
If
are simply connected
finite complexes,
l
then
Z has
t h e h o m o t o p y t y p e of a f i n i t e c o m p l e x . Proof: s o is
H (X,Q).
H (X;Z). P
Since
Since
Moreover,
# H (Xi;Q)
H (X.;Z) 1 p
is f i n i t e d i m e n s i o n a l
is f i n i t e d i m e n s i o n a l
the finite dimension
as a Q-vector
for each
has a common
space
p, s o is
finite upper bound for
22
Q
and all
p
simultaneously
(i. e . ,
the maximum
h o m o t o p y t y p e of a f i n i t e c o m p l e x , decomposition
of
for example,
group",
i.e. , the sympletic
in t h e o p p o s i t e o r d e r . classifies
XI, X2).
Thus
X has the
that obtained by a homology
X.
We a r e n o w r e a d y f o r e x a m p l e s . sympletic
for
If co E lr6(S 3)
S 3 - ~ Sp(2) -* S 7, t h e n
lr6(S 3) ~ Z 4 + 7. 3 w i t h g e n e r a t o r s t h e h o m o t o p y t y p e of X 1 = Sp(2)
Let
group
Sp{2)
denote the "opposite
obtained by multiplying
is c h o s e n a s t h e g e n e r a t o r
~pp(2) -~ S 7 i s c l a s s i f i e d v,,a and
2 e P2
and
fied by
-v, + ~ = 7~o. Interchanging
,
We h a v e
X 2 = Sp(2)
over
by
quaternions
which -¢o.
Recall that
¢o = v, + a .
K ( Z , 3) X K ( Z , 7) w i t h
3 E 3F l, the resulting g r o u p is the Hilton-Roitberg e x a m p l e
as a bundle b y
Sp(2)
and
If w e m i x
Sp(2)
classi-
gives a g r o u p classified
5c0.
F o r certain
n ~ +_ 1 (6), w e also obtain H - s p a c e s
exhibit as soon as possible.
O f course the a r g u m e n t
of Lie groups w h i c h are rationally equivalent. later, but first w e study the construction
B X
We
w h i c h w e will
can be applied to any pair
will return to such e x a m p l e s
further.
THE BAR
The space
CONSTRUCTION
BX
SPECTRAL
as constructed
SEQUENCE
is filtered by the subspaces
B .
The
n
e x a c t c o u p l e in h o m o l o g y o r c o h o m o l o g y sequence. sequence spectral
converges sequence
extension same
For example, to
in h o m o l o g y E O H , ( B x }.
e.g.,
if X
a s in T h e o r e m
g i v e s r i s e to a s p e c t r a l
Eln = H , ( B n , B n _ I )
and the spectral
[Milnor] presented
for his construction.
property,
argument
that results
If t h e s p a c e s
is C W , t h e n
the corresponding
involved have the homotopy
H.(Bn, Bn_I) ~
1. 9 s h o w s t h a t if X
H.(SEn_I).
is c o n n e c t e d
The
CW, then
En_ 1
h a s t h e h o m o t o p y t y p e of t h e n - f o l d j o i n , free with coefficients
X * . . . * X. If H , ( X ) is t o r s i o n n in a r i n g A , w e h a v e E 1 • ~ @AH..(X) a n d d 1 c a n b e n
identified with
~(-1) i 1 ®...®
Theorem
If X i s c o n n e c t e d
6.1.
is isomorphic
Corollary
CW a n d
6.2.
Similar
in c o h o m o l o g y
6.3.
E 2 ~ Ext H
generated
in each dimension. There
,
free,
(x)
is u s e d to s h o w
H,(pt))
of t h i s r e s u l t
Corollary
the homology,
of m ,
X
Tor
means
then
E 1, d 1
-,
d l d 1 = 0.
a s in
6.1.
is a n a l g e b r a i c simpler
follow from applying
(H, (pt), H~ (pt))
are many H-spaces
for
is t h a t
to evaluated by algebraic
results
is t o r s i o n
B ( H , (X)).
E2 ~ T°rH,(x)(H*(pt)'
and can sometimes
H.(X)
E 1 c a n b e t a k e n a s t h e d e f i n i t i o n of t h e b a r c o n -
Note that the associativity
The usefulness
H(B).
of
~
1.
with the bar construction,
Our description struction.
m, ®...®
~
provided
than computing Horn
is a n e x t e r i o r
carefully.
H~ (X) is f i n i t e l y ',-
(e. g. , m a n y c l a s s i c a l
with suitable coefficients,
functor
groups) for which
algebra
on odd d i m e n -
sional generators. Theorem
6.4.
dimensional
[Borel].
generators,
If H , ( X ) ~ E ( x 1 . . . . . then
Xn )' a n e x t e r i o r
H ( B x ) ~ P ( T x 1. . . . .
algebra
7Xn ) t h e p o l y n o m i a l
on odd algebra
24
on generators
~rx. which pull back to duals of Sx. on SX. I 1
Proof:
EXtE(xi)(k,k)
for any commutative
k n o w n to be isomorphic to a polynomial algebra Ext
coefficient ring k is
P(yi ) on generators
higher dimension than x.. i
Since
E X t A ® B ~ E X t A ® EXtB"
Thus it is sufficient to s h o w
is a natural functor of algebras, w e have Ext E(x)(k, k) ~ P(y).
The proof amounts to putting a differential on E(x) ® P(y) acyclic, i.e., a derivation
Yi of one
d defined by
dx = y
and
so as to m a k e it
dy = 0 so that d(xy k) =
k+l Y In classes
E 2, t h e g e n e r a t o r s
x. a n d w i l l a p p e a r 1
even total degree.
Yi w i l l b e r e p r e s e n t e d
E 12.
in
Therefore,
Since
b y d u a l s of t h e
d i m x .1 i s o d d ,
the spectral
sequence
E2
is entirely
collapses;
EZ = E
of .
o0
Since the polynomial
algebra
although
to show that the algebra
Recall
it remains
that the algebraic
(*)
a 1®
To complete Theorem
•
"
the proof,
6.5.
multiplication
"
is free,
diagonal
® an-"
for
Z (al ®
there
is no extension
B (A)
"
"
structure
problem;
is correct
E
~ H
(B X)
topologically.
is given by
. ® a p )®
(a p + l
®
"
® a n ).
"
we use the following theorem.
[1.~ilgram].
The diagonal map
on each term
of t h e s p e c t r a l
A : B X -~ B X × B X
sequence,
which on
induces
a
E 1 is given by
(*). Proof: mation. relation
First,
We continue
up to homotopy,
to follow Milgram BX
looks like
to get a nice chain approxi-
nU a n X x n / R
where
given by:
(t o . . . . .
t n , x 1. . . . .
x n) "- (t o . . . . .
t~i. . . . .
x i x i + 1. . . . .
~(to,...,ti_~+ti,...,xi,...,Xn)
x n)
if xi=e.
if
t.=O 1
R
is the
25
with the meaningless symbols u. ~ X, w e denote by I
XoX 1 and XnXn+ 1 to be deleted.
lUll.., lu ] the cell n n
diagonal approximation on G
n
involved.
of B X.
The
On. the chain level w e have
1%1 = EUll.-. of t h e i d e n t i f i c a t i o n s
n
r. (last p-face) X (first (n-p)-face)
given by
induces a diagonal approximation on B X.
because
X uI X . . . X u
Given cells
®
[Up+ll... lu n]
This proves
W e c a n a l s o s e e h o w to c o m p a r e
Theorem
6. 5.
B X with the bar construction
( C , ~X)). Theorem
cation and
6.6.
[Stasheff,
C,(X)
Milgram].
If X h a s a n a s s o c i a t i v e
denotes cellular chains, then
There are examples of such
U(n) with the cell
Ingeneral, a multiplication £an be
deformed to be cellular, but this m a y destroy associativity. h o w to modify
B
multipli-
C,(Bx) -~B(C,(X)).
X, e.g. , 0(n) or
structure described by [M£11er~ Yokota].
cellular
W e will see later
to obtain the analogous result in general.
The spectral sequence can be obtained entirely in terms of B(C,(X)).
This is the approach of ~ilenberg and Moore]. Theorem
6.4. presents us with polynomial algebras, m a n y of which
cannot be realized topologically. Theorem
6.7. [James]. Proof:
If B S 7
p 4 (u8) = u 8 3 # 0 but p 4 is zero.
Thus
B
S 7 admits no associative multiplication. exists, then H
factors as p i p 3
03S 7) ~ P(u8)" which takes
M o d 3, w e have
u 8 through
H 20 which
cannot exist. S7
In f a c t , w e will soon see
S 7 admits no homotopy associative
multiplication. Theorem
6.8. [Clark].
If X
is an associative H-space and
H,(X;Z)
is
26
t o t a l l y f i n i t e l y g e n e r a t e d a n d n o t a c y c l i c t h e n H 3(X) I 0. T h i s r e q u i r e s m o r e c o m p l i c a t e d a n a l y s i s , b u t t h e p r i n c i p a l :is the • same.
I n g e n e r a l , the q u e s t i o n of w h i c h p o l y n o m i a l a l g e b r a s c a n b e r e a l i z e d h a s
not been settled although Clark' s procedure gives many restrictions. have b e e n m a d e explicit in v e r y s p e c i a l c a s e s ,
[Smith] a n d [Ochiai].
These The m o s t
e x t e n s i v e r e s u l t s a v a i l a b l e n o w a r e due to [Hubbuck]. T h e s t u d y of the s p e c t r a l s e q u e n c e w h e n it d o e s n o t c o l l a p s e i s of great interest.
We s h a U r e t u r n to it w h e n we a r e in p o s i t i o n to i n t e r p r e t the
differentials geometricaUy.
ASSOCIATIVITY
HOMOTOPY
Now let us look at "associativity
up to homotopy"
in an elementary
way. Definition and
7.1.
(X,m)
is a homotopy
m { m X 1) a r e h o m o t o p i c
an associating
and homotopy
nected,
7.2.
A specific
homotopy
rn(1 )< rn) is called
[Sugawara].
on
an associating
If
(X,m)
extends
The situation
is homotopy
to a fibration
associativity
X)< CXU X, sowe m
homotopy
ones.
for instance,
on
S 3,
can be analyzed
"geometry".
The lack of strict X
S 7, w h i c h a r e n o t e v e n h o m o t o p y
multiplications,
to associative
the Hopf fibration
action of
X 3 -~ X .
such as
associative
by using a little more
Theorem
if t h e m a p s
as maps
are H-spaces,
which cannot be deformed better
H-space
homotop)r.
There associative
associative
with
over
defeats
work alittle
ho{X, y, z) = ( x y ) z
X X Of X CX[.)X) -~ X X C X h D X
associative
and
is con-
XP(2).
our previous harder.
and
X
Let
definition h
t
of a n
: X 3-~ X
h l { X , y , z) = x ( y z ) .
be
Define
by
x(y,t,z) = (xy, Zt, z) if O < 2 t < l =h2t.l(X,y,z)
T h i s iS w e l l d e f i n e d a n d c l o s e construction. we let
Definition
7.3.
XP(3)
case we let
be the quasifibration
denotes
The projective cohomology.
enough to fibrewise
As in the associative
P2 : E 2 -~ B 2 = X P ( 2 )
if l < Z t < 2 .
space
to apply the Dold and Lashof P o : X - ~ ~, Pl = H ( m )
and now
we have just constructed.
CE2~-)XP(2). XP(3)
This time the non-trivial
is used like cup cubes
XP(Z)
by ar,~lyzing its
are the significant
feature.
28
Theorem
7.4.
S 7 admits no h o m o t o p y associative multiplication.
This w a s originally proved by direct computation involving the obstruction, which is a class in 7rzl(S7) [James] but n o w it follows f r o m the s a m e a r g u m e n t w e used to s h o w
S 7 w a s not associative.
However,
the h o m o t o p y
a r g u m e n t has the advantage of detecting a Z - p r i m a r y obstruction as wet1. T h e existence of such a fibring over
XP(Z)
is equivalent to h o m o t o p y
associativity, at least for C W - s p a c e s . Theorem
7.5. [Sugawara].
multiplication
if t h e r e
If X
is C W ,
is a sequence
then X
admits a h o m o t o p y associative
of f i b r a t i o n s
X-~ El-- E z
• - . B 1 -* B z
with X
contractible in E 1 contractible in E 2. Recall that in this situation X
is a retract of ~ B I. The contraction
of E 1 in EZ. is used to s h o w this retraction respects the multiplication up to homotopy. Theorem
7.5 is in contrast with classical projective g e o m e t r y w h e r e
the existence of projective 3-space is enough to prove associativity of the coordinate r i n g . true
From
in general
but there
Rather Given
o u r p o i n t of v i e w ,
this would mean:
XP(3)
l a c k of n a t u r a l
examples.
is a curious
obvious
candidates
=> B x .
are the exotic multiplications
q : S 3 X S 3 --~ S 3 , t h e q u a t e r n i o n
multiplication,
S3 v $3 by an element of ~6 (s3) = ZIZ.
we can alter
This is not
on
S 3.
it a w a y f r o m
In this way, w e get the IZ different
h o m o t o p y classes of multiplications including quaternions and its opposite
q : x,y~
q(y,x)
29
which differ by a class
plication m we see
is h o m o t o p i c
H(m)
to q + no0 f o r s o m e
is h o m o t o p i c
p1 : w7(S 4)
to
Since
pl
detects
are associative, pI(H(q))
Thus
pI(H(q))
w e have
ZBC~r6(S3),
and
From
Any multi-
the c o n s t r u c t i o n ,
Now a homomorphism in $4~.) e 8 w e h a v e
we have
pl(~co) # 0.
Since
q and
m
pl(zco). In general, for m
-- q + nco,
can be h o m o t o p y associative only if
In fact, J a m e s shows in these cases the multiplication [_s_s
homotopy associative, i.e. , XP(3) XP(n)
[James].
pI(H(q)) = pl(H(q)) + pl(~co) are non-zero.
pl(H(m)) - I + n(3). Thus
these cases
n e ZlZ.
pl(a) = k where
m u s t have the s a m e sign as
n - 0 or I rood 3.
of w6(S 3)
H(q) + n ~ co e ~r7($4).
Z 3 can be defined by
p l ( u 4 ) = ku 8. q
co w h i c h is a g e n e r a t o r
can be formed.
[Slifker] goes on to s h o w in
can be f o r m e d for all n, although by the classification
theorem for Lie groups, only q and cations on the 3-manifold
S 3.
q are homotopic to associative multipli-
Thus there are topological groups of the h o m o -
topy type of S 3, but not multiplicatively equivalent to the unit quaternions in either order of multiplication. The first example of a homotopy associative H-space which is not equivalent to a loop space was given by [Adams]. Example
7.6.
Let
Y
be a M o o r e space
3 but no other primes is possible. Zn-I and for i ~ n, ITi (X) Consider
Y
Z and
has cohomology only in dimension
~r.(sZn'l)p. 3
yC~Z
structions to deforming
Thus
Y(G, Zn-I) w h e r e divisibility by
~Zy
Y X Y -~ 2
1
which is an associative H-space. ~ Z y X ~ Z ~ Z y -, ~ 2 ~ 2 y
into Y
The oblie in
Hi(y A Y; ir.(~Z ~Zy, y)). The relative groups are trivial to at least 5(Zn)-3, i
SO the obstructions vanish.
Similarly, there are no obstructions to deforming
an associating homotopy within ~ Z ~ 2 y
to one in Y.
That
space follows f r o m the decomposability of P n UZn = u2nP Further examples,
even finite complexes,
Y
is not a loop
for p > 3 and
n J-p-h
have been constructed by
30
Zabrodsky.
We w i l l p r e s e n t t h e s e e x a m p l e s w h e n we h a v e d e v e l o p e d the a p p r o p -
r i a t e m a c h i n e r y to e x p l a i n t h e m , n a m e l y , the h o m o t o p y a n a l o g u e s of h o m o morphisms.
MAPS OF H-SPACES
homomorphism
Bya
f ( x y ) = f(x}f{y). morphism.
For
of H - s p a c e s
example,
In a limited
if
sense,
we mean a map
g : W-* Z
then
~
f : X-* Y
: ~W-*
g
f~Z
such that
is ahomo-
we shall see that for associative
H-spaces
this
is the only example. Clearly
a homomorphism
S f : S X -~ S Y , b u t s u c h m a p s Definition 8.1. H-map
if
fm
If
(X,m)
is h o m o t o p i c
H-maps associative H-map
n ( f X f).
generally
are H-spaces,
maps
a map
for H-spaces
X P ( 2 } - ~ YP(2}
an H-map.
If
f: X - * Y
in g e n e r a l ,
but notnecessarily
but,
extending
is an
for An
BX-* By.
have been investigated
(shm) map"
and
n
are
strictly
f(x)f(yz)
exist for all
involving
associative,
or via
if w e h a v e t h e a p p r o p r i a t e
we are led to conditions
If s u c h m a p s
m
in t w o w a y s - v i a
are homotopic
by
map
f(xy)f(z).
f(xyz)and These
I g x X 3 -~ Y.
More
I n ' l x x n -> Y, s u i t a b l y r e l a t e d
on the
n, we have a " strongly homotopy multiplica-
[Sugawara] or an "A
-map"
[Stasheff] or an "H-homomor-
[Fuchs].
Definition 8. g.
an A -map
Let
X
and
Y
b e associative H - s p a c e s .
if t h e r e e x i s t s
a f a m i l y of m a p s
h 1 =f
and
t i _ l , X 1. . . . .
h i { t 1. . . . .
A map
h. : i i-1 ~< X i -~ Y
n
that
YP{n)
t h e y a r e n o t t h e h o m o t o p y a n a l o g of h o m o m o r p h i s m s .
are h0motopic
two homotopies
phism"
to
into
people.
f(x}f(y)f(z}
tive
(Y,n)
XP{n}
generally.
homotopy conditions for the latter
Consider
faces.
and
X-* Y will induce
The necessary several
occur more
are the relevant
H-spaces,
f:
induces a map
for
f : X -~ Y
is
1< i< n
such
1
x i)
t%
= h i - 1 {. . . .
t j. . •. , x. j x. j +. 1,.
= h .j ( t l , . " . , tj_ 1, x 1 . . . .
} if
t.j = 0
x j ) h i _ j (tj+ 1 . . . .
,ti_l, Xj+ 1 .....
x i)
if t.j = 1.
32
Such animals occur naturally.
For any space
m a k e the function space topology nice), let H(K) equivalences of K K r L s K
into itself. If K
and
L
K
(locally compact to
be the space of all homotopy
are two such spaces and
h o m o t o p y inverses, then there is a strongly h o m o t o p y multiplicative
homotopy equivalence
H(K)-~ H(L)
given by ~-~ r ~ s.
homotopy with R(0) = I and R(1) = sr, then the family
If R(t) : K-~ K
is a
{hi}, as constructed by
[Fuchs], looks like: hi(tI..... ti_l,¢l ..... ¢i ) = r #iR(tl ) CZ'''R(ti-1) ¢i s" The composition of A n - m a p s
is again an A n - m a p ,
families m u s t be fitted together, rather than composed.
families are
{h 1 : i i - I × X 1" - Y} and
to be Jlhl and
(jh) z to be
but the
For example,
if the
{Ji : ii-I X yi --* Z} then we define
(jh) 1
Jlhz + jz(hl X hl), m e a n i n g the h o m o t o p y :
Jlhl(xY) _~ Jl(hl(X)hl(Y)) _~ Jlhl(X)Jlhl(Y). For
(jh) 3, Jlh3 , jz(hl × h~), jz(h2 X hl) and J3(hl X h I X hl) a r e f i t t e d t o g e t h e r
as i n d i c a t e d below.
Full details are given (k(jh)).
y [Fuc s]
He points out
although they are homotopic.
a
((kj))1
is not the s a m e as
The a p p r o p r i a t e c a t e g o r y w h o s e o b j e c t s a r e
1
a s s o c i a t i v e H - s p a c e s has as m a p s h o m o t o p y c l a s s e s of s u c h f a m i l i e s
{hi}.
A l t e r n a t i v e l y [ D r a c h m a n ] g e t s a r o u n d the d i f f i c u l t y b y u s i n g h o m o t o p i e s of v a r i o u s lengths.
33
Of c o u r s e a h o m o m o r p h i s m
c o m p o s e d w i t h a n A - m a p is m u c h m o r e n
r e a d i l y s e e n to b e an A - m a p , the o b v i o u s f a m i l y b e i n g h o m o t o p i c to the one n d e f i n e d b y the g e n e r a l p r o c e d u r e u s i n g the " t r i v i a l " h, i . e . ,
h i ( t 1. . . . .
xi) = h(x 1 . . . x i )
family for a homomorphism
= h(Xl)...h(xi).
On the o t h e r h a n d , a m a p h o m o t o p i c to an A - m a p is i t s e l f a n A n
map, though again some fiddling with parameters Theorem 8.3.
[Fuchs].
n
is r e q u i r e d to s h o w t h i s .
A homotopy equivalence
f : X -~ Y is s t r o n g l y h o m o t o p y
m u l t i p l i c a t i v e if a n d o n l y if a n y i n v e r s e i s . Proof:
If f is a n H - m a p a n d g is a n i n v e r s e ,
we h a v e
gn ~ gn(fg X fg) ~ g f m ( g X g) ~ m ( g X g), which shows
g is a n H - m a p .
compatible with gf~
fg ~ id.
1X b y a h o m o t o p y
written as
To p r o c e e d f u r t h e r ,
we n e e d t h i s h o m o t o p y to b e
S p e c i f i c a l l y l e t fg ~ 1y b y a h o m o t o p y k.
If f m ~
n(f × f) b y
- g n ( ! X 1) - g f 2 ( g X g) + k m ( g × g).
I
and
f2' the a b o v e h o m o t o p y c a n b e F o r p u r p o s e s of i n d u c t i o n , w e
w i s h to f i l l in the d i a g r a m
fgfz(g ~
f g n ( l X 1)
[
x
~.
g)
] fz(g X g)
i)
The lower quadralateral
c a n b e f i l l e d in w i t h
l n ( l × 1) a n d t h e n the
u p p e r one b y u s i n g
l f 2 ( g X g) is we h a v e f o l l o w e d F u c h s in m a k i n g t h e c l e v e r
observation that
can be chosen so that
between
fgf a n d
l f.
fk is h o m o t o p i c to
If
as homotopies
34
The induction now proceeds,
constructing
at each state
so that
f n
{(fg)i}
is homotopic
to
(id) i.
Thus A -maps
are a reasonable
class
of m o r p h i s m s .
As expected,
n
A -maps
are nice with respect
to projective
spaces.
n
Theorem
8.4.
t e n d s to
XP(n)-@ YP(n).
Corollary t y p e of
Amap
8.5.
f : X-* Y
The homotopy
t y p e of
n
-map
BH(E)
if and only if Sf : S X - ~ S Y
is an invariant
ex-
of t h e h o m o t o p y
E. The induced map
terms
is a n A
of t h e f a m i l y
that "f respect H-map,
then
SX~)C(X
f P ( n ) : X P ( n ) -~ Y P ( n )
h i by formulas
the identifications fP(2)
X CX~)
m
[S.ugawara] which give
up to homotopy".
can be defined in terms
meaning
example,
of t h e r e p r e s e n t a t i o n
in
to the idea if
f
is an
XP(2) =
0<2s
(t,e,l, hz(Z-Zs,x, y))
1 < 2-S < 2 --
(s,x) ~
For
explicitly
X) by
(t, x, s, y) -~ (t,f(x),Zs,f(y))
and by
is constructed
(min[Zs, 1],x)
To show that
on
fP(n)
on
C(X
X Cx[-Jx)
--
m
SX. implies
the existence
of
h.
for
i < n
requires
1
u s e of
XP(n+l).
Before
doing so, we first
study some
special
A -maps. n
Theorem
8.6.
The usual map
X--
~XP(n)
is an A -map. n
This generalizes same terms
spirit. of
The maps
can be seen from
4.3 and a proof can be given in the
h. : i i - 1 M X i ~ ~ X P ( n ) l
8.6 is best possible,
the fact that
while the generator
(example
of T h e o r e m
can be described
conveniently
I i - 1 X X i × I - * Z~i × X i. Theorem
erator
part
10.7) that
of
H . (f~S 2)
for
is a polynomial
H v ( s 1) h a s t r i v i a l
S 1 --> ~ C P ( n )
S 1 -* ~ S z
is not an H-map. algebra
products.
i s n o t a n A n + l - m a p.
This
on a single gen-
We shall see later
in
35
Theorem
8.7.
If X
is an associative
H-space,
there
is a r e t r a c t i o n
~ X P ( n ) -~X
w h i c h is s t r o n g l y h o m o t o p y m u l t i p l i c a t i v e . Since there 8.6
~ X P ( n ) -~ ~ B x
is a h o m o m o r p h i s m ,
is a s t r o n g l y h o m o t o p y m u l t i p l i c a t i v e X-~ ~B X
it is s u f f i c i e n t to s h o w
equivalence
is s t r o n g l y h o m o t o p y m u l t i p l i c a t i v e ,
~ B x -~ X.
so by Theorem
By Theorem 8.3,
s o is
any inverse. Since we have an A of B x
into
By
corresponds
00
-equivalence
to a n A
between
- m a p of X
X
into
and
~ B X, e v e r y m a p
Y, b u t n o t n e c e s s a r i l y
to
¢O
a homomorphism. morphisms
Consider
f(x) = x
and
[0, 1] w i t h i t s u s u a l m u l t i p l i c a t i o n .
fl(X) = 1 a r e h o m o t o p i c
but not via homomorphisms. To consider A
[X, Y]
(Consider
this relation
denote homotopy
classes
(B I is c o n t r a c t i b l e )
ft(0). )
more
of A
00
via A~-maps
The homo-
fully, we follow [Fuchs] and let
-maps,
i.e. , a homotopy
is a f a m i l y
00
h. t : i i ' l × X i -~ Y
satisfying
the usual conditions for each
t.
Let
H o m ( X , Y]
1
denote homotopy classes ism for each
of h o m o m o r p h i s m s ,
i.e.
,
h t : X -~ Y
is a h o m o m o r p h -
t.
Consider
J : Horn [X, Y]-- A
[X, Y] o0
B :A
CO
[X,Y]-~ [B x , B Y ]
[B x, By] -~ H o m [ e B X, f~By] Let A : A
[•B x , n B Y ] - *
A
o0
{%Y} o {hi} o { A i X}
[X,Y] be given by
{h:nB x-* n B y } - *
¢0
where
{ A i X}
is t h e A
-map we have considered o0
X
~B X
and
{~}
is an inverse.
Let a : [B~x, B ~ y ] -* [X, Y] be given by f-~ a f o -I where G : B ~ X -* X Theorem
is given in T h e o r e m
8.8.
A J ~ B
4.8.
is the identity.
The proof involves showing commutativity
of t h e d i a g r a m
from
36
x!y ~B x
~
~By
f~Bf
a n d the c o r r e s p o n d i n g h i g h e r o r d e r d i a g r a m ,
w h i c h c a n be done in t e r m s
of
specific formulae. C o r o l l a r y 8. 9.
J ~ B
Theorem
~ B J ~
8.10.
Proof:
is
1-1 and onto. is the i d e n t i t y .
Consider X
B~X
f ---*
Y
--~ B~y Bf~f
w h i c h , u s i n g o u r s p e c i f i c d e f i n i t i o n of a, is c o m m u t a t i v e . C o r o l l a r y 8.11.
B J ~
is
l-1
a n d onto.
Combine these results. T h e o r e m 8.12.
B : Aco[X,Y]-* [Bx, By] J ~ : [X,Y]-~ A
[~X,~Y]
is
1-1 a n d onto w i t h i n v e r s e is
A J ~.
1-1 and onto w i t h i n v e r s e
a B.
co
We h a v e s e e n t h a t J
is onto f o r l o o p s p a c e s ,
i. e.
J : Horn [ I , I ] - ~ A ,
co
[I,I]
is n o t
l-l.
Notice that
e v e r y A c o - m a p of l o o p s p a c e s is h o m o t o p i c to
a loop map. T h e s i t u a t i o n f o r c e r t a i n c l a s s i c a l g r o u p s is t a n t a l i z i n g [ A t i y a h and Hirzebruch]. T h e o r e m 8.13.
A [B G, BH] ~ Horn (G, H) w h e r e ~
Notice strict homomorphisms A p p a r e n t l y a l i m i t of h o m o m o r p h i s m s
denotes "completion".
a r e u s e d b u t a c o m p l e t i o n is n e c e s s a r y .
is only an A
-map? CO
A - m a p s c a n be u s e d to c h a r a c t e r i z e n
structure.
H-spaces with additional
We c o n t e n t o u r s e l v e s w i t h the s i m p l e s t c a s e s .
T h e o r e m 8.14.
ACW-space
X is an H - s p a c e if and o n l y if X is a r e t r a c t
of
37
~SX. of
An H-space
XP(2)
is homotopy
associative of
if a n d o n l y i f
X
is a retract
We know if
X
is a CW H-space
associativity homotopy
(X,m)
yields
associative
gives an associating
~XP(2)
_~ X X ~ E 2.
within homotopy
~XP(2) within
X.
s h o w s t h e t w o w a y s of a s s o c i a t i n g
r(x+y+z)
and hence to each other. w e c a n u s e t h e a c t i o n of
associativity. reduced
(x1
product ~i .....
Alternatively, construction x ) i f x. = e n
(XlX?_ {x 3 (- . . (Xn))). • . ))).
1
~SX
then
~SX_~X
The converses
Similarly xyz
X ~ E 1 andhomotopy are easy.
an H-map in
X
are
on
H(m)
X
00
each hornotopic
with the retraction
of
~SX-~
with
given by
(x 1 . . . . .
(x 1 . . . . .
to X is
homotopy
up to homotopy,
=~flxi/---
is
the retraction
which follows from
can be described,
of [3ames]:
X
retraction
To show the usual retraction X
is a retract
via an H-map.
since the map is an H-map:
~SX ~ X
an H-map
~SX
i f a n d o n l y if X
by the x ) "-n
Xn,) -~
SPACES
As H-spaces extensions,
when does there
are those with
p : G --* K formed
are analogues
H-space
of
Theorem
Stasheff].
induced from
p
i
and 9.2.
an H-space
i~p
+q for some
[Copeland]._
criterion,
of m u l t i p l i c a t i o n s Proof
on
on
as fibre.
and
K,
of p a r t i c u l a r N o t i c e t h a t if
on
p-l(e)
G
can be de-
will be a sub-
let
is an H-map
over
Y
then the fibration
admits
a multiplication
is
(p-1)-connected,
p>
0, a n d
w.(Y) = 0 1
q. and
Y = K(G,q),
q>n
then
Ef
is
is an H-map. we will translate
"f
is an H-map"
various
reasons
into a purely
for the existence
K(w, n ) ' s.
of T h e o r e m .
Ef
(xx' , k k ' )
X
If X = K ( w , n )
] xe
is the path space,
multiplication However,
f : X --* Y
and will also consider
Ef = ((x,k) LY
If
i s t r u e if
if a n d o n l y if f
cohomological
H-map,
H
and then the fibre
the path fibration
In the next chapter,
Here
Cases
H
is a homomorphism. The converse
Corollary
with
G?
then the multiplication
is a homomorphism
[Moore,
~ Y -* E f p X
for
given H-spaces
exist such an H-space
and an H-map
to consider
G.
9.1.
such that
p
it is appropriate
In particular
G -* K b e i n g a f i b r a t i o n
is a fibration
so that
BY H-MAPS
of g r o u p s ,
i . e . , H - ~ G - * G / H = K.
we may ask: interest
INDUCED
is
Recall X, kc
LY,
f(x)=
{k : I -* Y ] k(O) =~ }.
An obvious candidate
(x, k) (x' , k' ) = (xx', kk' ) w h e r e
is not in
Ef
unless
h 2 : I X X 2-* Y be a homotopy
h2(1, x , x ! ) = f(x) f ( x ' ).
k(1)), w(x,k) = x.
f
kk' (t) = k(t) k' (t).
is a homomorphism. such that
We now define a multiplication (x,k) (x',k') = (xx',kk'
h2(0,x,x') in
+ H(x,x'))
for a
Ef
by
If
f
is an
= f(xx')
and
39
where
H(x,x')
: I-* Y by
H(x,x')
To see that this multiplication if x
or
x'
satisfying
= e.
It t u r n s
has a strict
homotopies
Notice, ~Y
unit, we need
o u t t h a t if a n y h o m o t o p y
the additional condition.
higher order
fibre
(t) = h 2 ( 1 - t , x , x ' ) . h2(t,x,x'
h 2 exists,
) = f(x) f ( x ' )
t h e n t h e r e is o n e
We wilt often have such comments
respecting
about
the unit.
with this additional condition,
is that induced by multiplication
on
that the multiplication
Y, a l t h o u g h h o m o t o p i c
on t h e
to l o o p
multiplication. The converse obstruction Hi(x~
theory.
The obstructions
X; lri(Y)).
Under
are the obstructions H-map,
p a r t of t h e t h e o r e m
to
fp b e i n g a n H - m a p .
~ri(Y ) = 0 f o r
HP(EfA
E f ; lr) a n d
Ef
involves a little more ~r is a n H - m a p
on
Ef.
By the general on
Ef
which can readily be evaluated Ahomotopy such that
K(G,q).
in
in
f; iri(Y))
f~r is n u l l h o m o t o p i c , f
if
which it is a n
(lr/k Tr)
and otherwise
is
if
on
obstruction
theory.
since the obstruction
If E f
l i e in
is (p-l)-connected.
of m u l t i p l i c a t i o n s
multiplication
Hi(Ef/~
The same follows for
Notice that different choices
classes
are classes
i < p + q with any coefficients
any multiplication,
multiplications
Since
in
exercise
i_> p + q.
The corollary admits
are all zero.
i.e. , for
forward
to f b e i n g a n H - m a p
lr A lr, t h e y m a p t o c l a s s e s
so its obstructions
an isomorphism,
is a s t r a i g h t
is in
of t h e h o m o t o p y result 1-1
h 2 g i v e r i s e to d i f f e r e n t
of T h e o r e m
3. 6, t h e s e t of h o m o t o p y
correspondence
as isomorphic
with
Fixing a homotopy
K{G,q)
and
L
m
is t h e f u n d a m e n t a l
o h 2 and its cochain
E f , El]
b c c q ' l ( K { ~ r , p ) ~ K { I r , p);G)
5b = m S f ~ ( ~ ) - (f X f)~t m ~ : ( L ) w h e r e or
[EfA
H q - 1 (K (Tr, p) A K (~r, p); G).
h 2 gives us a specific cochain
K(lr, p)
with
denotes the c o c h a i n of
b °, the correspondence
40
between multiplications
and the cohomology
E v e n if f is t r i v i a l , example,
if f = ~ t 2 w h e r e
Ef
L
g r o u p is g i v e n b y
can have more
is t h e f u n d a m e n t a l
than one multiplication. class
h a s t h e h o m o t o p y t y p e of S 1 × K ( Z , 2) b u t r e g a r d e d has a Pontrjagin
ring not ring isomorphic
The corollary
of a P o s t n i k o v
Definition 9.3.
A Postnikov
of f i b r a t i o n s
system
system
pnJn = J n - l '
[Suzuki,
fibre homotopy equivalent
to k i l l
systems
is to f o r m
~-ilX) f o r
i > n.
)
result
for a space
X
about
with maps
can be constructed
consists
of
classes Jn : X -* X n for
i
induced by a representative
The inclusion
Ef
[Peterson].
general
and cohomology
X , up to h o m o t o p y , n
fibration by the usual process.
L2' t h e H - s p a c e
( j n ) . : Iri(X) ~- lri(X n)
to a f i b r a t i o n
Such Postnikov obvious possibility
i > n,
Ef
Kahn, Stasheff].
{Xl,k 2,X 2 ....
-~ X n P n X n _ l -~ . . .
lri(Xn) = 0 f o r
~E
c a s e of a m o r e
kn ¢ H n + l {Xn - l ' • wn(X))' c a l l e d k - i n v a r i a n t s , t o g e t h e r that
as
For
of H 2 ( Z , 2 ; Z ) , t h e n
H . ( S 1 × K ( Z , 2))
a b o v e is a s p e c i a l
the k-invariants
a sequence
to
h 2 -~ {b - b ° ) .
in a v a r i e t y
by attaching
such
and
Pn
is
of k n. of w a y s .
c e l l s to
X
One so as
X n ~ Xn_ 1 c a n t h e n b e m a d e i n t o a
T h e f i b r e w i l l h a v e to b e
K(~r ( X ) , n )
and
kn
n
can be chosen as the transgression the obstruction
then
rrn
in t h e s i m p l y c o n n e c t e d
is i s o m o r p h i c
H n + l ( X n . l , X) b y t h e i n v e r s e H n + I ( X n _ I , X ) -- lrn(X) which gives
X
n
with
determines
wn(X)).
or, equivalently,
as
b u t is n o t a n i n v a r i a n t . k n+l
map. a class
That
kn
if Xn_ 1 h a s b e e n c o n -
w h i c h is i s o m o r p h i c
with
Choosing the isomorphism in
H n + l ( X n _ l , X ; ~rn(X))
induces a space satisfying
the
is easy to check.
Note that the Postnikov
of 7r, t h e n
case,
7rn+l(Xn_l,X)
of t h e H u r e w i c z
carefully
k n e Hn+l(Xn_l,
conditions for
class,
to a c r o s s - s e c t i o n .
Alternatively structed,
of t h e f u n d a m e n t a l
and
system
For example, g~ k n + l
determines
if X
determine
n
= K(~r,p)
spaces
t h e h o m o t o p y t y p e of X and
g
is a n a u t o m o r p h i s m
of t h e s a m e h o m o t o p y t y p e .
41
Corollary Theorem
9.4.
X
9.
generalizes.
Z
is an H-space
there
is a m u l t i p l i c a t i o n
k n+l
is r e p r e s e n t e d
Pn
if a n d o n l y if f o r a n y P o s t n i k o v Xn
for each stage
such that
Pn
system
for
X
is a n H - m a p
and
by an H-map.
The multiplication
p
can be constructed
f r o m one on
X
as
n
follows: X (n+l) n
There
is a c r o s s - s e c t i o n
so we map
a l l of X n × X n Similarly i > n+2.
Pn
X
(n+l)
× X
n
to (n+l) n
_in : X - * X n
-~ X × X - ~ X - * X .
It f o l l o w s t h a t The problem
lie inHi(Xn ~
since the obstructions
kn+l
T h i s t h e n e x t e n d s to
n
since the obstructions is a n H - m a p
over the (n+l)-skeleton
is r e p r e s e n t e d
X n ; lr i _ l ( X n ) )
l i e in H i ( X ~
by an H-map
of f i t t i n g t h e m u l t i p l i c a t i o n s
for
X ; "n'i(Xn_l))
by Theorem
p
i > 2n+Z.
together
for
9.1.
to f o r m a
n
multiplication
on
X
the multiplication
is s o l v e d b y c o n s i d e r i n g
"mixing and
however,
X ~1 Y'I"* X0
such that
I H i ( Y . ; Z ). p
the cohomology Yi+l
qi
Let
of Z a b r o d s k y '
X(P 1)~ X 0 by a succession
is a n i s o m o r p h i s m
There
i.
A
s method
of
for
becomes
r < i-1
K(Z
P
,i)
in
PI"
f o r b e i n g so d e t a i l e d .
as
and
and all a
p ~ ]t~1.
in t h e k e r n e l
in t h i s d i m e n s i o n
in t h i s d i m e n s i o n .
enough times
Repeat for all primes
is r e a s o n
in t h e k e r n e l
monomorphic
f : X ~ X0
a far.torization
Y i + l - * Y'I b e i n d u c e d b y a c l a s s
by taking a product with
i s m in d i m e n s i o n
interest.
of f i b r a t i o n s ,
homotopy equivalence
Continue killing classes
morphism
c a n b e a p p l i e d to a
to b e of o n l y t h e o r e t i c a l
is a r a t i o n a l
H r (X, Zp)
p be such a prime. 1
approach
by induction that we have constructed
qi * : Hr (Y.,Z)-~ 1 p
qi
X and constructing
Given a rational homotopy equivalence
we can construct
Assume
system
gives useful applications
homotopy types".
P1CP,
follows:
the Postnikov
H - * E - * K, b u t t h i s a p p e a r s
modification,
of
by induction.
More generally, fibration
the skeleta
to m a k e
qi+l
Let
of until
Now form an isomorph-
42
Theorem map,
9. 5. [Zabrodsky].
then
X{PI)
If f : X - * X 0 is a rational equivalence and an H -
admits a multiplication so that fl' f2 are H - m a p s .
Proof:
If f : X - ~ X'
is an H - m a p
with
f~ : H r ( X '; Z P
being an i s o m o r p h i s m
for
r < n, then ~ ~ K e r f',~ I Hn(X' , Z
)-~ Mr(x; Z ) P
) is represented by P
an H - m a p ,
for f'~ ~ = 0 is represented b y an H - m a p
being represented by an H - m a p
lie in H n ( x ' ~
and the obstructions to
X' ; Z
) w h i c h is m a p p e d
iso-
P morphically resented trivial
to
HncK ~ X; Zp)
by an H-map one) showing
will admit
Corollary H-maps,
The homotopy
showing
so as to map into a homotopy
f$¢~ i s a n H - m a p .
Thus the space
such that
Y
If t h e i n g r e d i e n t s
the space 9. 7.
multiplication
constructed
X'
by
T : X -~ Y.
s construction
are H-spaces
and
will be an H-space. is classified
by
m0, t h e n
M 10 a d m i t s
a
n
if n ~ 2 ( 4 ) . of
can be constructed
S--p(Z) a n d
maps
(e. g. , t h e
f can be lifted to an H-map
of Z a b r o d s k y '
If S 3 - ~ M 1 0 - ~ S 7
The values
or
is rep-
induced over
n
spaces
a
follows by induction.
9.6.
Application
( f : ~ f)~.
can be chosen
a multiplication
The theorem
by
n
not covered
by having
X z = S 3 X S 7 or
Sp(2) -~ K(Z,3)
in Hi(Sp(Z)~'Sp(2))
and for
previously
2 E P1
and
i = 3 or 7.
n -+3,
3 ¢ P2
X 1 = S 3 X S 7 and
Sp(2) -~ K(Z,7)
are
The H-spaces
and taking
X2. = Sp(Z)
are H - m a p s
+4(12).
These
X 1 ; Sp(g)
or Sp(Z).
The
since the obstructions lie
M I0 +3
are definitely not h o m -
m
otopy associative as ~pl : H 3 -~ H 7 is trivial w h i c h contradicts the existence of cup cubes in the 3-projective space.
43
The relation properties
of
f carries
we have studied between over to many
can also be proved
more
Theorem
has the homotop7
9.8.
Postnikov
X
system
k-invariants
of
X
Corollary
9. 9.
X
t y p e of a l o o p s p a c e
has each stage being a loop space
forms
as well as Aoki, H o n m a
structures.
of
Ef
and
The following corollary
directly.
are loop classes Various
other
properties
and the
in' Pn
of t h e t h e o r e m
if a n d o n l y if s o m e such that the
are loop maps.
have been proved:
[Suzuki],
[Iwata],
and Kaneko.
has the homotopy
t y p e of a l o o p s p a c e
if 17.(X) = 0 f o r 1
i
and
i>2p-2. This follows by induction on the stages of the Postnikov s y s t e m since
the only non-trivial k-invariants are in the range w h e r e an isomorphism.
the following result.
Corollary
H-space
rr.(X) = 0 for sented by an
An i
and
A -map" n
is
W e go into this in greater detail in the next chapter w h e r e w e
will be able to verify 9.10.
Hi(y)--~ Hi-I(~Y)
X
i>3p-1.
has the homotopy Todo
in cohomological
t y p e of a l o o p s p a c e
so, we will interpret terms.
if
"ct i s r e p r e -
DIFFERENTIALS
Throughout particularly
this chapter,
nice class
as a cohomology
~K(w,q+l).
w. : K × K - ~ K 1
generator
of
Hq(K;~r).
Alternatively,
the usual addition
in
Hq(;1~)
Hi(K/. as
K; Ir.(K)) 1
u
class,
is a multiplica-
Any other multiplicato the
We shall see later
that
group
Yr.
is represented
u E Hq(x;yr)
by an H-map
if and only if
the equation
into a homotopy
between
repre-
maps.
is primitive
10.2.
of
E 1 in the bar construction
if and only if
of the higher Let
dl[U ] = 0.
Theorem
spectral
sequence
10.1 g e n e r a l i z e s
to an
differentials.
X be an associative
following are equivalent:
q
a
i . e . , m S u = ~rlSu + ~ 2 ~ u .
interpretation Theorem
+ wZ St
u ¢ Hq(X,~r).
Our description shows
admits
~r
One need only translate sentative
q
since the obstructions
which are all zero.
the
K(w, q ) ,
~rl~ t
is the fundamental
A
BB.
Now consider
is primitive,
q
to this one for q >1
K(~r, 0) b e i n g t h e a b e l i a n
A class
the class
Wl~% q + ~Z~t q
"B
10.1.
consider
K(~,q)
by regarding
of
is homotopic
Theorem
for example,
That
#
K(vr, q)
with
ways,
u E Hq(x;~).
AnT representative
tion on
K(zr, n )
class
H-space.
in which case
L
and induces
we can regard
Y = K(lr,q)
and
K{w,q),
belong to
with
are the projections
tion on
homotopy
will denote an associative
occur
can be seen in several
up to homotopy, as where
X
of A - m a p s n
map can be interpreted a multiplication
IN THE BAR CONSTRUCTION
H-space
and
u • Hq(X;~v), t h e n t h e
u
45
l)
d [u] = 0 f o r
r < n
r
2)
Su
3)
u
pulls back to
XP(n)
is represented
by anA
-map. n
The equivalence differential
in a spectral
of
1) a n d
sequence
e x a c t c o u p l e of t h e f i l t r a t i o n . d [u] = 0 r class
is easy.
in
r < n, since A -maps
is a standard
u
proof that
as
f*(L
f being an An-map respect
interpretation
which can be seen most
A direct
If w e r e g a r d
K(lr, q ) , t h e n
2)
u
implies
the differentials
from
being an A -map n
) where
q
easily
of t h e
L
q
the implies
is the fundamental
dr[U ] = (fx...xf)*
dr[L q]
which are defined in terms
for
of
n
XP(s),
s < n. --
resents
L
Now
X-* ~XP(n)
Corollary
if
Su
If X
v ~ Hq+I(Bx;w)
r
since
extends
if a n d o n l y if
reasons,
L
q-r+l
Special
XP(n)-*
survives
q
cases
K(lr, q + l )
in which all maps and
dr[U ] = 0 for
of course,
i.e. , dr[U ] ~
which is zero for
to
is (p-1)-connected
The point is,
Corollary
] for all
-* ~ B K ( y r , q) -* K
10.3.
nectivity
q
to
E
where
it rep-
q+l" Finally
as
dr[t_
then
can be factored
are at least A -maps. n
u ~ Hq(x;~r), then
r + 1 < ¢L+2 -- p+l
that higher
El+r, q- r+l r
u
for
"
differentials
and
u = ~v
vanish
for con-
l+r, q=H ~ E1 r+l q-r+l
r+l
~X)
< (r+l)p. are well known.
10.4.
~ : H q + l (Y;~r) -* H q ( ~ Y ; ~ r )
is onto for
10.5.
~ : H q + l ( y ; l r ) -* H q ( ~ Y ; l r )
maps
q < 2p
where
Y
is p-
connected. Corollary q < 3p
where
Y
is p-connected.
We write "loop class"
greater these
~
rather
(Corollary than
a
content than the over-worked corollaries
yield Corollaries
9.10 is now established.
and refer
rather than as a " s u s p e n s i o n "
onto the primitive
to a class
subspace )
in the image
as a
as w e prefer terminology of
"suspension".
Applied
9. 9 - 1 0 of t h e l a s t c h a p t e r .
to k - i n v a r i a n t s ,
for
46
For class
Y = K(G,n),
it so happens that primitive
implies being a loop
if w = Z , b u t t h i s i s n o t t r u e in g e n e r a l . P
Example
10. 6. [ S t a s h e f f ] . --
a loop class.
In f a c t
Let
~ ~ 0 { HZn(z
d2(~P) ~ 0, s o
, 2n-1;Z).
p
~P
~P is n o t r e p r e s e n t e d
is p r i m i t i v e
but not
by ahomotopy
associ-
ative map. To obtain examples ferent
of m a p s w i t h
d
r
~ 0 for
r > 2, w e h a v e t w o d i f -
sources.
Example
10.7.
An-map
A non-zero
class
a
in
H2n(~cP(n))
is r e p r e s e n t e d
by an
b u t n o t b y a n A n + l - m a P. The class
cannot be a loop class
since
H2n+l(cP(n))
= 0.
Recalling
that ~CP(n) ~ S 1 X ~ S zn+l, the only possible'non-zero differential is d lot] = k[ul.., lu] where n
u ¢ HI(~cP(n)).
It follows that S I-~ COP(n)
is not an
An+l-mapE x a m p l e I0.8. [Zabrodsky]. _
Let X ~ K(Z --
, 2n-l) )< K(Z p
ative multiplication obtained as the loops on the space so that B x ~ Y. Ap_l-map,
The class
, Znp-g) have the associP
u = ~ 2np-Z c HZnP'Z(X;Zp)
Y
with k-invariant
(~ Zn )P,
is represented by an
not an A p - m a p . B y comparing the spectral sequence with that of the product structure
on K(Z
, gn-l) X K(Z P
, 2-np-Z) w e see the only w a y the class
(L Zn )P =
P
it Zn_ll... [~ gn_l ] can be killed is by E x a m p l e I0. 9. [Zabrodsky]. and k-invariant ~ l WZp_z(Y)
restricts to ~ p - 2 in K ~
and
k-invariant ~ l
= 0, there is a class
2p-3
to ~ P - 2 L 4p-6"
be the space with
WZp- 3
Now
u
4p-5"
~Y
where
2p-2 + k(L 2p-2 )2 for any
u c H2P(P'I)-3(X)
(We have -~p-2~pl
k ~ Z p"
which restricts
is not a loop class since there is no class in Y
which
+ ks 2) = -2s P + k z ~ P P - J ~ P J - Z ~
, 2p-2). ) B y the s a m e token, for k = 0, L P goes to P
W4p- 6 ~ Zp
Zp-3' which can be regarded as the loop space
w4 p_5(Y) ~ Zp
Since ]PP-Z~IL
Let X
dp_l[~ 2np_2].
zero
in Y
and
0
47
thus u
[~ I ' ' "
I t ] must
is the first
class
assasin.
Thus
Example
10.10.
u
be killed in the Eilenberg-Moore
in
X
which exists
is represented
[Gheng].
Let
for unstable
spectral
reasons,
by an Ap_l-rna pbut
Y be the space with
~
With respect
back to the fundamental
not an Azi-rna p.
class
is represented
Again
be the
k-invari-
" 2 u ~ H z l - (f~Y) w h i c h p u l l s
a class
K(Zz, zi-z)
must
w2 = w 2 i _ l = Z 2 a n d
to loop multiplication, of
u
Since
not by an Ap-map.
2 i+l ant
sequence.
by an A . -map but 21_i
u kills [~ ii... IL i] in the spectral sequence.
For
i=g,
v ~ H 7 {Y) w h i c h restricts to S g S IL is represented by an A ) - m a p q q 7
the class
but not an A4-rna p for any A4-structure on
Y.
It is possible to give chain formula for using a spectral sequence is to avoid such work.
d , although a m a j o r point of r T h e case
d g is quite m a n a g e -
able and illuminating in t e r m s of our next topic. If
dl[U ] = 0, t h e n
any representative Gq'l{x~:
X;w).
u ~ -For
u
u
we have
any choice
c = (1 × m ) ~F b - {m × 1)~
is primitive.
b
- w1 ~ -u - w/ u
m~
of b , t h e c o m p o n e n t
represents
by a coboundary
On the chain level,
dg[u].
u, w e a l t e r
b
a n d if w e a l t e r
we alter
c
by
dg[u ] is
[(1 X m ) * - ( m X 1)*] H q ' l ( x ~ x ; w )
[(1 X m ) ~: - ( m X 1 ~ ]
= 5b{u)
in
this means
where
our choice
of a c o c y c l e .
b •
G q - l { x ~b X ~ - X ; w )
Notice by altering of b
of
our choice
for a given
of u,
Thus the indeterminacy
which is
dl(Hq-l(x
for
~=X;w))
in
just as
it should be. Example
10. 6 i s w o r k e d
In C h a p t e r sented
by H-maps.
associative
out this way in [Stasheff].
8 we saw that the k-invariants
Similarly
of an H-space
one can show the k-invariants
H - s p a c e are r e p r e s e n t e d
by A3-rnaps,
are repre-
of a h o m o t o p y
so e x a m p l e s I0. 6 and 10. 8
and I0. 9 for p = 3 provide e x a m p l e s of H - s p a c e s w h i c h are not h o m o t o p y associative.
In order
associativity
to generalize
more
fully from
these
results
our homotopy
to A -maps n
we need to study
p o i n t of v i e w .
A
-SPACES n
We h a v e s e e n t h a t t h e e x i s t e n c e H-space
is e q u i v a l e n t to h o m o t o p y a s s o c i a t i v i t y ;
significance
of p r o j e c t i v e
induced by A3-maps natural
of a p r o j e c t i v e
n-space.
In b o t h c a s e s w e a r e l e d to c o n s i d e r
invariant
for an
to i n q u i r e a s to t h e
On the other hand, we have seen that fibrings
to a s k a b o u t t h e s i g n i f i c a n c e
homotopy
it is n a t u r a l
admit homotop7 associative
equation but as a conjery
three-space
again,
it i s
of a f i b r a t i o n b e i n g i n d u c e d b y a n A - m a p . n the associative
of n - v a r i a b l e
characterization
multiplications;
equations.
of s p a c e s
law not as a three variable T h i s in t u r n l e a d s to a
of t h e h o m o t o p y t y p e of a s s o c i a t i v e
H-spaces. Consider determine
five maps
a single application topy as a map
the various
w a y s of a s s o c i a t i n g
of X 4
X, e a c h of w h i c h is h o m o t o p i c
into
of h o m o t o p y a s s o c i a t i v i t y .
h : I-~ X X3, we can construct
Regarding a map
S1 as a pentagon with the five maps as vertices
If t h i s m a p c a n b e e x t e n d e d to a t w o c e l l of p r o j e c t i v e case for
~Ix,
the associating
spaces
four factors.
These
to t w o o t h e r s b y
the associating
homo-
S 1-* X X 4 b y r e p r e s e n t i n g
and the five homotopies
as edges.
,iwx e 2 with boundary
can be extended one stage further.
t h e s p a c e of l o o p s p a r a m e t e r i z e d homotopy can be represented
S 1, t h e c o n s t r u c t i o n
T h i s i s of c o u r s e
by the unit interval.
schematically
by
the
In ~ I x ,
49
s o t h e m a p of
S1 we are looking at is represented
which can be extended to
e 2 by deforming
by
all paths to
(wx) (yz)
in the obvious
way.
To proceed volving maps morphic
to
m.
1
K 2 = ~.
(K r × K s ) k
K . X X i -~ X
:
1
where
w e n e e d a f a m i l y of c o n d i t i o n s
K.
is a s p e c i a l
1
in-
cell complex borneo-
Ii-2.
D e f i n i t i o n U . 1. Let
with this approach
K. d e n o t e s a c o m p l e x 1
Let of
K. = C L . , 1
1
(Kr × K s )
symbols,
e.g.,1
Z ...
responds
to i n s e r t i n g
constructed
t h e c o n e on
L.
(k k + l . . . two pairs
w h i c h i s t h e u n i o n of v a r i o u s
1
corresponding
inductively as follows:
to inserting
k+s-1) ...
i.
of p a r e n t h e s e s
a p a i r of p a r e n t h e s e s
The intersection with no overlap
copies in
of c o p i e s c o r or with one as a
subset of the other: I ...
(k...k+s-l)
...
I...
(k... (j...j+t-l)
(j...j+t-l)
...
r
× K
s
-~ K.
1
(An a l t e r n a t i v e
sense,
is t h e i n c l u s i o n of the c o p y i n d e x e d by indexing by trees
i
k+s+t-Z) ...
Thus the foUowing definition makes K
...
or i.
where
a k ( r , s) :
I . . . (k... k+s-1) . ..
i s g i v e n a t t h e e n d of t h i s c h a p t e r . )
i.
i
50
Definition maps
11.2.
An An-space
(X;{Mi})
M . : K. X X . - ~ X , i < n
x i) = M r (p, x [ . . . . .
M.
exist and satisfy
and a family
of
M s (or, x k . . . .
Xk+ s _ l ) . . . . .
xi)
p ~ K , ~ c K . r
If t h e
X
with unit and
M i ( ~ k ( r , s) (p, a ) , x I . . . . . for
of a s p a c e
such that
1) M 2 i s a m u l t i p l i c a t i o n 2)
consists
these
S
conditions
for all
i > 2, w e s p e a k
of
{X, { M i } )
1
as anAl-space.
Where
Conditions
necessary,
we refer
approximating
The complexes
K.
to the
these were
{Mi}
as an An-fOrm.
first presented
a r e a l s o of i m p o r t a n c e
in [Sugawara].
in category
theory
in
1
relation
to coherence
morphic
to
exhibited
Ii-2
the
of f u n c t o r s
is not obvious.
K.
1
as specific
[MacLane]. Several
That the complexes
are homeo-
ways to see it are available.
convex subsets
of
Ii-2
which are
clearly
I have homeo-
K3 morphic
to the whole cube,
e.g. ,
K2 = *
~0
1~2
/"
1
/
K4
\ Adams
has computed
the homology
and fundamental
group
of
L.
and
1
thus shown
L. f o r 1
i>
shown the cell complex Z~i - 2 .
[Boardman]
5 has the homotopy
t y p e of a s p h e r e .
L . i s t h e d u a l of a c e r t a i n z
has given a cubical
decomposition
subdivision of
K. 1
idea first
suggested
by Adams.
Stallings
has
of the boundary
indexed by trees,
of an
51
Associative fined to have constant
H-spaces value
are
of c o u r s e
Before
description
proving
this,
-spaces
o0
since
M.
can be de-
1
x 1. . . x i.
T h e m a i n p o i n t of t h e d e f i n i t i o n invariant
A
of A
CO
of a s p a c e
of t h e h o m o t o p y
we present
the main theorem
-space
is that it is a homotopy
t y p e of a n a s s o c i a t i v e about A -spaces,
H-space. which is
n
w,h a t o n e s h o u l d e x p e c t . Theorem
11.3.
A connected
CW
admits
X
the structure
of a n A - s p a c e
if a n d
n
only if there
exists
a sequence
of quasLfibrations
E 0 =X-*
1-*
,., with
E.1 c o n t r a c t i b l e
in
En_ 1
. . .
B I-~ ...
Bn_ 1
E i + 1.
The construction
is not iterative,
En
although
En_l~
be
~
inductive.
We let
Kn+ z X X n+l
n
Pn Bn
Bn_l~
Kn+ z X X n n
The attaching ~n{0k(r' s)(P'c)'Xl with the
M
term
s
.....
map for
if
the first
x
factor,
. M. s (. ~ ' X. k . . . .X k. +.s -.1 ). .
k + s - 1 = n + 2.
x
coordinate
By induction we prove first
is given by
n
Xn+l) = ~ r ( P ' X l ' .
deleted
obtained by dropping
E
Pn'
is a quasifibration.
The attaching
map for
B
n
is
consistently.
induced by projection
This
Xn+l)
time
we break
onto all but the
B
into two
over-
n
lapping pieces
by considering
1
crucial
condition
weak homotopy one
onto
in proving
equivalence
and breaking
K. = CL.
Pn
is a quasifibration
occurs
as the fibre
~ -~ ~
occurs
over
over
(~,x_ .....
x ) where n
L..
This map
can be identified with mapping
1
up a cone as before.
The
1
in showing that a
(T,x z .....
is a deformation x
Xn )
is mapped
of a n e i g h b o r h o o d into
x
by
of
to L. 1
52
x-~ M r(p,x,x 2 ..... M
r
(p,x,e .....
e)
As for the limit, Theorem o n l y if
l l . 4. X
Xn) since
for fixed X
p
and
is c o n n e c t e d ,
the arguments A connected
X
admits
the structure
admitting
an associative
before,
an A
00
for some
invariant
multiplication
is not.
associating
if a n d
a s o p p o s e d to
We h a v e m a d e t h i s l a t t e r
follow.
quasifibrations
Thus
multiplicative
as in T h e o r e m
S3 with these particular
the unit. A d a m s
has given m e
-form.
remark
on
S3
chosen
Actually he works by
exotic multiplications
cannot be deformed
T h e p r o o f of T h e o r e m
o0
11. 3 f r o m w h i c h t h e A
h o m o t o p y t y p e of an a s s o c i a t i v e
these multiplications
of m u l t i p l i c a t i o n s
[Slifker] shows that a properly
h o m o t o p y c a n b e e x t e n d e d to a n A
constructing
H-space
=o
-forms
has the homotopy
t h o u g h on t h e s t a n d a r d
to be a s s o c i a t i v e .
11. 4 w h i c h i s i m p l i e d b y o u r e x p o s i t i o n u s e s
an alternative proof of a stronger result w h i c h
no use of units.
Theorem {Mi} ~
-space
b u t l e t us e x p a n d on it now.
only eight are homotopy associative.
makes
00
is a homotopy invariant while
R e c a l l t h a t of t h e t w e l v e h o m o t o p y c l a s s e s
S3
of a n A
case.
Y.
statement
-structure
to
to t h e i d e n t i t y .
t o t h o s e in t h e a s s o c i a t i v e
CW
since admitting
and hence homotopic
similar
N o t i c e t h i s is a h o m o t o p y 4.3,
T h i s in t u r n i s h o m o t o p i c
are
h a s t h e h o m o t o p y t y p e of ~ Y
Theorem
x..1
II. 5. {Adams). satisfying
If X
admits a m a p
2) of II. 2, then X
with an associative multiplication n
M z : X X X-~ X
and a family
is a deformation retract of a space
such that n IX X X
is h o m o t o p i c in Y
Y to
m. T h e proof has b e e n simplified by [Boardman]. while for A
n
-spaces with n
Definition U. 6. Bn_iVKn+
defer the proof
finite, w e again look at projective spaces.
If (X, { M i } ) is an A
Z X Xn
We
n
-space, XP(n)
constructed in proving T h e o r e m
will denote the space
II. 4.
53
Theorem
Ii. 7.
If Y
is a M o o r e
space of type
(G, Zp+l) w h e r e
abelian group in w h i c h division is possible for all p r i m e s prime
p, t h e n
Y admits
The maps
the structure
M.
for
i< p
of a n A p . l - s p a c e
are constructed
G
is an
q less than the b u t n o t of a n A p - s p a c e .
a s in t h e c a s e
p = 5
1
(Example M
P
7.6) by deforming
t h e t r i v i a l o n e s in ~ 2 ~ Z y .
follows from the decomposability
p-fold cup products
in
YP(p)
of ~ p + l
The nonexistence
contrasted
of
with the non-trivial
if i t w e r e to e x i s t .
Given two A n - s p a c e s ,
w e can again consider m a p s
which respect the
structure. Definition II. 8.
If (X;(Mi})
a homomorphism
if
and
(Y, {Ni})
are A n - S p a c e s ,
a map
f : X -~ Y
f M i (7, x 1 ..... xi) = N i (~, fx I..... fx.1)" It is also possible to consider m a p s
of A
-spaces which respect the n
structure
up to homotopy,
pletely here.
but the details are too complicated
F o r example,
to m e n t i o n
respecting a n associating h o m o t o p y
corn-
involves a 2-
cell subdivided as a hexagon, while respecting an A4-structure involves a c o m plex w h i c h looks like
7ill
z_&L
k\ \
is
54
However,
maps
of an A
n
-space into an associative H - s p a c e
or vice v e r s a are
manage able. Definition A map
U . 9.
Let
f : X -~ Y
(X, { M i } ) b e a n A n - s p a c e
is an A -map
if t h e r e
exists
and
Y
an associative
a family
H-space.
of m a p s
n
h i:
Ki+ 1 × X i-~ Y
such that
h 1 = f and h i (Ok ( r , s ) ( p , a ) ,
x 1. . . . .
= h r ( 9 , x 1. . . . .
x .1) =
Ms(a,x k .....
= h r _ l ( p , x 1. . . . .
Xk+s.1) .....
X r . 1 ) h s _ 1 (¢r, X r . . . . .
It is easy to see that an A -map
xi)
x,)l
of a s s o c i a t i v e
for
for
r + s = i+2 k < r
k = r.
H-spaces
is an A -map
n
sense
with respect
Theorem
11.10.
to the trivial If
(X;{Mi})
higher
homotopies
is an An-space,
The proof is a generalization h i : Ki+ 1 X X i-~ ~XP(n)
then
X -~ ~ X P ( n )
conveniently
by defining some
cO
-form.
is an An-map.
8.6.
The maps
in terms
of
reasonable
homeomorphisms
K i + 2. M a n y of o u r r e m a r k s
associative H - s p a c e s
Theorem
used as the A
of t h a t of T h e o r e m
can be described
K i + 1 × X i × I "*- K i + 2 × X i ' * X P ( i ) Ki+ 1 X I~
in this
n
11.11.
X
about H-maps
c a r r y over to A
admits
n
-maps
of H - s p a c e
in this m o r e
and A -maps n
of
general sense.
of a n A - s p a c e if a n d o n l y if e a c h s t a g e
the structure
n
of a n y P o s t n i k o v
system
for
homomorphisms
and the k- invariants
Corollary ll. lZ. (cf. 9. I0). space provided
X
does in such a way that the projections are represented
An An_l-space
~.(X) = 0 for
i< p
and
X
Pn
are
by An-maps.
has the h o m o t o p y
type of a loop
i > np+n-4.
I
Example
11.12.
class
of ExampIe
u
Let
W be the space 10.8
or
constructed
10. 9, t h e n
W
by using as k-invariant
admits
an Ap_i-form
the
but not an
A -form. P These
examples
used the bar
construction
spectral
sequence.
More
55
generally,
for an A -space
X
we have the spectral
sequence
derived
from
the
n
finite filtration Theorem
of
11.14.
XP(n) Let
by
XP(i),
i < n.
(X, { M i ) ) b e a n A - s p a c e
and
u e Hq(x;Tr).
Then
n
If
3)
u
is represented
holds for
1)
d
2)
Su
r
[u] = 0 f o r
r < i
pulls back to
by an A.-map
then
1
i f a n d o n l y if
XP(i)
1) a n d
2)
follow.
The converse
i < n.
The converse know to prove
~XP(i)
is stated
-* X
in this limited
is an A.-map
way because
is to use
the only way I
XP(i+I).
1
Our analysis
of A - m a p s
in terms
of c o h o m o l o g y
classes
also applies
n
to the maps
inducing the succession
Zabrodsky'
s technique.
Zabrodsky's
method
of f i b r a t i o n s
used to construct
T h u s w e f i n d if t h e i n g r e d i e n t s
are A -spaces
and maps,
first
the result
is anA
used the technique
to construct
a homotopy
b u t n o t of t h e h o m o t o p y
sky].
was not an A5-space.
Example
the example
11.15.
Let
P1 = {2,3),
That the resulting
X
~ 1 : H3 ( X z ; Z 5 ) -~ s l l ( X z ; Z 5 ) essentially A3-space marks,
the same if
G
the example
not A -spaces P
is trivial.
can he adapted
several
i d e a of i n d e x i n g b y p l a n a r in the plane,
H-space
t y p e of a l o o p s p a c e
[Zabrod-
follows from Xz
is an A3-space
Adams
divisible
by
the fact that
to show
Z and
3.
to give finite complexes
follows from
Y(G;Zn+I)
is an
As Zabrodsky
re-
which are Ap_ 1 but
p.
Boardman' are
associative
X 2 = (S 3 × S 5 X S 7 × S 9 × s l l ) ( P 2 ) .
That
used by Frank
of r a t i o n a l s
for any prime
There
X 1 = SU(5),
is not an A5-space
argument
consists
-space. n
which was a finite complex In fact,
in
to be mixed by
n
Zabrodsky
X(]t~ 1)
s Proof clever
trees,
so as to keep track
of T h e o r e m
ideas
11. 5.
in the proof.
i.e. , directed
connected
of w a y s of i n s e r t i n g
First, acyclic
parentheses.
there
is Adam's
finite graphs For
example,
56
w{(xy)z)
corresponds Second,
an associative
to t h e t r e e there
operation
m ( m × 1) = m(1 X m )
D e f i n i t i o n 11.16.
~
o
is an idea from categorical not by a multiplication
algebra
of c h a r a c t e r i z i n g
m : X × X -* Y
and a relation
but as follows:
An A-structure
on a s p a c e
X
i s a f a m i l y of c o n t i n u o u s m a p s
n
{k i : X i - ~ X , i > 2} Usually, The other trees
k.
1
s u c h t h a t if k
i
~ m. = m then k o(vk ) = k . 1 n rn. m 1 1 is t o b e t h o u g h t of a s t h e m u l t i v a r i a b l e m a p
can be indexed by the trees
can be obtained by composites The complex
where
T
K.
1
is a tree with
without disconnecting
n
the tree).
For
-//
m
.
and all the
of t h e s e .
will now be represented
branches
edge is subdivided needlessly.
~kk
x 1. . . x
a s a u n i o n of c u b e s
C(T)
(= i n p u t s = e d g e s w h i c h c a n b e r e m o v e d our present
The cube
C(T)
purposes
we will assume
will have parameters
no
indexed by
t h e e d g e s of t h e t r e e w h i c h a r e n o t b r a n c h e s .
Definition II. 17.
WA
with n-branches.
(n, I) is the union with identifications of C(T) over all trees
T h e identifications are that a face
t. = 0
of
C(T)
is to be
1
identified with edge indexing
C(T' ) w h e r e
T'
is obtained f r o m
t.. 1
F o r example, WA(Z,I) =
=
C(V)
W A ( 3 , 1) = ~ ( ~ / ) G ( ~ )
G(h) ~)
T
b y shrinking to 0 the
57
It c a n b e s h o w n t h a t Definition
U. 18.
A
WA(n,1)
WA-structure
on
is a cubical
X
is an A
subdivision
-structure
of
K . n
without units,
i.e. ,
~C
a family
of maps
l~l : W A ( n , 1 ) × X n - ~ X n
Mn(~, x I .....
x n) = lVir (p, x 1 . . . . .
if ~ = (tI ..... tn_Z)
•
C(T)
with
such that
Xk_ 1, M s (c;, x k . . . . .
t. = 0 w h e r e ,
Xk+ s) . . . . .
x n)
if the e d g e indexing
t. is
1
deleted, same
T
as
decomposes
T' [J T "
values to the c o r r e s p o n d i n g
1
while
p e C(T' ), a e C ( T " )
e d g e s as does
7.
T h e f i n a l i d e a of t h e p r o o f i s to u s e t h e nective
tissue
to build something
like a tensor
associate the
WA(n,1)
algebra
complexes
of w h i c h
X
as con-
will be a
retract. First
we let
that now we permit
For
example,
description as
WA(n,1)
trees
WA(Z,I)
be the complex
with an extended
= C(y) = ;
root,
: and
constructed
except
i.e. , "'~'"
WA(n,I)
gives a useful parameterization.
as before
= WA(n,l)
We also let
× I but the tree
WA(1,1) ~ •
regarded
C(1).
Definition MX
If. 19.
Given a
is defined by taking
(T,x I..... • ,p,a
x n)
with
(~)
WA-structure WA(n,1) × Xn (p,x I .....
on
X, the associated
for each
n
Xk_l, Ms(~,x k .....
associative
space
and identifying Xk+s_l) .....
x n)
where
are as above. If
t. = 0
on the edge corresponding
to the extended
root,
then
(•)
1
means
Mn(t I .....
~i .....
The operation
t k - l ' Xl . . . . . on
MX
= ((p,a),x I ..... regarded
as being in
tive involves combinatories
essentially
only the
aptly called tree
is given by
Xr+ s)
C ( T 1 v TZ).
Xn)"
where
(p,x I .....
now for
That the operation WA-parameters,
surgery.
x r ) • (a, X r + I . . . . .
p c C(TI),
ae
X r + s)
C(Tz), (p,a)
is well defined and associaan exercise
in parameterized
is
MASSEY PRODUCTS The differentials were
usefu~ in analyzing
the homology
spectral
AND GENERALIZED in the cohomology
k - invariants
sequence,
BAR (31)NSTRUCTION
Eilenberg-Moore
in terms
of
spectral
A -maps. n
we have in particular
sequence
If we turn to
differentials
of the form
dr[all .. l Ur+ l] represented These
by homology
are closely
ucts originally introduced,
related
of t h e a s s o c i a t i v e
to the Pontrjagin
defined in the cohomology
these homology
the duality; however, algebra,
classes
products
Massey'
ring analogues of a n a r b i t r a r y
were
s procedure
so we will use the term
"Massey
should now expect,
strict
homotopy
we save such generality
analogue;
associativity
As for the differentials
H-space
called
in question.
of t h e [ M a s s e ~ p r o d space.
Yessam
When first
products
product"
generically.
as one
by an appropriate
f o r t h e e n d of t h i s c h a p t e r .
more
generally,
it turns
products
out [ May]
by appropriate
Massey
allow matrices
classes
than single homology
rather
differential
In fact,
that they are all determined of h o m o l o g y
to emphasize
is valid in any associative
can be replaced
dr
X
if w e a r e w i l l i n g t o classes
as
arguments. Until further
notice,
with differential
d.
Definition
Let. u,v,w
product
12.1.
~
Remark.
If defined,
has the larger remarks higher
where
.
u
E H(A)
.
indeterminacy
Massey
be an associative s original
such that
of H ( A )
represents
like this continue order
A
We start with Massey'
is the coset
B
ux(.1)deg u
let
by
uH(A) + H(A)w
.
.
[Uehara
.
triple
by
dy = uv.
Notice that
d2[ulvlw]
this situation,
The differentials are usually
and Massey]-
The Massey
As we generalize
but the latter
algebra
determined
dx = vw,
d2[ulvlw]
represents
to be applicable.
products,
product
uv = 0 = vw.
u, e t c . , a n d
H(A). H(A).
differential
more
are determined delicate,
less
by
60
often defined and with s m a l l e r i n d e t e r m i n a c y .
choice, for of course
T h u s in g e n e r a l i z i n g we h a v e s o m e
d r [ . 1 1 . . , l ur+ 1] can itself be regarded as a generalization.
We w i s h to d e f i n e h i g h e r o r d e r M a s s e y p r o d u c t s < u l. . . . . , u i + s >
a r e defined and z e r o for
l<_i
and
s < r-1.
< u 1. . . . .
Ur> w h e r e
[May] h a s
d e v e l o p e d the f o l l o w i n g n o t a t i o n .
D e f i n i t i o n 12.2.
aij ~ A
The M a s s e y p r o d u c t < a 1. . . . , a t >
for l<_i_< j<_r
excluding the case
is d e f i n e d if t h e r e e x i s t
ij = ir such that a..11 represents
a. ~ H(A) a n d 1
daij = /i) k=i where
aik ak+l. J
aik has signs altered appropriately.
The M a s s e y p r o d u c t < a 1. . . . .
ar>
is the set of all homology classes represented by r-I 1
a_ik a k ÷ l r
for a n y s u c h s y s t e m .
T h e o r e m 12.3.
represent
If < a 1, . . . , a r > is d e f i n e d , t h e n a n y of its r e p r e s e n t a t i v e s
dr'l[all...
]ar].
The p r o o f is s t r a i g h t f o r w a r d , though t e d i o u s .
The d e f i n i n g s y s t e m
aij is used directly to show d s [all " ' " l a r ] = 0 for s < r - 1 a n d to o b t a i n a representative
X i n B'{A) of
[ a l l . . . J a r ] , w h i c h is a c y c l e u n d e r the t o t a l
d i f f e r e n t i a l in B(A).
E x a m p l e lZ. 4.
In H . ( ~ C
P ( n ) ) , if u g e n e r a t e s
Hi, t h e n < u , . ~ n+l
generates
HZn.
S i n c e n - f o l d M a s s e y o p e r a t i o n s a r e e a s i l y s e e n to be n a t u r a l
w i t h r e s p e c t to A - m a p s , t h i s a g a i n shows n
S1-~ ~ C
P(u)
i s - n o t a n A n + l - m a p.
61
T h e c o m p u t a t i o n m a y be done by o b s e r v i n g
H2n+I(CP{n)) = 0 w h i c h c a n b e
a c h i e v e d o n l y if the g e n e r a t o r of H Z n ( ~ C P(n)) The m a t r i c M a s s e y product,
is k i l l e d by
dn.
i n t r o d u c e d b y M a y , is a f a i r l y
s t r a i g h t f o r w a r d g e n e r a l i z a t i o n in w h i c h
a.
V..
is r e p l a c e d by a m a t r i x
l
obtain a reasonable definition, certain conventions about matrices
To
1
will be
observed. If V is a m a t r i x
(v..), t h e n ~
w i l l b e the m a t r i x
((-I) l + d e g v i i v . . ) .
U
An o r d e r e d p a i r of m a t r i c e s n × q and for each
i,j,
matric Massay product Vn
is
q × 1 and
U
(X,Y)
is m u l t i p l i c a b l e if X is
deg Xik + deg Ykj
is c o n s t a n t
for
m × n
and
1 < k < n.
The
V > w i l l be c o n s i d e r e d only if V 1 is n
V 1 . . . V . , j V j+ 1 . . .
Vk
is m u l t i p l i a b l e f o r e a c h
G i v e n the a b o v e c o n v e n t i o n s , D e f i n i t i o n 12. g c a r r i e s d e f i n e the m a t r i c M a s s e y p r o d u c t
"
Y is
1 × P,
j , k _ < n. o v e r v e r b a t i m to
T h e i n d e t e r m i n a c y is the s e t
of a l l p o s s i b l e d i f f e r e n c e s c o r r e s p o n d i n g to d i f f e r e n t c h o i c e s of t h e s y s t e m
A... U
M a y (in p a r t f o l l o w i n g [ K r a i n e s ] ) g i v e s b o u n d s on the i n d e t e r m i n a c y , linearity formulas,
associativity formulas,
Massey products, permutation rules. As b e f o r e ,
" s l i d e " r u l e s and for o r d i n a r y
He a l s o d i s c u s s e s n a t u r a l i t y .
t h e s e M a s s e y p r o d u c t s c a n b e r e l a t e d to the d i f f e r e n t i a l s
in the s p e c t r a l s e q u e n c e .
Matric products are particularly relevant when
dr
is
d e f i n e d on a c o m b i n a t i o n of t e r m s w i t h o u t b e i n g d e f i n e d on the i n d i v i d u a l t e r m s . F i n a l l y M a y s h o w s t h a t m a t r i c M a s s e y p r o d u c t s d e t e r m i n e the s p e c t r a l s e q u e n c e in t h e f o l l o w i n g s e n s e : such that for each element
x
if x
d x P
s u r v i v e s to
<W 0 . . . . .
E , then P
Wp_I,V>.
all
q there are matrices
of E p ' q t h e r e is a c o l u m n m a t r i x is r e p r e s e n t e d
The differentials
of p a r t i a l d e f i n i n g s y s t e m s f o r
For each
drX f o r
<W0 . . . .
x ; on the o t h e r h a n d , t h e y a r e h u g e .
'
W
p-l'
V
such that
by a suitable r e p r e s e n t a t i v e r <_p V>.
W.
of
c a n b e e v a l u a t e d in t e r m s
N o t e t h a t the
W.
i
work for
62
Of course
A -spaces
can be mimiced
on t h e c h a i n l e v e l ,
just as
n
associative
differential
algebras
Definition 12.5 [Stasheff]:
mimic
topological monoids.
( A , m . , 1 < i < n)
is a n A - a l g e b r a
1
--
if m . : A x -* A
n
i
such that 0 = T
(-I)
m r {l@. . . @ m s @ ' ' ' @ I )
k,s
k-1 where for
al@[email protected]
the
(s+l)k + s (i + ~
~ is
d i m a.) 2
/
I
m 1 p l a y s t h e r o l e of d i f f e r e n t i a l . )
(Note:
For an A
-algebra,
there
is a g e n e r a l i z a t i o n
of t h e b a r c o n s t r u c t i o n .
00
Given an A
Definition 12.6 [Stasheff]:
-algebra
(A,m.),
o0
B'(A)
is
@ i=0
A i with the differential
~[all-.-lanl : where
the tilde construction
1
(-1)x [all... [ms(ak®...®%+s_l)l'-" I%1.
k-1 )~ = (s+l)(k+l) + s(i + >
dim aj).
1 A l l of o u r m a c h i n e r y and Massey
products,
is d e f i n e d b y Finally,
connected
C QC P q
uy+xw+_m3(u,v,w)
differential (1~)
Let
including the spectral
for
coalgebra,
JC = C/A
~
Let
x e C
P
For example,
Let
~
P,
and define
E@...®C
n>O ~ --
be a simply
graded,
denote the component
> 0 that
•
(C, ~)
i . e . , if p o s i t i v e l y
%, q
7-Cp
~(C) = T(~) =
sequence
[Stasheff].
the dual situation.
= (&®l)~.
and we shall assume
£~0, p(X) = x@l.
over,
albeit with additional complication.
l e t us c o n s i d e r
associative
C O = A, C 1 = 0 and
carries
n
o(X) = l ~ x
and
of
~
in
63
with
@c = - d c =~'---- (-l)P A
Z__
p,n-q
c for c e C
and e x t e n d m u l t i p l i c a t i v e l y to
n
l
r e g a r d e d as the f r e e a s s o c i a t i v e a l g e b r a g e n e r a t e d by ~ . [Adams] shows
H,(~(C~(X))
is isomorphic to H,(~X)
b u t the p r o o f is a t o u r de f o r c e u s i n g s i m p l i c i a l c h a i n s f o r
as an algebra,
X and c u b i c a l c h a i n s
for f~X. Following a suggestion of Peter May, w e outline a proof which follows m o r e n a t u r a l l y f r o m the p o i n t of v i e w we h a v e e s t a b l i s h e d .
w
T h e o r e m 12.7.
Proof.
T h e r e is an
shin
equivalence
~ C , ( X ) ~--~ C , ( ~ X ) .
We w i l l c o n s t r u c t m u l t i p l i c a t i v e e q u i v a l e n c e s .
B C, (X) ~-~ C, (Bf~X) -- ~ B C , (~X) -~ C, (f~X) The left hand m a p is induced by the h o m o t o p y equivalence multiplicative by naturality of ~ . the standard inclusion
B~X-~
B
and is
The s a m e applies to the middle m a p which is
BC~(Y) -~ C$(BY).
The fact that ~ B
is naturally
equivalent to the identity via shin m a p s should be a basic bit of general nonsense in the appropriate category; at present only a laboriously detailed proof is conceivable. Since ~ B A construct
: BA-~ A
homotopy equivalence.
is the f r e e a s s o c i a t i v e a l g e b r a on B'A, it is e n o u g h to s u c h t h a t its m u l t i p l i c a t i v e e x t e n s i o n We d e f i n e [a] = a = 0 on
A n inverse for given by L
and @ A ®n . n>l
is the obvious (but not multiplicative m a p
L(a) = [a] for which
_~ I ~ A
:~] B A -~ A is a
L = IA.
i : A-~BA
The details of the h o m o t o p y
are given in [Halperin and Stasheff].
It is worth remarking that if A
modules are of finite type then letting
64
(
)
denote
Horn(
, A ) we h a v e 8 ( A )
= (B'A) .
Thus
H~,(~X)
can be
c a l c u l a t e d a s t h e h o m o l o g y of [BC ~ (X)] ~. The spectral sequence derived from filtering n u m b e r of b a r s " h a s
E 1 = BH (X) a n d
(X) b y
E Z = T o r H * (X) (A, A).
a r e now g i v e n in t e r m s of M a s s e y p r o d u c t s w i t h Massey' s original
BC
dz[ul v]w]
The differentials
being represented
.
In general
B and ~
are too large for complete computation but
s p e c i f i c e x a m p l e s in l o w d i m e n s i o n s c a n o f t e n b e done n e a t l y in t e r m s m
"the
of B ~
m
o r ~]B, e . g . ,
Example I0.7.
I t i s t i m e we l e a v e a b s t r a c t d i f f e r e n t i a l a l g e b r a a n d r e t u r n to s o m e geometry.
by
HOMOTOPY We have analyzed view.
associativity
We could do the same
expressed length;
diagramatically.
other examples
X 3 -* X
commutativity
Every
{x,y,z)-~
direct
homotopic
to
An H-space
mT
where
The easiest H-space k + /a
homotopy =/~(s-t)
/~ + k
t<
s<
evaluation
on a space
is homotopy
Moufang.
of t h e o b s t r u c t i o n s .
I, a homotopy
on a sphere
is homotopy
disassociative,
commutativity.
{X, m )
is homotopy
commutative
~X
of a n H - s p a c e . to pointwise
{Here to have
if t
is determined
is
commutative
The point is that loop addition
/~ : [ O , r ] - ~ runs from
by
but homotopy
multiplication
t E I. ) F o r
if m
T{x,y) = yx.
of a n o n c o m m u t a t i v e
k-/~ t w h e r e
t+r.
but we could normalize izedby
example
is homotopic
is given by for
{x(yz))x
T : X × X-* X × X by
is the loop space or
M o u f a n g if t h e f o l l o w i n g
(xy)x.
We now turn to homotopy
13.4.
is homotopy
multiplication
multiplication
x(yx) ~
Definition
X
y = e, we also see
13.3.
we have
at some
{ x , y , z) -~ ( x y ) ( z x )
Every
The proof involves
i.e.,
p o i n t of
We will study homotopy
An H-space
13.2 [Norman].
Theorem
a homotopy
condition which can be
are homotopic:
Taking
from
for any other algebraic
and
Theorem
extensively
have also been handled.
Definition 13.1 [Norman]. maps
COMMUTATIVITY
~Ix
X 0
to
then q
of l o o p s v t (s) = *
where
consisting
12 × ~ X X ~ X - ~
X
k"
k./~ .
The
for
O< s<
[O,q]-~ X
of loops parametergiven by
t
66
(t, s, k,/~) -~ k(t)./~(s).
There
are very few examples
of finite dimensional
homotopy
commuta-
tive H-spaces.
Theorem
13.5 [Hubbuck].
If X
is a connected finite c o m p l e x and
h o m o t o p y c o m m u t a t i v e H - s p a c e , then torus
X
(X,m)
is a
has the h o m o t o p y type of a point or a
S 1 X ... X S I. H u b b u c k ' s proof involves applying c o m p l e x K - t h e o r y to the projective
plane
XP(2).
ways.
T h e h o m o t o p y c o m m u t a t i v i t y of m
H u b b u c k uses the existence of a m a p
is reflected in XP(2)
f : XP(Z) -~ XP(Z)
in two
such that there is
a homotopy commutative diagram S X - ~ SP(2)-~ S X / / S X
tT S X -~ X P (2) -~ S X ~ Z S X where
SX-~ SX
r e v e r s e s the p a r a m e t e r .
T h e ~ e is another reflection of h o m o t o p y c o m m u t a t i v i t y in X P (Z).
Theorem
13.6 [Stasheff].
SX × SX-~ XP(2) associative a map
If
(X, m )
which is the inclusion
and right translation
S X × S X -~ X P ( 2 ) Proof.
is homotopy
on each factor.
is a homotopy
implies
The obstruction
commutative,
the homotopy to extending
If
equivalence commutativity
there
(X,m)
is a map
is homotopy
the existence of m .
S X v S X -~ X P ( 2 )
to the
of s u c h
67
SX X SX
is a generalized
out explicitly,
one sees
a : X-* ~XP(2).
class
Whitehead
product
it is adjoint to
The obstruction
[Pl + P2 ] - [P2 + Pl ] and
Pl
in
[SX z, X P ( Z ) ] .
(a} + P2
to homotopy
(~) - P l
Writing
(a)-
commutativity
a, : iX 2,x]-* ix 2,axp(2)]
P2
in
the map
(~) w h e r e
iX Z,X] is the
takes the one ob-
struction to the other. Now, homotopy
if X
is h o m o t o p y associative and right translation is a
equivalence, w e have the retraction
r : ~ X P ( 2 ) -* X
and hence
a~
is a monomorphism.
Corollary
13.7.
~CP(3)
Proof.
is homotopy
We know
type of a w e d g e o s s p h e r e s . t o a l l of
~Clm(3) ~ S1 ~ ~S 7 so
S~CP(3)
has the homotopy
Thus for
to extend
SX v SX-~ XP(Z)
SX × SX
involves
obstructions
Now all Whitehead
products
in
we at least
have
CP(3)
S X × S X - * B X.
tivity since the obstruction
commutative.
X = ~CP(3),
a l l of w h i c h a r e are trivial
to zero
products.
[Barratt-James-Stein]
This is sufficient
is mapped
Whitehead
in
so
to imply homotopy
[XZ,~Bx]
commuta-
but the map is an
is omorphism. Note u
4
CP(3}
is not an H-space,
= 0 which is not a primitive
further. Since
The familiar f~CP(3)
maps
is homotopy
S I X ~ S 7-* ~ C P ( 3 )
relation.
is again an H - m a p .
ue
HZ(CP(3)}, we have
The discrepancy
S 1 -~ ~ C P ( 3 ) commutative
since for
and
is worth
~ S 7 -~ f ~ C P ( 3 )
considering
are H-maps.
it is not hard to show the product
Now
S 1 )< ~ S 7 ~
~(CP(o0) X S 7)
m
and hence is the loop space of an H - s p a c e so be an A
n
- m a p for s o m e
n.
S l X ~ S 7-* ~ C P ( 3 )
Indeed w e have seen
Higher homotopies related to h o m o t o p y
S I-* ~ C P ( 3 )
m u s t fail to
is not an
A 4 - m a p.
commutativity are of interest (cf.
[Kudo and Araki]) but, as w e shall see, the approximations
do not converge to
68
strict commutativity,
Definition 13.8.
w h i c h is b e t t e r s t u d i e d d i r e c t l y .
An H - s p a c e
(X,m)
is a b e l i a n if m
c o m m u t a t i v e and a s s o c i a t i v e with E x a m p l e s abound.
For each abelian group (v,n).
is
X, d e f i n e d as t h e l i m i t of x n ] ~ { n )
t i o n g r o u p a c t i n g by i n t e r c h a n g i n g c o o r d i n a t e s . t h e b a s e p o i n t and u n i t of SP °°{X).
~r a n d n a t u r a l n u m b e r
n,
S o m e w h a t m o r e g e n e r a l l y , for any
X we c a n c o n s t r u c t the a b e l i a n m o n o i d
p r o d u c t on
If m
u n i t , we s p e a k of an a b e l i a n m o n o i d .
t h e r e is an a b e l i a n m o n o i d of t y p e space
is c o m m u t a t i v e .
SP°°(X), t h e i n f i n i t e s y m m e t r i c where ~(n)
is the f u l l p e r m u t a -
T h e b a s e p o i n t of X b e c o m e s
A n y o t h e r p o i n t in S P °° {X) c a n be r e p r e -
n
sented as a f o r m a l sum
~
/
m(x.)x, 1
1
where
m{x.) 1
is a p o s i t i v e i n t e g e r and
x.
1
i=l i s n o t t h e b a s e p o i n t of X.
Ir.(SP °°{X)) is n a t u r a l l y i s o m o r p h i c to
T h e o r e m 13.9.
1
T h e p r o o f c o n s i s t s in verify~ing t h a t Eilenberg-Steenrod
C o r o l l a r ~ r 13.10.
Ir.(SP°°())
H.(X) 1
if X is
CW.
s a t i s f i e s the
1
axioms.
If X is a M o o r e s p a c e
Y(G,n), then
SP°°{X) h a s the
h o m o t o p y t y p e of K(G, n}.
T h e o r e m 13. iI.
A n a b e l i a n m o n o i d h a s the w e a k h o m o t o p y t y p e of a p r o d u c t of
Eilenberg-MacLane
Proof.
spaces
Let
i n d u c e s an i s o m o r p h i s m
[D__old a n d Thorn].
Y. = Y{H.{X), i). 1 1 in h o m o l o g y .
T h e r e is a m a p
Since
VY. -* X w h i c h i 1
X is an a b e l i a n m o n o i d , t h i s m a p
69
e x t e n d s to
SP°°(VYi)
or
T~SPC°(Yi)
s o a s to r e d u c e
an isomorphism
of h o m o t o p y
1
groups. Leaving aside associativity, ized by a retraction
S P 2 ( X ) -~ X.
e n o u g h to r u l e o u t m a n y s p a c e s multiplication
o n l y in t h e 2 - p r i m a r y
then
Here
strictly
a
of S P Z ( X )
[ e . g . ,if X = S n, t h e n
X
admits
is r i c h
an abelian
Adams
indicates that the obstruction
is e s s e n t i a l l y
If G
is a g r o u p of r a t i o n a l s
with even denominators,
is a n a b e l i a n H - s p a c e .
Associatlvity
illustrated
rood 2 structure
The
is c h a r a c t e r -
part.
13.12 [ A d a m s ] .
Y(G, Zn+l)
either
(X,m)
o n l y if n = 1].
On the other hand,
Theorem
an abelian H-space
and commutativit7
o r up t o h o m o t o p y .
There
can occur independently are
10 p o s s i b i l i t i e s
of e a c h o t h e r ,
to c o n s i d e r
in t h e f o l l o w i n g c h a r t .
and
c
na
ha
ea
nc
1
2
3
hc
4
5
6
ec
7
8
~ ~ / . /[u
abbreviate "associative " a n d c o m m u t a t i v e ,
"equivalent ,Ia n d "not h o m o t o p y " a n d T h e subdivision
9-10
h
e
and
n
abbreviate
stands for " h o m o t o p y but not equivalent".
refers to the alternatives:
9.
equivalent to an associative
multiplication a n d equivalent to a c o m m u t a t i v e
one but not simultaneously;
i0.
multiplication.
equivalent to an associative, c o m m u t a t i v e
means
via a n H - m a p
homotopy
same homotop7 type. indicates
X with
equivalence to a multiplication o n a s p a c e of the
[Adams] provides
~.
H e r e equivalent
the following examples;
killed above dimension
where
X[0, n]
n.
1
Theorem
as
13.13.
There
are examples
of t h e
10 t y p e s of H - s p a c e
above:
70
I.
S7
2.
S 7 w i t h c e r t a i n p - c o m p o n e n t s of lr. (S7) k i l l e d for
i > Zl
1
3.
Q u a t e r n i o n i c m u l t i p l i c a t i o n on S 3
4.
S 7 with the Z - c o m p o n e n t s of ~.(S 7) k i l l e d f o r
i > 14
1
5.
S 7 with c e r t a i n p - c o m p o n e n t s of ~. (S7) k i l l e d for
i > Zl and Z-components
1
k i l l e d for
i > 14
6.
s7
7.
AMoore
space
Y(Z[I/Z],7)
8.
A Moore
space
Y{Z[I/Z,I/3],5)
9.
Y(Z[1/ Z], 5)
10.
[o, lz]
[0,8]
S1 If X is a f i n i t e c o m p l e x , the s i t u a t i o n c h a n g e s r a d i c a l l y .
a r e p o s s i b l e only for
1, Z, 3, a n d 10, of w h i c h a l l b u t
Examples
Z are given above.
For
a n e x a m p l e is p r o v i d e d b y [ Z a b r o d s k y ] : the H - s p a c e w h i c h m o d 2 a n d 3 is SU(6) b u t m o d
a l l o t h e r p r i m e s is
S 3 X S 5 X S 7 X S 9 X S 11.
A t t e m p t s h a v e b e e n m a d e to c h a r a c t e r i z e h o m o t o p y c o m m u t a t i v i t y in t e r m s of a u n i v e r s a l e x a m p l e .
C o n j e c t u r e 13.14.
X a d m i t s a h o m o t o p y c o m m u t a t i v e m u l t i p l i c a t i o n if a n d o n l y
if X is a r e t r a c t of ~ZSZX. [ W i l l i a m s ] h a s g i v e n c o n d i t i o n s w h i c h a r e e q u i v a l e n t to X b e i n g a n A ° ° - r e t r a c t of ~ Z s Z x .
STRUCTURE Since an associative on
BX
implies
homotopy
homotopy
commutative
H-space
X
commutativity
and homotopy
ON
Bx
is essentially
of
X.
~B x,
a multiplication
O n t h e o t h e r h a n d if m
associative,
then
m
is at least
is
an H-map,
since we have
(wx) (yz) _~ w(x(yz)) _~ w((xy)z) _~ w((yx)z) _~ w(y(xz)) _~ (wy)(xz).
Theorem
1 4 . 1 [Su_._gawara].
multiplication
(X,m)
if a n d o n l y i f m
Notice that for x y ..~ y x
If
by taking
m
is strongly
Similarly, regarded
xyz
yzx
Proof B X × By
and
of T h e o r e m . B X X Y"
homotopy
to be an H-map
w = z = e.
fill in the following triangles
is a n a s s o c i a t i v e
m
H-space,
Bx
implies
being an A3-ma p implies of
we can
S 1 X X 3 -* X :
xyz
zxy
The key to the proof is the equivalence
A specific
a
multiplicative.
(i. e . , w x y z _~ w y x z )
as maps
admits
equivalence
called the shuffle map
of is
induced by : A p × (X X e)p × Ziq )< (e × Y)q-~ A p + q )< Of × Y)P+q w h i c h triangulates (e X Y)q
~P X ~q
and shuffles
(X)< e) p
and
together according to w h i c h s i m p l e x of the triangulation is involved. Specific f o r m u l a s are e a s y to write d o w n [Sugawara, Iv[ilgram,
Steenrod] if w e r e p a r a m e t e r i z e • .. < s
< I.
We
An
by n-tuples
(sI ..... s ) s/t
set up the c o r r e s p o n d e n c e so that the face
0 < sI < s 2 <
t. = 0 c o r r e s p o n d s
72
to the f a c e
s i = si+ I.
The m a p ~
can then be w r i t t e n as
(sI..... Sp, x I ..... Xp) (Sp+ I..... Sp+q,
Yl' " " " Yq)
= (s (i)..... s (p+q), z (i)..... z (p+q)) where
z.x = (x.,e)x for
tion such that Although this
i<_p
s (1). . . . .
and z i =
( e , y i p) for
i > p, a n d = is a n y p e r m u t a -
s (p+q) is c o r r e c t l y o r d e r e d ,
i . e . , is i n AP+q.
~ is n o t w e l l - d e f i n e d , it d o e s i n d u c e a w e U - d e f i n e d m a p
XP(p) X YP(q)--
(X × Y) P(p+q).
T h u s if m
is s t r o n g l y h o m o t o p y m u l t i p l i c a t i v e , we h a v e B X X B X_~B
x × X-" B×
w h i c h can easily be checked to be a multiplication.
T h e converse is straight-
forward. N o t i c e t h a t if m
is a n
s h r n m a p , the m u l t i p l i c a t i o n r e s t r i c t s to
X P (p) × X P (q) -~ X P (p+q) just as does map
CP(p) × CP(q) -~ CP(p+q).
S X X S X - ~ XP(2)
(X X X) P(2)
How homotopy
can be seen by going through the above m a p
SX X SX-~
explicitly.
T h e condition involved in constructing reduced to the following.
(in X x 3 ) :
S X X XP(Z) -~ XP(3)
Let h(t,x, y) be a c o m m u t i n g
h(0,x,y) = xy, h(l,x,y) = yx.
triangle
commutativity gives a
T o construct the m a p
homotopy,
can be
i.e. ,
w e m u s t fill in the following
, ~ ~ s ~
h ( t , x , yz) If m
w e r e o n l y h o m o t o p y a s s o c i a t i v e , the f i g u r e w o u l d b e a h e x a g o n .
A
c o r r e s p o n d i n g f i g u r e a p p e a r s i n M a c L a n e ' s s t u d y of c o h e r e n t f u n c t o r s [MacLane]. The symmetric
condition can he c o m b i n e d with this one to f o r m a
73
f i g u r e i n v a r i a n t u n d e r the s y m m e t r i c
group.
y~z
T h e r e c t a n g l e c a n b e f i l l e d in xyz ~
y
z
× by h(t,x, h(s, y, z)).
x z y ~ , z y x
zxy T h i s h e x a g o n a p p e a r s a l s o in M i l g r a m ~ s s t u d y of ~ Z S 2 X
[Milgram].
T h i n g s a r e m u c h s i m p l e r if X is a n a b e l i a n m o n o i d .
The multiplica-
tion B x X B x-~ B X can be described directly as
(s 1 . . . . .
Sp, x 1. . . . .
Xp) (Sp+ 1. . . . .
Sp+q, Xp+ 1. . . . .
Xp+q)
= (sa (1) . . . . # a (p+q)' Xa (1) . . . . . x a (p+q))" One can check directly that this multiplication is again associative and commutative.
By i n d u c t i o n d e f i n e
Theorem 14.3.
B(n)x
as
BB(n-I)X
with
If X is a n a b e l i a n m o n o i d , B ( n ) x
a d i s c r e t e a b e l i a n g r o u p , B(n)~r is a s p a c e of t y p e One c a n a l s o n o t i c e t h a t Now f o r a m o n o i d morphism. group
BSp~(x)
B(1)(X) = B X.
e x i s t s f o r a l l n.
If ~ is
(~r,n).
= SP°o(SX).
X, b e i n g a b e l i a n is e q u i v a l e n t to m
being a homo-
On t h e o t h e r h a n d , t h e r e a r e s p a c e s s u c h a s t h e i n f i n i t e u n i t a r y
U for which
Eilenberg-MacLane of s i g n i f i c a n c e .
Theorem 14.3.
B (n) e x i s t s , spaces.
e v e n t h o u g h the s p a c e s a r e n o t p r o d u c t s of
T h u s the u s e of s h i n
There is, however,
Let
a compromise
m a p s in T h e o r e m 14.1 is c o n d i t i o n of s o m e r e l e v a n c e .
(X, m) b e a n a s s o c i a t i v e H - s p a c e .
t i o n if t h e r e is a h o m o m o r p h i s m
B X admits a multiplica-
n : X X X - * X s u c h t h a t the u n i t of m
is a
74
h o m o t o p y u n i t of n . For a multiplication
example, on
if ~ l X
X
induces a homomorphism
The multiplication is of c o u r s e we have
homotopy
while with
then so is In g e n e r a l ,
structure
Theorem
some
Y
B
n
BX
of l o o p s ~ln
is induced by
on
Bn.
x = y = e
we have
An associative
then
The multiplication so with
n ( w , z ) "-~wz.
and hence the multiplication
on
)~ : [0, 1] -~ X,
~Ix.
n(wx, yz) = n(wy)n(xz)
we can look for additional structure
"up to homotopy"
14.4.
on
commutative:
n ( x , y ) -~ y x
associative,
denotes the space
on
BX on
m
w = z = e If n
is
is also.
BX
in t e r m s
of
X.
H-space
X
h a s t h e h o m o t o p y t y p e of ~ 2 y for K. if there exists a family of shin m a p s M . : X i -~ X 1 satisfying the
conditions for an A - f o r m as shin m a p s . K. i structure and X t h a t i n d u c e d f r o m X. )
{Here
X i has the product H - s p a c e
T h e t h e o r e m is trivial at this point, though it is tediously difficult to write out explicitly w h a t the c o m b i n e d compatibility conditions on higher h o m o t o p i e s are. the f o r m StiU m o r e
C. × X i-~ X J
It is clear, h o w e v e r , where
spaces,
that they can stiU be written in
C. is an appropriate (if foreboding) cell c o m p l e x . J
elaborate conditions are m a n a g e a b l e
homotopy everything
M .i and its
manageable
in B o a r d m a n ' s theory of
because
t h e y do n o t n e e d to be e x p l i c i t .
INFINITE
There
are spaces
are not only loop spaces
D e f i n i t i o n 15.1. i = 1,2 . . . .
such that Of course
X
X
O,
MacLane'
s
have this property,
U, S p
and their analogues
such spaces
is a f o r m i d a b l e PACTs
task.
In a c a t e g o r y
(a)
the objects are
(b)
the morphisms
such as
in t e r m s
[Boardman]
0 , 1 , Z. . . . from
of h i g h e r h o m o t o p i e s
invents a new gadget (modelled on we need.
We follow him
that
has permutations,
morphism
S
n
to
n
form a topological
-~
associative
lre S
m
m
• n= m
+ n ;
we are also given for each
(n,n), S
we impose and
~(m,n),
continuous functor
n
the symmetric
g r o u p on
(We o m i t a n y s y m b o l f o r t h i s h o m o m o r p h i s m . permutations
space
is continuous;
:~..~such
if
on t h e
;
m
(c) w e a r e g i v e n a s t r i c t l y
(i)
F = lira H(sn).
of operators
and composition
if ~
but less trivially we
[B_.oardman a n d V o g t ] .
Definition i5.2.
(d)
X. f o r z
QX = lira f~nsnx ~ f~(lim~n-lsnx).
[MacLane]) to index the structure
throughout this chapter
topology which
X. h a s t h e h o m o t o p y t y p e of f~Xi+ 1. z
the infinite loop space
To characterize
in a l g e b r a i c
loop spaces.
abelian monoids
We a l s o h a v e f o r a n y
importance
is an i n f i n i t e l o o p s p a c e if t h e r e a r e s p a c e s
X = X1 and
have the infinite Lie groups
multiplication
of c e n t r a l
but iterated
A space
LOOP SPACES
p e S
n
two further then
lr @ p
n
a homon
letters.
) In t h e c a s e w i t h
axioms: l i e s in
S
m+n
az~d i s t h e u s u a l
sum permutation; (ii)
given any
r
morphisms
a . : m . -* n. a n d z z L
~r e S , w e h a v e r
76
~r(n)o(aI ~
a z • ... • Ur ) = Ir(al @ aZ • ... ~ a r )
where
:
m
~,m.,1 n = r.n.,1 Tr p e r m u t e s
and the permutation
w(n) E S
o Tr(m),
the factors
is obtained
from
of a 1 @ a 2 @)" " " • a r , lr b y r e p l a c i n g
i by
n
a b l o c k of
n.
elements.
We require
functors
to preserve
all this
1
structure.
Example maps
15.3.
E n d x, f o r a b a s e d
X m -~ X n , w h e r e
This example
Definition
Xn
space
X.
is the n th p o w e r
Endx(m,n) of X.
is the space
T h e functor
of a l l ( b a s e d )
@) is just
X.
has permutations.
15.4.
The category
if we are given a functor
~-~
~
of o p e r a t o r s
End
acts on
X, or
X
is a~-space,
. X
A particularly
Example
A(m,n)
15.5.
A
{I, Z} -~ {I}
element,
A
m
example
encodes
the associative
law.
be the category of operators described as follows:
i s t h e s e t of a l l o r d e r If
map
Let
important
acts on
preserving
X, then
corresponds
is associative.
X
maps
admits
{1,2 .....
the structure
to a multiplication
rn.
m}--> {1,2 .....
n}.
of a m o n o i d .
The
Since
A(3, I) has only one
Since the single e l e m e n t of A(I, I) can be r e g a r d e d
as the composition of l-~ I c {1,2}-~ I or as the composition of I--~ 2 E {l,Z} -~ I, the multiplication has a unit. B e i n g a rnonoid is not a hornotopy invariant. a category action by
WA WA
to construct
of the s a m e
homotopy
is a h o m o t o p y WB
for any
Consider
B
A(m,l).
W e w i s h to replace
A
by
type (as a category of operators) so that
invariant.
Essentially the s a m e
that m a p s
nicely e n o u g h into A.
It consists of precisely one m a p
w h i c h can be r e g a r d e d as factorized in a variety of ways.
method
may
be u s e d
{I ..... n} -~ {I}
T h e s e factorizations
77
c a n be d e s c r i b e d f a i t h f u l l y b y f i n i t e d i r e c t e d p l a n a r t r e e s w i t h a s i n g l e r o o t (no v e r t e x of the f o r m
~ being p e r m i t t e d and I
b e l o n g s to o n l y one edge). unique m a p
(V)
ponding to~
The i d e a i~ c o n s t r u c t i n g and ~
WA(m, n)
~
i.e.,
or
(V) ~ ( V / )
is a c u b i c a l c e l l c o m p l e x i n w h i c h the c e l l s a r e i n d e x e d by
a I ..... ar
such that ~I .... err E A(m,n). less than the n u m b e r
(for n = I) or of the corresponding such a set a copse.
WA is to h a v e d i s t i n c t m a p s c o r r e s -
a n d to h a v e a s p e c i f i c h o m o t o p y b e t w e e n t h e m .
d i m e n s i o n equal to m
For
WA-structure
C(a I ..... ar)
n = I w e have the cell c o m p l e x of K
m
is a cell of
of edges of the corresponding tree
o r d e r e d set of trees for
Chapter II, a cubical d e c o m p o s i t i o n has a
or
d e s c r i b e s the
T h a t t h e s e a r e two f a c t o r i z a t i o n s of the s a m e m a p e x p r e s s e s the
a s s o c i a t i v e law.
sequences
F o r e x a m p l e , in A(3,1), the t r e e ~
w h i c h can be factored as ~
a (~V).
is the o n l y t r e e for w h i c h the r o o t
.
WA(m,I)
T h e category
if Definition Ii. 18 is satisfied,
n > I.
WA
Boardman
calls
described in
acts on
X
or
X
i.e. , w e have compatible m a p s
WA(n,I) )< X n-~ X.
Theorem X
15.6.
If X
if and only if W A
and
Y
acts on
have the s a m e Y.
If W A
a n d a deformation retraction of M X T h e construction of M X deformation retraction. WA-structure
onto
homotopy
acts on
type, then
X, there is a m o n o i d
acts on MX~X
X.
w a s given in Chapter 11 along with the
A s one should expect, the m a p
up to h o m o t o p 7 ,
WA
X-~ MX
respects the
at least in the sense w e n o w define.
Definition 15.7.
Let
L
be the category with two objects
Definition 15.8.
Let
X
and
Y
be W B - s p a c e s .
A map
I and
2 and one m a p
f : X -~ Y
is a h o m o t o p y
79
B-map Y.
if W ( B X L)
By
Endf (re,n}
acts on
Endf
s o a s to i n d u c e t h e g i v e n W B - a c t i o n s
we m e a n the s p a c e of c o m m u t a t i v e
Xm ~fm
example,
Theorem
I
. T so that
is a homotopy A-map
uniquely up to homotopy through a homomorphism
Corollary 15. I0. Bf : B E - ~ B y .
If f : X - ~ Y (Take
f must be an H-map.
into a monoid,
it f a c t o r s
M X ~ Y.
is a h o m o t o p y A - m a p ,
B X = BMX,
diagrams
yn
Vo.ex. V
If f : X ~ Y
and
~fn -~
W ( A × L) (2,1) = !
15.9.
X
_~ X n
ym For
on
then there exists
Bf = BMf.)
T h e real point of B o a r d m a n ' s a p p r o a c h is to be able to iterate the construction of B E
without a s s u m i n g an abelian m o n o l d structure.
will n e e d lots of homotopies. Boardman)
of a c a t e g o r y
contractible
Theorem
X B
for all
15.12.
is an E - s p a c e of o p e r a t o r s
An E-space
map being described
15.13.
if i t if g i v e n a n E - s t r u c t u r e ;
with permutations
such that
i. e . , a n a c t i o n o n B(n,1)
is
n.
The contractibility
Theorem
Rather than give all the details (we await t h e m f r o m
w e will try to outline the theory conceptually.
D e f i n i t i o n 15.11. X
Clearly w e
is a WA-space. of
B(n,1)
is u s e d to m a p
WA~
B, t h e
0-skeleton
specifically.
If X
is an E - s p a c e ,
the operations
A-maps. Thus there are induced operations
on
B X.
: X m ~ Xn
are homotopy
79
Corollar~r 15.14.
is a n E - s p a c e .
BE
T h e a i m of B o a r d r n a n ' examples
the category
{algebraic) dimension
and linear
R °° w i t h o r t h o n o r m a l
{el, e z .....
is to g e t s e v e r a l
~
of r e a l i n n e r - p r o d u c t
isometric
significant
base
finite topology, dimensional
from
A to
of c o u n t a b l e
As examples
{ e l , e2, e 3. . . }, a n d i t s s u b s p a c e
linear maps
which makes
spaces
maps between them.
e n } , w h i c h is a l l t h e r e a r e up to i s o m o r p h i s m .
t h e s e t of a l l i s o m e t r i c
Lemma
s approach
exists.
BB...BX
of E - s p a c e s . Consider
have
By iteration,
R n with base
We topologize~
B, by first giving
we
A
and
(A,B), B
the
e a c h t h e t o p o l o g i c a l d i r e c t l i m i t of i t s f i n i t e -
subspaces.
15.15.
T h e s p a c e ~ (A, R °°)
This is a consequence
(a) ~ i 2 (b) i l
is c o n t r a c t i b l e .
of t w o e a s i l y c o n s t r u c t e d
homotopies:
: A-~ A@A, u :R
°°
-~
R °o
O R °°, for s o m e
S u p p o s e w e have a functor
T
isomorphism
u.
defined on the c a t e g o r y ~
, taking topo-
logical spaces as values, and a continuous natural transformation : T A X T B -~ T { A ~) B) (a) Tf
called W h i t n e y s u m ,
such that:
is a continuous function of f E ~ (A, B);
(b) T R 0 consists of one point; (c) co p r e s e r v e s associativity, c o m m u t a t i v i t y and units;
(d)
Theorem classifying
T R °° is t h e d i r e c t l i m i t of t h e s p a c e s
15.16. space
T R °° is a n E - s p a c e . B T R °° a g r e e s
If
T
h a p p e n s to b e r n o n o i d - v a l u e d ,
with that from Theorem
As a (noncanonical) multiplication T R °° X T R ° ° ~
T R n.
on
15. lZ.
T R °° w e t a k e
T ( R ~ O IR.~ ) - ~ T R °°, Tf
the
80
where
f : R °° @ i~ °° -~ R °°
provides
is any linear
homotopy-associativity,
commutativity,
and all higher
In t h e e x a m p l e s sional
since
the maps
Tf
The Lemma
homotopies.
below we define (d)
embedding.
f o (f $ 1) ~ f " (1 • f), h o m o t o p y -
coherence
A, and note that axiom
each case
isometric
TA
extends
explicitiy
only for finite-dimen-
t h e d e f i n i t i o n t o t h e w h o l e of ~ .
and the Whitney sum
~
are obvious,
In
i n v i e w of t h e i n n e r
products.
Example
1 5 . 1 7 . 1 . T A = O (/%), t h e o r t h o g o n a l Z. T A = U ( A ®
group
C), the unitary
3. T A = B O ( A ) ,
a suitable
of
group
classifying
A.
of
Then
T R °° = O.
A®
C.
Then
space
for
O(A).
T R °° -- U. Then
TRam= B0. 4. T A
= F(A), the space of b a s e d h o m o t o p y
sphere with
Theorem
15.18.
SA, which is the one-point o0 a s b a s e p o i n t .
The following spaces
Then
equivalences of the
compactification
and maps
admit the structure
U-~ 0-~ F and
Top
of A ,
T R o° = F .
loop spaces :
The semi-simplicial spaces PL
A~)oo
c a n also be handled.
of i n f i n i t e
OPERATIONS
For order
IN I T E R A T E D
LOOP
SPACES
X to be an infinite loop space required
homotopies.
Certain
subfamilies
g i v e r i s e to h o m o l o g y o p e r a t i o n s
a r e of i n t e r e s t
of g r e a t s i g n i f i c a n c e .
a whole congery in t h e m s e l v e s Historically
t h e s e o c c u r in t h e [ K u d o a n d A r a k i ] d e f i n i t i o n of H - s q u a r i n g Steenrod
for they t h e f i r s t of
operations,
analogs
operations.
D e f i n i t i o n 16.1. maps
of h i g h e r
An H -space n
consists
of a s p a c e
X together
w i t h a f a m i l y of
0. : i i X X 2 -*" X, i < n, s/t 1
D
Oi(t I . . . . .
ti,x,y ) = Oj.l(t I .....
tj_ I ,
x,y)
t.j : 0
= 8j_l(1-t I..... l-tj_l,Y,X)
[More efficiently,
the family
=x
if y = e
=y
if x = e .
O. c a n b e r e p l a c e d 1 O
n
such that O (T,x,e) = O (T,e,x) = x n n
by switching factors
in
Thus for
where
T ~ 0 E Zz
on
commutative
H-spaces
map
acts antipodally on
is a h o m o t o p y c o m m u t a t i v e
are H
X
-spaces
H-space.
Notice the
n e e d not be a loop space.
Corollary
16.2.
If X
16.3.
If X
Proof~of Theorem. notation,
i.e.,
is a n H n - s p a c e ,
is
~ny,
Represent
then
Sn
a p o i n t is r e p r e s e n t e d
~X
X
as
is a n H n + l - s p a c e .
is a n H n . l - s p a c e .
Z 2 * Z 2 '~ . . . as
t0a 0 •
For
e v e n if n o t h o m o t o p y a s s o c i a t i v e .
cO
Theorem
S n,
X. ]
condition b e a r s no relation to associativity so
example,
by an equivariant
: Sn × X z -"X
X 2 and trivially
n > 0 X
t.j = I
;~ Z 2 w i t h M i l n o r ' s
. . . {~ t a n
n
where
of
82
a i• Z z, (to ..... tn) • A n.
Define
O n + l ( t 0 a 0 • . . . • t n a n • t n + l l ; k 1, kZ) (t) to b e tn o to ~n+l (t)) whe r e k ~ ( t ) = k z ( t - (l-s )(r2)) e n ( l _ - ~ n +1 0 0 e . . . e n l _ t n +1 ; k l ( t ) ' k
w i t h the u n d e r s t a n d i n g
kz(t) = kZ(0)
for
t < 0
= k2(r Z) f o r
Extend by equivariance. an H-space
For
t >r z .
n = 0, this is a standard proof that the loop space of
is homotopy commutative.
Definition 16.4.
Given an H -space
(X, O ), the K u d o - A r a k i
n
Qi : I_Iq(X;Z2) -* H N + i (X;Z z) is d e f i n e d f o r where
square
n
i-n < q _< i by oi([u]) = Or~ (ei_q®U®U)
e. is an i-dimensional cell in the standard equivariant decomposition of I
S n" Before going further w e introduce the rood p analogs [Dyer and Lashof ].
Defintion 16.5.
An Hn-space P
X consists
o n : ~(p)*.
s/t on(~,e ..... e,x,e ..... e) = x
Theorem
Proof.
l6. 6.
If X
We p r o c e e d
tn no
x xP-
map
x
and on(o • ... $ O @
v e r y m u c h a s in t h e c a s e
l'l;xI..... Xn) = x l...x n.
p = 2..
If k i : [0, r i ] - ~ X, d e f i n e
f o r On+ 1 t h e n b e c o m e s to t @ s.id; k I..... k p ) (t) = SniFfs a0~).., l@~.~an;kl(t) ..... kS(t)). p
Now consider TJe.,, 0_< j < p
.. *J(p~
X and an equivariant
is H n, f~X is ~I-F "+I. P P
k s (t) = k i ( t - ( l - s ) ( r 1 + . . . + r i . 1 ) ) .
en+l(t0a 0 @ . . . ®
of a m o n o i d
such that
The formula
W , the standard P 8eZi+l = (T-1)ezi
resolution
of
7.
@ezi -- (1 + T +
P
with generators + T p-l) eZi_l.
83
The i n c l u s i o n "n-skeleton"
Z -~ ~ ( p ) as c y c l i c p e r m u t a t i o n s i n d u c e s c o n s i s t e n t m a p s of the P n of W into C ( ~ ( p ) * . . . * ~ ( p ) ) . Thus we think of 0 . a c t i n g o n P
W ® C (X) @p. P
Definition 16.7.
where
~tO,q)
For
(2j-q)(p-1) <_n and x E H (X), define q OJ(x) = ~ / ( j , q ) ( ~ ) l 8 n, (e(2j_q)(p_l) @ x ® . . .
@ x)
p-12
is the s i g n of q + [j + ( Z - ~ ]
The o p e r a t i o n s defined have the following p r o p e r t i e s ,
s o m e of w h i c h
d e p e n d on this p r e c i s e c h o i c e of ~ (j, q). QJ : Hq(X;Zp)-~
Hq+zj(p_l)(XiZp)
QJ is a h o m o m o r p h i s m
if
for j _> q / Z
and
(3j-q)(p-l)_< n
(gj-q)(p-l) < n-I
QJ is natural with respect to H n - m a p s P QI
is trivial if q = 0
Q q / Z l x ) = xP
if q is e v e n
a . Q j = QJ~, w h e n b o t h a r e d e f i n e d and a , : Hq_I(~X) -~ Hq(X) is the h o m o l o g y " s u s p e n s i o n " . J u s t as S t e e n r o d o p e r a t i o n s give a n i c e d e s c r i p t i o n of H ( Z , n ; Z ) P t h e s e o p e r a t i o n s give a n i c e d e s c r i p t i o n o f i i denote by QI the c o m p o s i t i o n Q 1 . . . Q r. if<2i2-- .... 'ir-i
excess,
is defined on is < q+n.
r
H
of an H n - s p a c e
if the
If e(I) = i = q, then QI
--
r
zr-th power.
T h e o r e m 16.8. ~Kudo and Araki].
For
h a v i n g as g e n e r a t o r s all a d m i s s i b l e Similarly for
k > 0, H , ( ~ n s n + k ; z Z) is a p o l y n o m i a l r i n g
Q~uk of e x c e s s
1.
> k and l a s t d e g r e e
p > 2, we c o n s i d e r s e q u e n c e s £
1
lr), we
q
--
with e. = 0 or
I = (i 1. . . . .
We s a y QI is a d m i s s i b l e if
r
excess of I is > q and the last degree i raises to the
For
e(I) = il - Zi2 + i Z - Zi3 + ... + i r = 2iI- ~i"3
e(I) < i . Notice that QI --
H . (~nsn+k).
so
We let QI denote
S
¢'_
~ 1Q 16 ~ . . . ~
£
I = (e 1, s 1. . . . . S
kQ k, w h e r e
< n+k.
e k ' Sk)
84
: Hq (X) -~ Hq_l(X) 0-~ Z p - ~ Z p 2 - ~ Z the r e l a t i o n
is the B o c k s t e i n b o u n d a r y f o r the s e q u e n c e -~ 0.
[For
~ = 2, ~ n e e d not be u s e d e x p l i c i t l y s i n c e we have
~Qgi+l = oZi. ] [ D y e r and L a s h o f ] d e s c r i b e g e n e r a t o r s f o r
H , {"Ansn+k ~ ; Z p ) in t e r m s of a l l o w a b l e s e q u e n c e s .
May has translated" allowable"
into the following.
k Definition 16.8.
QI is m - a d m i s s i b l e
if PSi+ 1 " ¢ i+l >-- s i > [ m + >
Zsj(p-l)-¢j]l 2.
i+l The following two t h e o r e m s a r e then t r a n s l a t i o n s of t h o s e g i v e n by D y e r and L a s h o f .
T h e o r e m 16. 9.
F o r any
connected
X we have that H.(l~m 6 ~ n s n x ; z ) is f r e e P commutative on {x, Olx I x , basis of H,(X;Zp), Ol is d i m x-admissible}. N o w let O X
denote the base point component of lirn onsnx.
T h e o r e m 16.10.
H , ( Q S 0 ; Z ) is f r e e c o m m u t a t i v e on g e n e r a t o r s y(I) of d i m e n s i o n P e q u a l to deg I w h e r e I r u n s o v e r all 0 - a d m i s s i b l e s e q u e n c e s . [ F o r p = Z, k I = (s 1. . . . . Sk) is 0 - a d m i s s i b l e if 2si+ 1 > s i > ~ ' - - sj. ] The D y e r - L a s h o f o p e r a t i o n s b e h a v e as f o l l o w s : J = (¢l, Sl . . . . .
If
i+l
~k_l, Sk_l), then Q J ~ k y ( s k )
Y(S k) e HSk(QS0;Z z) and if J = (s 1. . . . . The g e n e r a t o r QI
=y(£1, Sl . . . . .
Sk_l)
then
Ck, Sk).
[For
Q J y ( s k) = y(s 1. . . . .
y(I) c a n not be i n t e r p r e t e d as
p = Z, Sk).]
QI(x) f o r a n y x s i n c e
is t r i v i a l on H0(QS 0) a l t h o u g h an i n t e r p r e t a t i o n in t e r m s of QI is p o s s i b l e
if we c o n s i d e r all the c o m p o n e n t s of
lira 0nsn.
Kudo and Araki prove their result by mimicing H*(Z, n;Zz). Theorem
for
The crucial machine is a dual t o ~ o r e ~ s transgression theorem.
16. U.
If H,(X;Z2)
Serre
Let X
be a simply connected, homotopy associative
has a simple system of transgressive generators
x. then I-I,(~X;Z 2) 1
is a polynomial ring on generators
Yi such that Yi £ Tx..1
H-space.
85
Dyer and Lashof proceed somewhat differently. H.(~ksix;Zp)
in the range < 3i- Zk which determines
They compute
H~(lim..f~nsn+kx;Zp).
They do the computation by analyzing the homology as a tensor product of monogenic Hopf algebras, mapping the corresponding tensor product of model spectral sequences into the Serre spectral sequence for ~ k + I s i x - J ~ k s i x - ~ ~ksix
and applying the comparison theorem.
Finally, they identify the various
classes at hand in terms of the operations QJ. ~nsn
The final stage from
~n-Isn
to
requires s o m e special effort. N o w let us return to a space of m o r e geometric interest.
The space
Q S 0 has the s a m e homotopy type as S F = lira SH(Sn), S denoting m a p s of degree I, but the equivalence is not one of infinite loop spaces. multiplications are not equivalent.
In fact even the
A major accomplishment of the last few years
has been the determination of the Hopf algebra H $ ~ ; Z z) and the algebra # H ( B F ; Z ) for p >_.Z. The operations Qi have played an important role in this P development. That H * 0BSF) was not the s a m e as H *(BQS 0) has tong been k n o w n for H ( B S F ; Z 2 ) D Z 2 [w i I i [ 2] w h e r e H~'(BQS0;Zz)
{wi}
is a n e x t e r i o r a l g e b r a .
a r e the S t i e f e l - W h i t n e y c l a s s e s .
While
The c o m p l e t e r e s u l t s c a n n o w b e s t a t e d ,
a l t h o u g h the p r o o f s a r e s o i n v o l v e d a l g e b r a i c a l l y a s to b e i n a p p r o p r i a t e f o r p r e sentation here. Let
o denote composition,
l o o p a d d i t i o n in QS °.
the m u l t i p l i c a t i o n in S F
We h a v e c o r r e s p o n d i n g
operations
t h e f i l t r a t i o n of H~ (SF) b y p o w e r s of t h e a r g u m e n t a t i o n
and l e t
Q~ and Q I. i d e a l and l e t
# denote Consider
E"
denote
the associated graded.
T h e o r e m 16.12. [ M i l g r a m ] . of H~(QS °)
For
p = 2, l e t
o r the i s o m o r p h i c c l a s s e s
I Q,~y(k) b e the D y e r - L a s h o f
in H ~ ( S F ) .
generators
86
y(k)
o y(k) ~ 0 ,
y~)o
y(k) o y e ) .
y(k) : 0
Q y(k) ° Q,y(k) = 0 in E ° (y(k) * y(k)) ° (y(k) * y(k)) : 0
Corollar~" 16.13.
H
(BSF;Z2) ~. Zz[Wi] Q C
E°
in
where
C
is isomorphic to
E(ezi+t Ii > I) ® r(g([)i I is l-admissible of length > 1). Here
eZi+l is dual to sly(i) • y(i)] and g([) is dual to ~y(1). The spectral sequence f r o m
ExtH~(SF)
to H
(BSF) has no choice but
to collapse since, being a spectral sequence of Hopf algebras, only primitive relations can be added.
This m e a n s only 2i-th powers of primitive classes could
be killed, but the only nontrivial ones present in E 2 are in ZZ[wi] which w e k n o w survives untouched. For
p > Z, there is a striking difference which is really a subtle
s i m i l a r ity.
T h e o r e m 16.14. [May].
For
T h e o r e m 16.15. [May].
In the E i ! e n b e r g - M o o r e
E2 ~ EXtH ( S F ; Z ) p If I = (1, j , J )
we h a v e
is 0 - a d m i s s i b l e ,
dp_l[Y(J) I . . . I
p > 2, H , ( S F ; Z
E 2 ~ E p . 1 with
P
)~--H(QS0;Z
P
) as Hopf a l g e b r a s .
spectral sequence for
BSF
with
dp_ t g i v e n as follows:
J odd of d e g r e e Zj-1 and l e n g t h > 1, then
Y(J)] =y(I)-
J.
C o r o l l a r y , 16.16. 1) 2)
H (BSF;Zp) ~ Zp[qi ] O E(~q i) O E O F w h e r e
{qi } a r e the
Wu c l a s s e s
E is a n e x t e r i o r a l g e b r a on p r i m i t i v e g e n e r a t o r s
e. dual to 1
~y(1, Z(p-1) 1, i) in H Z P i ( p - 1 ) - I ( B s F ) a n d
g(I) dual to ~y(I) w h e r e
I r u n s o v e r all 1 - a d m i s s i b l e s e q u e n c e s of e v e n d e g r e e and length
>
1.
87
3)
1~ is a divided polynomial algebra on primitive generators
~e. i
and g(J) where
J runs over all 1-admissible sequences of odd
degree and length> I. [The W u
class qi is dual to ~(l,i) and
~qi to a(0, i). ] Milgram' s and May' s proofs are rather unusual exercises in manipulating Hopf algebras over the Steenrod algebra or its dual. the C a f t a n f o r m u l a e and A d e m r e l a t i o n s for the t h e [ N i s h i d a ] r e l a t i o n s b e t w e e n the operations. structures
Theorem
Qi
Qi
It is important to have
[ D y e r - L a s h o f ] and e s p e c i a l l y
a n d t h e h o m o l o g y d u a l s of t h e S t e e n r o d
An old f a c t in h o m o t o p y t h e o r y c r u c i a l in r e l a t i n g the v a r i o u s a l g e b r a i c _ S n-l, •
involved. 16.17.
(~nsnx, e) is a module over
Corollary 16.18.
He{~nsnx)
Theorem
(~nsnx, e) is a module over
(sn-l,e
is a Hope algebra over
,°).
H e(s n'l,eS
n-I • , ).
S n-l, • 16.17.
(Sn-l,e
, .).
S n-l, Corollary 16.18.
I-Ie {~nsnx)
is a Hopf algebra over
T h e t h e o r e m is a r e s t a t e m e n t
(leg) . ~.a = f • r.c~eg . r.~. ~nsnx
is commutative, corresponding
e).
of the r i g h t d i s t r i b u t i v i t y of c o m p o s i t i o n
if f , g : S n -~ s n x
over track addition, i.e.,
He (Sn'l, •
and
a : S n ' l -~ S n-1
D i a g r a m a t i c a U y we h a v e w i t h
X ~ n s n X × F(n-1) -~ ~ n s n x
then
F ( n ) = Sn , e S n ' e , t h a t
X ~ n ~ n x X F(n)
~ n s n x ~'~F(n)
~ n S n "X - -X ~ n S n~X X F(n) X F(n)
~-~ n x
~'~nsnx X F (n) X ~ n s n x X F (n)
~
at least up to homotopy.
The diagram helps in describing the
c o n d i t i o n in h o m o l o g y .
T h e h i g h e r o r d e r p h e n o m e n a i n v o l v e d in h a n d l i n g t h e o p e r a t i o n s n e c e s sitate studying this distributive t e r n a t e d e s c r i p t i o n s of H n
or
l a w up to h i g h e r h o m o t o p i e s . Hn-structures P
on BO
and
BF
There are also al[Boardman,
T s u c h i y a , M i l g r a m ] w h i c h s h o u l d g i v e the s a m e h o m o l o g y o p e r a t i o n s b u t at the
88
m o m e n t a r e n o t k n o w n to do s o . characterizeable problems,
FinaUT, infinite loop spaces should be
in t e r m s of t h e m a p s J ( n )
*...*
~ ( n ) X X n - ~ X.
In a l l t h e s e
we a r e f a c e d w i t h a n a l T z i n g a f a m i l i a r a l g e b r a i c s t r u c t u r e f r o m a
h o m o t o p 7 p o i n t of v i e w , b u t p e r h a p s t h e s p i r i t of t h a t p o i n t of v i e w is by n o w sufficientl 7 clear.
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