Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
507
Michael Reed
Abstract Non Linear Wave Equations
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Lecture Notes in Mathematics Edited by A. Dold and B. Eckmann
507
Michael Reed
Abstract Non Linear Wave Equations
Springer-Verlag Berlin. Heidelberg. New York 197 6
Author Michael C. Reed Department of Mathematics Duke University Durham, North Carolina 27706 USA
Library of Congress Cataloging in Publieation Data
Reed, Michael. Abstract non-linear wave equations. (Lecture notes in mathematics ; 507) Based on lectures delivered at the Zentz~m f~r interdisziplin~me Forsehung in 1975. Bibliography: p. 1. Wave equation. I. Title. II. Series : Lecture notes in mathematics (Berlin) ; 507. QA3.La8 no. 507 [QCI74.26.W3] 510'.8s [530.1'24] 76-2551
AMS Subject Classifications (1970): 35L60, 47H15 ISBN 3-540-07617-4 ISBN 0-387-07617-4
Springer-Verlag Berlin 9 Heidelberg 9 New York Springer-Verlag New Y o r k . Heidelberg 9 Berlin
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 means, and storage in data banks. Under w 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 be determined by agreement with the publisher. 9 by Springer-Verlag Berlin 9 Heidelberg 1976 Printed in Germany Printing and binding: Beltz, Offsetdruck, Hemsbach/Bergstr.
Preface
These notes cover a set of eighteen lectures delivered at th e Zentrum f~r interdisziplin~re Forschung of the University of Bielefeld in the summer of 1975 as part of the year long project "Mathematical Problems of Quantum Dynamics".
It is a pleasure to thank the Zentrum
for the opportunity to give these lectures and the Physics faculty of the University of Bielefeld for their warmth and hospitality. people deserve special %hanks:L. C. Pfister,
Streit,
Three
for extending the invitation,
for help in the preparation of the man~scrlpt,
and M. K~mper
for her excellent typing.
Mike Reed Bielefeld, August,
1975
Table
Introduction
Chapter
1
I. L o c a l
of Contents
. . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Existence
and global
and properties
existence
1
of s o l u t i o n s
. . ~ . . . . . . . . . . . . . . . .
5
2. A p p l i c a t i o n s : A.
utt
-
B.
The
case
C.
Other
D.
The
E.
An example
F.
The
~u + m 2 u
p,
5. W e a k
Chapter
7.
2
8. S c a t t e r i n g
9. G l o b a l
.
.
.
.
.
.
.
.
.
II
equation global
. . . . . . . . . . . . . . . . . . existence
fails
and K l e i n - G o r d o n
. . . . . . . . . . .
equations
. . . . . . . .
. . . . . . . . . . . . . . . . . . . . .
speed
and continuous
25 29 33
40
dependence 49
56
. . . . . . . . . . . . . . . . . . . . . . . . . . .
64
theory
of scattering
for s m a l l
existence
10.Existence
3 .
. . . . . . . . . . . . . . . . . . . . . . . . .
Scattering
Formulation
=
. . . . . . . . . . . . . . . . . . . . . . . . . . .
solutions
6. D i s c u s s i o n
D
20
Dirac
propagation
,
A . . . . . . . . . . . . . . . . . . . . . .
of solutions
on the data
3
=
19
where
coupled
n
. . . . . . . . . . . . . . . . . . . . . . .
sine-Gordon
3. S m o o t h n e s s
4. F i n i t e
m = o n and
,
= -~lulP-lu
data
for s m a l l
of t h e W a v e
problems
. . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . .
67
71
data
. . . . . . . . . . . . . . . . .
88
operators
. . . . . . . . . . . . . . . . .
90
Vi
II.
Applications: A.
The
non-linear
B.
utt
- Uxx
C.
utt
- Au
D.
The
coupled
12.
Asymptotic
13.
Discussion
Bibliography
Schr~dinger
+ m2u + m2u
= =
lu p Au p
Dirac
completeness
, n = , n =
and
equation I 3
. . . . . . . . . . . .
~94
. . . . . . . . . . . . . . .
96
. . . . . . . . . . . . . . .
102
Kleln-Gordon
equations
. . . . .
. . . . . . . . . . . . . . . . . . . .
105
IIO
. . . . . . . . . . . . . . . . . . . . . . . . . .
121
. . . . . . . . . . . . . . . . . . . . . . . . . . .
125
Introduction
During the past year there has been a great deal of interest, both in applied physics and in q u a n t u m field theory, equations.
Like all n o n - l i n e a r problems,
in n o n - l i n e a r w a v e
these equations must to some
extent be dealt w i t h individually because each equation has its own special properties. treated separately;
Thus,
in the literature these equations are often
the proofs of existence and properties of solutions
often seem to depend on special properties of the p a r t i c u l a r equation studied.
In fact, these equations have in common certain basic problems
in abstract n o n - l i n e a r
functional analysis. Using just the standard
tools of linear functional analysis and the c o n t r a c t i o n m a p p i n g principle, one can go q u i t e far on the abstract level, thus p r o v i d i n g a unified approach to these n o n - l i n e a r equations.
Furthermore,
the ab-
stract a p p r o a c h makes it clear which p r o p e r t i e s of the solutions are general and w h i c h depend on special p r o p e r t i e s of the equations themselves.
The abstract approach, which o r i g i n a t e d in the w o r k of Segal
[~|], has been n e g l e c t e d p a r t i a l l y because one can always push further in a p a r t i c u l a r case using special properties.
Nevertheless,
the ab-
stract methods and ideas form the core of much of the recent work, although this is somewhat obscured
in the literature,
Furthermore,
there are m a @ y b e a u t i f u l and important unsolved p r o b l e m s both on the abstract and the p a r t i c u l a r
level.
For all of these reasons,
it seems
an a p p r o p r i a t e time to pull together what is known about the abstract theory and how it is applied. To see how the abstract q u e s t i o n s arise n a t u r a l l y from an example, consider the n o n - l i n e a r K l e i n - G o r d o n equation:
(I)
utt(x,t)
Basically,
- Au(x,t)
+ m2u(x,t)
= - glu(x,t) IP-lu(x,t)
u(x,o)
= f(x)
ut(x,o)
= g(x)
x ~ Rn
one w o u l d like information about local e x i s t e n c e of solutions,
global existence,
smoothness,
finite p r o p a g a t i o n speed, continuous de-
p e n d e n c e on the initial data and e v e n t u a l l y we want a s c a t t e r i n g theory, As we will see, the results and the t e c h n i q u e s depend c r i t i c a l l y on the size of p and n and the sign of g.
To treat
(i) in a general setting
we r e f o r m u l a t e it as a first order system as follows:
-
Let
v(x,t)
2
-
= ut(x,t) , t h e n v t - du 9 m 2 u = - g l u l P - l u
(2)
ut = v
Now,
for e a c h
(3)
u(x,o)
= f(x)
v(x,o)
= g(x)
t, d e f i n e
~(t)
=
v(x,t)>
we
can r e w r i t e
(2) as
Then, (4)
#' (t) -
J(~(t))
(0 ~-m 2
Io)~(t)
~(0)
The
operator
with
domain
where
^ always
que p o s i t i v e calculus. space
(
the
transform.
inner
product
W B = D(B)
,
, v>
root
)B =
(Bu
of
positive (Bu
We d e n o t e
-4 + m 2 g { v e n and
closed,
, BU)L2
~ L 2 ( R n)
on
L 2 ( R n)
with
, BU)L2
+
We can the
( v
inner
by B the uniby the
functional
D(B)
is a H i l b e r t
thus
define
the
Droduct
, v )L 2
let
Then, D(A)
the F o u r i e r square
operator
so t h a t
(k) G L 2 (R n)
B is s t r i c t l y
>
=
self-adjoint
f G L 2 ( R n)
- glulP-lu
= J(~(t))
(k 2 + m 2) f
self-adjoint
space
, v>
by t h o s e
denotes
Since
under
Hilbert
is a p o s i t i v e
- A + m2 given
= <0,
one
can
check
= D(B 2) ~ ) D ( B )
that
A is a s y m m e t r i c
and A is c l o s e d
since
operator B and B 2
on
~B
are
with closed.
domain
-
3
-
Now define for each t, W(t)
=
B-isin(tB) 1
Ic~
\ -B
sin (tB)
cos(tB)
where each of the entries is defined by the functional calculus for B
on L~(Rn).
One can now compute directly that
continuous o n e - p a r a m e t e r group and that for tive of itself,
W(t)~
exists and equals
- iA~.
a corollary of Stone's t h e o r e m
self-adjoint in D(A)
and generates
our original p r o b l e m
(i) as follows.
function
W(t)
~ fD(A) Since
the strong deriva-
W(t)
(see~,p.26~)
W(t).
is a strongly
takes
D(A)
into
says that A is
We have thus reformulated
We must find an
~B
- valued
@(-) on R w h i c h satisfies:
d~(t) dt
r
= _ iAr
=
r
+ J(@(t))
-
w h e r e the self-adjoint operator A is given by This shows that
(5) and J is given by
(3).
(I) is really a special case of a very general class
of Hilbert space problems. Hilbert space ~ , a vector
Namely, given a self-adjoint operator on a r in~ , and a n o n - l i n e a r m a p p i n g J of ~
into itself, when can one find an
~-valued
function
~(-) on R w h i c h
solves the initial-value problem:
(6)
@' (t) = - iAr
r
+ J(r
= r
It is this abstract p r o b l e m w h i c h is the main subject of these lectures, but the main m o t i v a t i o n classical properties equations.
for studying the abstract problem is to prove
(existence, smoothness,
etc.)
of n o n - l i n e a r wave
So, we will always return to the equation
n o n - l i n e a r equations like the s~ne-Gordon equation, K l e i n - G o r d o n equations,
the n o n - l i n e a r
(i) and to other
the coupled Dirac-
S c h r ~ d i n g e r equation.
Our treat-
ment of applications is uneven because there is no attempt to be complete - the applications are used to show the d i f f e r e n t ways the abstract theory can be applied.
Thus we sometimes provide most of the details
and sometimes just sketch the important features or say how one appli-
-
cation d i f f e r s
from other.
cations w h i c h we don't listed
The m a t e r i a l
of the
Here the a b s t r a c t
problems,
well
either
ding the t h e o r y
lectures
In C h a p t e r
theory
understood.
there
but w h i c h
are many b e a u t i f u l can be found
falls n a t u r a l l y theory
appli-
in the DaDers
is quite
complete
2 we d e v e l o p
various
roughly means c o m p a r i n g
and the method
applications
to cover new applications. clear
In
of solutions
of
of
there are many u n s o l v e d
of s p e c i f i c
will become
into two parts.
and p r o p e r t i e s
Nevertheless,
in the details
are very d i f f i c u l t
(6) w h i c h "free"
Furthermore,
even m e n t i o n
I we treat the e x i s t e n c e
application
which
-
in the bibliography.
Chapter (6).
4
or in exten-
T h e s e problems,
some of
as we proceed.
aspects
solutions
of a s c a t t e r i n g of
theory
(6) to solutions
for
of the
equation
~' (t) = - iA~(t)
(o) = ~o for large p o s i t i v e
and n e g a t i v e
times.
Here the a b s t r a c t
satisfactory
in that many more h y p o t h e s e s
applications
are
less well
understood,
required
in order to have a c o m p l e t e
interest
in these many u n s o l v e d
main purpose.
is less
on A and J are required,
and more a b s t r a c t
theory.
problems
theory
then
results
the
are
If I can arouse your I will
have
achieved
my
Chapter
i
E x i s t e n c e and P r o p e r t i e s of Solutions
I. Local and Global E x i s t e n c e In this section we prove a local e x i s t e n c e t h e o r e m for give various applications.
existence of solutions of o r d i n a r y d i f f e r e n t i a l equations. late
(6) and then
The basic idea is the same as the proof of We reformu-
(6) as an integral equation problem:
(7)
f~
~(t) = e-iAt~o +
and then solve
Theorem 1
e-iA(t-s)J(~(s))ds
(7) by the contraction m a p p i n g principle.
(local existence).
Let A be a self-adjoint operator on a Hil-
bert space ~ and J a m a p p i n q from D(A) to D(A) w h i c h satisfies:
(Ho) (H i )
TIAJC~)II ~ c ( I T ~ ] I ,
(HLo)
llJr
(H~)
llA(Jr
- J(~)ll < c ( l l ~ t l ,
I1~1t)11~- ~11
J(~))ll <_c(ll~li,
for all # , ~ D ( A ) where
I IA~LI~IIA~T!
finite)
IIA~II, f l a i l ,
w h e r e each constant~C
IIA~II)
is a m o n o t o n e
function of the norms indicated. Then,
there is a T > O so that solution for tE[O,T).
IIA~-A~II
increasing
(every-
for each ~o6D(A)
(6) has a unique c o n t i n u o u s l y d i f f e r e n t i a b l e
For each set of the form
T can be chosen u n i f o r m l y for all #o in the set. Proof. Let X(T) be the set of D(A) ~(t) and A~(t)
-valued functions on
are continuous and
[I*( )I[ T = sup 11~(t) In + sup
l lA~(t)[l
<
[O,T)
for w h i c h
-
Since A is a closed operator, Banach
space.
Choose
X(T,u,~ O) consist
-
X(T) with the norm
some fixed ~ > O.
of those
II~( ) - eiAt ~ollT ~ ~(8)
6
~( ) in X(T) with
~(0) = #o and
+ ;~ e -iA(t-s)
J(~(s))ds
is a contraction
on X ( T , u , ~ ) if T is small enough.
of the constants
in the hypotheses that
with arguments
~(. ) s
IIJ(~(s+h))
-J(~(s))
- e-iA(t-s)J(~(s))
and
II
II + II(e -iAh -I) J(~(s)) II
is a continuous
proof shows that Ae-iA(t-s)d(9(s)) hand side of
+ u
-~(s)l] + l](e -tAb-z) J(~(s))il
_< %ll~(s+h)
so e-iA(t-s)J(~(s))
We denote by C~ any II#o[J
then
I le-iA(t-(s+h))J(~(s+h))
<
(8) can be defined
n n n (t)
~-valued
function
is also continuous.
using the Riemann
of s. A similaE Thus,
integral,
the rightand if
~l_-i (t- (m/n) t) A Jf~(~m t ))
--
m= 1 and n(t)
then qn(t)--~n(t) ,n(t)~D(A),
-= st e -i(t-s)A
as n - - ~
J(~(s))ds
. Now, by the hypotheses
on J, each
so
n Ann(t)
=
I -i(t-(m/n) t)A A; (~ ( ~i~ ,mt )) E~
;
m=l
--~
is a
be given and let
We will show that the map
(S~) (t) = e-iAt#o
I IA~oi I + u . Suppose
II~( ) J]T
Let ~o 4 D(A)
t o
e
- i,(t-s) A
AJ(#(S) )ds
-
Therefore,
(9)
n(t)~D(A)
7
-
and
A/te -i(t-s)A J(~(s))ds ~o
= Ite -i(t-s)A AJ(#(s))ds ao
Further, I IA~(t+h)
- A~(t) I I <
[ t+h e -iA(t-s)
e-iAhAj(~(s))ds
1
Jt +
[t(e-ihA -i) e-iA(t-s) ~o
<_ hC~II~IIT
+
Aj(4)(s))dsll
I( e-ihA -I)AJ(#(s))Ilds
The integrand in the second term converges to zero as h-90 for each s and by the hypotheses on J, the integrand is uniformly bounded. Thus, by the dominated convergence theorem the right-hand side converges to zero as h--90, so An(t) is continuous and similarly, n(t) is continuous. Further, exactly the same kind of estimates ~(.) and ~(.)~X(T,O,~o) , we have
l l(s~)(t)
- e-iA%oll
< C T sup IIr --
I IA(S~) (t) - Ae-iAt~oll
as above show that for any
~
t
~
II
[o,T)
<_ CoT sup I IA~ (t) I i t 9 [o,T)
II (S%) (t) - (S~) (t) ll <_ CoT sup I Ir t ~[o,T)
- ~(t) ll
l l~(~s~) (t) - (s~) (t)) i l _< C T sup liAr(t) - A~(t) ll tG [o,T)
Th~s, for T small enough, S is a contraction on X(T,o,~0) so, by the ~ontraction mapping principle (see[~&],p,|5|), S has a unique fixed point 4(.) in X(T,O,~o) which satisfies (7). Now, suppose that ~ is a continuoulsy differentiable D(A) -valued solution of (6) on the inter-
-
val
[0,@) w i t h
tinuous, obeys
if
(7)
T
so
9(0)
= #o"
=
~(t)
for
t
< T, l i m t § T,~(t)
-
By the d i f f e r e n t i a l
~(t) 9 X ( T o , ~ , ~ O)
~(t)
8
for t in some
< TO .
Let
T
= ~(T ) and
1
I
equation,
interval be
the
sun
limt+ T,A~(t)
A~t)
[O,To). of
such
= A~(T
1
~(T ) = ~(T ) G D(A) 1
is conSince TO.
Then,
) exist
so
!
and the same a r g u m e n t
as a b o v e
shows that
~(t)
= ~(t)
1
for some small
~nterval
T
< t < T < T which contradicts 1 -2 reality of T . T h u s T > T, so ~(t) = ~(t) for t E [O,T). 1 1 -any s t r o n g s o l u t i o n of (6) on [O,T) e q u a l s ~(t). To p r o v e the s t r o n g d i f f e r e n t i a b i l i t y
(t+h)
- ~ (t) =
( e - i A h -I ) e - i A t ~ o
h
0oED(A)
and s i n c e t h e to J ( # ( t ) ) .
is,
of ~(t), we w r i t e
+ ~i Jt It+h e - i A ( t - S ) e - i h A j ( ~ ( s ) ) d s
h
the first t e r m c o n v e r g e s
integrand
-ihA II e
of the t h i r d t e r m c o n v e r g e s
as h - - 4 0 converges
to
for e a c h s and
-I
h
so the i n t e g r a n d gence theorem,
to - i A e - i A t ~ ~
of the s e c o n d t e r m is c o n t i n u o u s , i t
The integrand
e - i A ( t-s) ( - i A J ( ~ ( s ) ) )
is u n i f o r m l y
the third
I
bounded.
term converges
te-iA(t-s) o
~which b y
That
h
-0
Since
the m a x i -
Thus,
by the d o m i n a t e d
as h--~O to
( - iAJ(~(s)))ds
(91 e q u a l s - i A [ t e -iA(t-s) -o
J(~(s))ds
conver-
-
Therefore
#(t)
Corollar~ 1
-
is strongly d i f f e r e n t i a b l e
for
t~[O,T)
Let A be a self-ad~oint o p e r a t o r o n e ,
and n o n - l i n e a r m a p p i n g J takes ~ for each #o e ~ lution ~(t) on
Proof
9
and satisfies(6).|
and suppose that
into itself and satisfies
' there is a T > o such that
(H~). Then
(7) has a continuous so-
[o,T).T can be chosen u n i f o r m l y on balls
in ~ .
This is really a c o r o l l a r y of the proof of T h e o r e m i. The proof is
similar, only much easier since we don't have to d i f f e r e n t i a t e the integral equation.
Just define
X(T,~,~ o) = { ~ (t) I supl I $ (t) - e-iAt~ol I ! ~, ~ (o) = ~o } t~ [o,T) and proceed as before. ~ We remarkT that the hypotheses
(Ho) and
(H I ) follow from h y p o t h e s e s
T
(HE) and
(H~). We state them separately
for easy comparison with the
hypotheses T h e o r e m 2 below. Notice also that the same proof shows local existence on an interval
(-T,T)
since e -iAt is a group.
It is w e l l known from freshman calculus that n o n - l i n e a r ordinary d i f f e r e n t i a l equations may not have global solutions in time (for exdx 2 ample: ~ = x ). As in that case, one can prove global e x i s t e n c e if one has as apriori estimate which guarantees that the solution remains bounded.
T h e o r e m 2 (global existence) T h e o r e m 1 except that
Let A, J, and ~
(H I ) is r e p l a c e d by
(i.e. C does not depend on
I IA~I I ). Suppose that on every finite in-
terval on w h i c h a strong solution of Then
satisfy the hyDotheses of
(6) exists,
I l~(t) I I is bounded.
(6) has a unique global solution for all time.
Proof:
By T h e o r e m 1 we know that a solution exists on
T > o small enough. solution of
for some
Let T be the s u p r e m u m of the numbers T so that a
(6) exists on
that ~ < ~ and
[o,T)
[o,T) with ~(t)
I IA~(t) I I is bounded on
and A~(t)
continuous.
SupDose
[o,T). Now in the local existence
proof in T h e o r e m 1 the length of the interval of e x i s t e n c e d e p e n d e d only on the numbers
ll#ol I , I IA~ol I. Therefore,
if we choose a point T 1 close
-
iO
-
enough to 5 we can construct a solution of T 1 < 5 < T 2. solution on
(6) on IT1, T 2) where
By local uniqueness this solution extends our previous [o,T)
and thus violates the m a x i m a l i t y of 5.
= ~ , so the solution exists on that it exists on the interval
It remains to show that
[o,~)
and a similar proof shows
( -~,o].
I IA~(t) I I is apriori bounded on any finite
interval where the solution exists. The solution of on any such interval,
I IA~(t) If <
Therefore
(6) satisfies
(7)
so
I IA~oll +
I
t Ie_iA (t_s) I AJ(~(s)) lids
o
<_ r l~,orr +
by
(Hi). By hypothesis,
o
c(ll,cslrl~
I FA,(s) Ids
I l~(s) I I is bounded on any finite interval
w h e r e the solution exists, say by CI(T). Since C(-)
[o,T)
is locally bounded
we have
r1A~(t) ll <_ I IA~oll + C(Cl(T)~
f
t
o
IIA~(s) llds
for all t < T. By iteration this implies that
l i A r ( t ) II ~ I I A ~ o l l e t C ( C l ( T ) )
w h i c h shows t h a t
J l A ~ ( t ) ll
The original
i s b o u n d e d on [ o , T )
idea of using this abstract formulation to prove
e x i s t e n c e for non linear w a v e equations I and 2 and also the theorems his ideas
if T is finite.
is due to I.Segal~l]. T h e o r e m s
in Section 3 are simplified v e r s i o n s of
(see also R e e d [ ~ ] a n d Reed and Simon[~6]).
This is further dis-
cussed in the notes to Section 3. Other h y p o t h e s e s on J and A guaranteeing local and global existence can be found in Browder [~]. Wahl
[40~ treats the case where A depends on t.
W. yon
-
I i -
2. A p p l i c a t i q n s
In t h i s Usually, estimates general,
Finally,
and sometimes
one passes
Therefore,
first
that
usual
calculations.
nature,
In
vectors
of A b y a l i m i t i n g
for
argument.
functions
inequalities.
some extra
Although
it is i m p o r t a n t
we will do most
the requisite
many
of
to under-
and
Sobolev
say that
of t h e t e d i o u s
estimate.
After
the technical
tech-
that we
details
are
example.
we restate
I u,v~L2c~'~,
ll'II
on Sobolev
set of n i c e
vector-valued
example
estimates
B = ~- A + m 2. F o r
Notice
may be applied.
through.
-__~u + m 2 u = - l l u l P - l u
{
where
the
to the
known
convenience
~=
full d o m a i n with
tedious
on a d e n s e
to u s e e n e r g y
first
and prove
just quote
utt
them
in o u r
nical details
For
to the
theorems
, i = O,l,depends
long and rather
are o f a " t e c h n i c a l "
stand how to carry
(A)
on
(H i ) , (H~)
are v e r i f i e d
are necessary
details
similar
show how the existence
since we are dealing
arguments
will
we
hypotheses
the estimates
A and then
these
section
proving
always
,
I > o,
the basic
m > o,
n = 3,
definitions:
11ll 2 ~ llBull~2 § iivll2 % = e~, denotes
we define
the norm on~
L p n o r m o n R 3 . As p o i n t e d
D = 3
out
in t h e
J(~)
and
< | }
=
If-If D w i l l d e n o t e
introduction,
Io I) A = i
is s e l f - a d j o i n t
Sobolev
f
~
by
:
{ ~
of t h e e s t i m a t e s
simple
o
on
D(A)
All
-B 2
in t h i s
inequality.
and various
I u(D(B2),
example
We denote
universal
v~ D(B)}
are based
the Fourier
constants
will
on t h e
transform
be denoted
following of a function b y K.
-
Lemma
I
Let
Proof: Denote calculus,
uEC~
(R').
Then
~u(x)/~x i by
12 -
Ilull,
~ KIIBulI,
~i u. Then by the fundamental theorem of
lucx) l ~ ~ 411u'aiuldxi where the integral is taken over the llne where x. is held fixed for 3 j # i. Thus,
,o,x,,~_,~Cf,u,~u,,~ >" ([,u,~u,,x )~' r
u,,~ ) "
By integrating both sides (by iterating the integrals) and using the Schwarz inequality, one obtains
fR, lUt~O x --<
K(fR. lU.~.uldx )~= ([R.!u., uld ~ ).~ C/R. fU~ utdx R3
R3{%X u]=dx )
From this one easily obtalns
s,[Ul'dx
_< Kr
= KClIklQ]I,
,
+ Ilk
= ~llBull, |
all , * Ilk
,
QII , ~
)lr~
-
1 3 -
To e~tend this e s t i m a t e to D(B),we need:
Lemma 2: B is e s s e n t i a l l y s e l f - a d j o i n t on C o
Proof:
(R ~).
By using the Fourier t r a n s f o r m it is clear that both B and B 2
are e s s e n t i a l l y self-adjoint on the Schwarz s p a c e ~ ( R n ) .
Now let u s
n)
be given.
Since C~(R 3) is dense in ~ ( R n) (in the ~ ( R n) topology) we o LZ L2 can find UnEC (R S) so that u n , * u and B2u n ) B2u. But,
llB(u n - u) ll ! I I ( B~
+
! ]IB2(Un
I)(u n
-
u) ll
-
u) lT + flun
-
urJ
) o
T h e r e f o r e B r e s t r i c t e d t o ~ ( R n) is in the closure of B r e s t r i c t e d to C~
(Rn). Thus, B is e s s e n t i a l l y self-adjoint on C~(R').
Lemma 3
Suppose that u
!
, u , u ~D(B). 2 3
I
Then
lluu=u 11 2 -<- KrlSu, rl 2 11Su 11 2 lIBu 11 2 1 Pr___ooof Let u s
Since B is e s s e n t i a l l y self-adjoint ~n Co(R3), we
can find a sequence of C ~ ( R 3) functions u n so that Un L _ ~ u, and L2 Bu n > Bu, and by passing to a subsequence if necessary, we may assume u n converges p o i n t w i s e to u also.
I lu~
-
u m~
II 2
=
II
(u~ + UnU m +
(u n
-
u m)
! Kllun
-
umll61](u~
<
--
But
um) ll
+ UnU m
+
2
Um)]l 3
~IIu n- Umll (llUnll 26 + llUnll 6
_< K [ [ B U n
_ BUmll2(lIBUnll,
2 +
ilBunl
I[Uml[
6
+ llUm[l 2) 6
I 2 iiBUml
[~ +
TlBUml]~) ,
-
so {u~} u3eL~.
is C a u c h y
in L 2 a n d s i n c e
it c o n v e r g e s
pointwise
to u 3 we h a v e
T a k i n g t h e l i m i t in t h e i n e q u a l i t y w e o b t a i n
IIull6 ' = The statement twice.
Lemma
For all @,,r
4
flu'If ~ _< K I I B u I I '
of the lemma n o w f o l l o w s by a p p l y i n g
equality
~,
I IJ(~,,) Proof:
Let
(by the c a l c u l a t i o n
- J(,~)ll
ll~u~
Kilr
u
l
p r o v e s the lemma.
Lemma
5
1
II 2
3,
< ~llBu 1 I
--
' < Kl1~
2 --
1
113
3)
I II = t l ~ , ( u,~ , - u 2~ 2 2 711 2
>11 2 (~lBu ; ] 2~ +
- r II(II~
which
Let @ ,r i 2
2
in-
_< c(ll~,
by L e m m a
in L e m m a
I IJ(r ) - J(r
< K]/B(u-
H61der's
J satisfies
~i = < m i ' v i > ' T h e n '
llJ(~,)II = and
14-
B~,il
2
IIDu 2 II 2 + It~u~ll 2~)
II ~ + II~ II l l ~ ' J
+ IIr
~)
, then
(11)
IIACJ(~) - J ( ~ ) ) I I _ < Proof
Let
r
ccII~, I , I I % I
=
where
,IIA~II,IIA~
uiGD(B2),
viED(B).
II)IIA~-A(hll We c o m p u t e
- 15-
IIBaiull
so, by Lemma
]]ai(u~)
~ = II ( [ k [
+ m ~)
2 = l{B2ul12
kiQ{{~
3,
]} ~ =
12uuai~ + uaai~][ ~ _< KllBull=llBaiul[2
Thus,
~ KIIBul[211B2uil ~ 2
3
§ ~m2ttu:%tI: 2
<
--
which
proves
II~i(u:U
K(llSu
the first
- u~U )ll:
1
~= I
{l~{{B2u, tl ~2 + m~llBu 2
inequality.
l{ ~) 6
To prove the second,
:. Ilu:~i(~ ~ - u~)lI:
we compute:
§ t t (u~ - u:)ai(%)t
i~
+ {12(tu ,.{" - lu t~) aiu, ll ~, .,- {121u l'ai(u,. -- u2)l[=
'{{s'(u
< K(I{Bu --
1
- u ){
2
1
2riB(u-
_< K(II~,I ~{IA(r
+ {IA~ll~(lIr
2
u ) { I ~ ]B~(u
- u ) l { ~)
- ~2) lI 2
+ II~
I)IIA(r
- r
~
-
16
-
Therefore,
l la(d(~ 1 )
d(~ 2 ))li 2
A211B(u2~u2~)I12 1 1 2 2 2 3
= ~ 2 _ [ I la i ( u : ~
+ 12m211u~,-
- %u:) I I ~
u2~
I I~
<_c(li~ li,II~211,11A~ II)lIA(~ ~- ~)II 2
+C(II~,II,II~II)IIA(~,
- ~)11 ~
w h i c h proves the lemma. We have several times used the inequality
IIBull~ _< KIIB~uil
J
The last two lemmas show that A, J, and ~ satisfy the h y p o t h e s e s of T h e o r e m 1 so ~ocal solutions exist. Notice that in Lemma 5 (formula (11)) we have a c t u a l l y shown the stronger hypotheses
(H') of T h e o r e m 2. 1 Thus, to prove global existence we need just show that I l$(t) II is uniformly bounded.
Let $(t) =
initial d a t a ~o = ~ D(A). D(BJ
T h e n u ( x , t ) ~ D(B 2) and ut(x,t)
as functions of x for each fixed t.
E(t)
Since
be a local solution of
if
- ~
{IBu(x,t) 12 +
u E L~(R3)~L6(R3)
= v(x,t)
We now define the "energy"
lut(x,t ) Ix + ~ l u ( x , t ) l ~ } d ' x
we have u E L ~ ( R 3) and since Bu and u t are also
in L 2 the integral on the right side makes sense. Now, we know that $(t)
(6) w i t h
from T h e o r e m 1
is strongly d i f f e r e n t i a b l e as a n ~ - v a l u e d
function
w h i c h means that u(t+h)
liB(
h
- u(t)
- st(t)) II
2
) o
(12)
-
17-
I I ( utct+h> - u tct~ ) - utt(t) If 2
as h
)
o. T h u s the first t w o t e r m s
t h a t the t h i r d t e r m
u(t+h)
in E(t)
is d i f f e r ~ n t i a b l e
are d i f f e r e n t i a b l e .
- ut,,:,),,.._
follows
(u(t) 2,u(t) 2) entiable
2
To see
n o t e that
,,u,,..,.,,,,u,,...,,,,C 2
(12), the r i g h t h a n d side goes to z e r o as
easily
o
- u(t)
I lu(t) <
By
;
that
h--~o and
u(t) 2 is s t r o n g l y d i f f e r e n t i a b l e .
is d i f f e r e n t i a b l e
so the t h i r d t e r m
'':+''-~ h
from t h i s
Z
it
Therefore
in E(t)
is d i f f e r -
and
E' (t) = ~ ( B u t ,
Bu) + ~ ( u t t , u t) +
1 + ~(Bu,
1 Bu t ) + ~ ( u t ,
(uut,u2)
utt)
~(u2,
+
uut)
1
= T ( u t, B2u + utt + llul2u) +
=
o
since u satisfies
B2u + utt
the s o l u t i o n
+
xlui2u
II~(t) I1 is
N o w w e can s h o w t h a t where
(B2u + utt + AIuI~u,ut )
exists.
Since
=
o
bounded
on any f i n i t e
interval
~ > o,
-~II~ct~II ~ < ~II~ct~II ~ + ~
f Iu~x,tll ~d~
R 3
= E(t)
T h u s we have v e r i f i e d following
theorem.
= E(o)
the h y p o t h e s e s
of T h e o r e m
2 and so we have the
-
Theorem
3
Suppose
I > o,
m > o
g ~ D((
- ~ + m 2) ua)
u(x,t)
, t & R,x E R 3, so t h a t
strongly for
in
La(R3).
differentiable
all t, u(x,o)
several
both
u(x,t)
= f(x),
real
and
remarks.
and u(x,t)
and
feD(
Then
there
t~----*
u(.,t)
L a ( R 3) - v a l u e d ut(x,o)
utt We m a k e
18-
Notice
that
satisfy
(12)
the
I > o
linearity
global
so that
existence the t e r m
is p o s i t i v e .
that
if this
even
is not
though
positive
Notice
that
assumption equation fied.
E D(-A
+m a)
and
(13) valued
u = ~.
then
Thus
u is
know
it is t r u e
makes
for
also can
we
cannot
that
(7)
remains
to this
that
(Theorems
the rest
hand
We w o u l d
sense.
1 and
of t h e p r o o f
On the o t h e r
For
equation
the p r o o f
just
like
to k n o w if we
one
if w e start
C~
(13)
since
gained
we
and
framework.
Given
3 is not
~(t)
some
in S e c t i o n
the general
Sobolev
functional
can s o l v e with
it since
bounded
(non-trivial)
technical
of T h e o r e m
The reason
we n e e d
abstract
easy.
is s a t i s -
(H~)
has b o t h
in the quite
2) and the was
the r e s u l t
example
was
integral
question
to r e a l i z e
term
on the
the
Thus
it is i m p o r t a n t
is t h a t
exis-
differentiate
E(t)
We r e t u r n
the K l e i n - G o r d o n
global
non-linear
is global.
on the data.
gained
hold.
depended solve
ex-
doesn't
the h y p o t h e s i s of
fact
to t h e non-
prove
of the
differentiable.
to show set.
result
solution
sense,
a dense
energy
1 since
the
be s t r o n g l y
argument
sometimes
~oE~,we
due
existence
dependence
results
satisfactory.
can
on the
in an a n a l o g o u s
continuous
lost by t r e a t i n g
classical
by Corollary
energy
global
to the
a general
show that
(in general)
we d i s c u s s
details.
For
E(t)
of c o n t i n u i t y
equality,
one
contribution
global
locally
kind
abstract
then
strongly
(part E)
existence
although
What we have
conserved later
fails then
depended
the
not
Finally,
see
= - lu 3
D and F below)
will
4 when
of t, u ( , t )
= - l]u[2u
(see D a r t s
#o ~ D(A). (7)
in the
is m i l d
the
But we c a n n o t
is that
continuously
if f and g are r e a l
result
We w i l l
condition
If the n o n - l i n e a r i t y tence
function
satisfies
Secondly,
ample
function
so by u n i q u e n e s s
utt - ~u + m ~ u
that
a unique
is a t w i c e
= g(x)
- Au + m 2 u
- A + m2), exists
in-
analysis
entirely in a c o m p l e t e l y
data,will
the
solution
-
remain
C ~ ? The
quired
(see s e c t i o n The
[I~].
and
proof
The
case
m = O
The
case
m = o
mates teed
on J
(except
as b e f o r e
in p a r t
Thus,
E(t)
as
v>)
in part
=
linear
(13)
was
to d e v e l o p e
which
we have
are re-
d u e to J ~ r g e n s the a b s t r a c t
presented
are t a k e n
not
changed
A, w h e n = ~(o)
bounded
remains
bounded.
on
A but
term
device.
We
choose
i. the
conserved
~ o E D(A), and
E(t)
f r o m this
as
+ moU>
constants) Of c o u r s e
+
(14)
J is n o w d e f i n e d
in J d o e s
+ lute
]Vul ~
in o r d e r
remains
following
as
- l[ul2u
by c h a n g i n g
by T h e o r e m
!! However,
of
Segal
by the
the e q u a t i o n
E(t) - ~
As
(and e s t i m a t e s )
- Au + m o U = - lu ~ + m o U
of the
(14) we h a v e
details
can be h a n d l e d
J(
addition
existence
stimulated
technical
and A are d e f i n e d
The
of g l o b a l that
and w r i t e
utt ~
but more work
Simon[~7].
The
some m ~ > o
is yes
3).
his w o r k
in~l].
from Reed
B.
first
It w a s
approach
answer
1 9 -
not
affect
so local
a n y of t h e e s t i -
existence
by r e w r i t i n g energy
which
the
in g u a r a n -
equation
is:
Iui }dx
is d i f f e r e n t i a b l e it f o l l o w s
and E' (t) = o.
that
(15)
+ Jut 12} dx ~ 2E(o)
to c o n c l u d e finite
By t h e
that
intervals
fundamental
as
I l~(t) I I 2 = we
also
theorem
need
11Bu(t) I I 2 +I lut(t) I 1 2 2 2 that
of calculus,
I lu(t) I [
2
-
u(t)
since
u(t)
so from
= u(o)
is a s t r o n g l y
(15) w e g e t
20
i
+
-
t
Us(S)ds o
continuously
differentiable
L2-valued
function,
that
Ilu(t) II~
_<
11u(o) I I
+ r 2E(o)
t
Thus,
I1 (t ir = !!r ul + m;rul + lutl l dx is a p r i o r i global case
bounded
existence.
on
Thus,
intervals.
all the
By T h e o r e m
statements
2, w e t h e r e f o r e
of T h e o r e m
3 hold
get
in t h e
m = o. The case
because
rates
m = o
(-A + m2) -I
difficulties
is o f t e n
(in t h e
Because
cases
can be handled
tence
theory
treated
is u n b o u n d e d
and because
of decay
different.
C.
finite
the
separately
in t h a t c a s e c a u s i n g
scattering
s u p norm)
theory
of solution
of the above
device
on an e q u a l
in t h e
literature,
some technical
is d i f f e r e n t
of the
at
least
since the
free equation
(see S t r a u s s [ ~ 7 ] ) ,
footing
are
the two
as far as t h e
exis-
is c o n c e r n e d .
O t h e r ~,
n,
In o r d e r
to discuss
and
the
equation
u t t - Au + m 2 u = - ~ l u l P - l u
for v a r i o u s
both
p a n d n, w e
lev estimates.
state
The proofs
u(x,o)
= f(x)
ut(x,o)
= g(x)
the
following
generally
consist
x GR n
(I)
special
cases
of t h e s a m e
of t h e sort
Sobo-
of t r i c k s
-
we
used
See,
above
in
lemma
for example
Theorem
4
Friedmann
(Sobolev
o < a < 1
1 plus
appropriate
, and
Let
for
all
m and
SUDpOSe
1 p =
Then,
use
of
interpolation
theorems.
[IOB
Estimates)
, 1 < p < ~
21-
1 2
u E C ~o ( R n ), t h e r e
n be
positive
integers,
that
am n
is a c o n s t a n t
K so
that
Ilollp _< KIIDmul[allull x-a2 2 except
when
both
and
a =
integer
of the I.
[IDmu[[2 2
Let same
us
see when
analysis
as
these
A and
carry
through
our
is a n o n - n e g a t i v e
permit
us t o
carry
through
the
Let
~
L 2 (R n)
as b e f o r e .
same
m ~ n/2
n m ; ]I (~-~.) u1[ 22 j~l j
estimates A.
= D(B)
B defined
hold:
above,
denotes
in p a r t
~o
with
following
In the
(16)
methods
Now, we
J(~)
need
=
an e s t i m a t e
- llulP-lu> of
the
so to
form
11uEl2p ~ KIIBulI~ As
indicated
in p a r t
A, w e
can
r
always
estimate
I IDu] I
and
I lull
2
I IBui I 2.
So
it f o l l o w s
from
(16)
that
(17)
will
hold
by 2
in t h e
following
cases:
n =
1
,
2 < p < ~
n = 2
,
2 < p
n = 3
9
2 < p < 3
n = 4
,
p--
< ~
(18)
2
-
In a l l o f t h e s e hypotheses data
cases
Er
Thus, er
if
~ > o
Theorem the
5
clvul Rn
we g e t
Let
of T h e o r e m if
This
theorem
is r e a s o n a b l y
will
to hold
can become
class
later
of e x a m p l e s
L e t us d i s c u s s
where
as
(19)
it w i l l
E(t)
if t h e
uI~
dx
Since
the
in t h a t
strong-
case.
The
(18).
Then
w e have:
in t i m e
in
if
i < o
and
(i).
since we do not
case
I < o, s i n c e
both
still
conserve
energy.
the
that global
expect
lie(t) I 12 a n d
existence
In fact, does
not
the
Notice,
equation
that
not
initial
we
in
- Au + m ~ u = - lu p
if p is odd b u t be
initial
I < o.
for a m o m e n t
p is an i n t e g e r .
ces t o
Thus,
locally
(part E) when
the
for n i c e
ll.
existence
B.
satisfactory
and
utt
and
o n e of t h e p o s s i b i l i t i e s
in t h e
large
in p r o v i n g
+
II~(t)
I > o for t h e e q u a t i o n
show explicitly
a whole
lutl')dx
+
bound on
3 hold
in t i m e
~+l[lUl p
lul '
in p a r t
p and n s a t i s f y
existence
in p a r t A,
we get global as
globally
global
as
involved
energy:
an apriori
is h a n d l e d
conclusions
same
+ m
(H i) h o l d s
zero case
details
a conserved
I
=
hypothesis
mass
1 are t h e
we have
= Ect
-
the technical
of T h e o r e m
~o e D ( A ) '
22
if u is r e a l - v a l u e d
i~ p is even.
data
(19)
are real,
= I ((Vu) 2 + m 2 u 2 + u ~ ) d x
+
Assuming (19) h a s
~1- ~
then
(I) r e d u -
u is r e a l - v a l u e d ,
a conserved
energy
!uP+Idx
Rn
We can
only
insure
a n d p is odd. these
cases
by the
that
So we
it is g i v e n
same methods
as
be a simple
conserved
pect
existence
shown
global
in p a r t E t h a t
the term
only
expect
on t h e r i g h t w i l l global
by Theorem in p a r t A.
energy
but
anyway. global
existence
5.
When
For
complex
it d o e s n ' t
In f a c t
existence
be positive when
p is e v e n w e valued
matter
if I > o
D is o d d
u there will
since we don't
in t h e c a s e m = o, n = i, doesn't
hold.
and
can treat
in (19) not
exit is
-
We now
consider
the
Since we do not have begin
to try to prove
However,
we
consequences integer
strong
we work.
when we
k so t h a t
local
holds.
t r y to p r o v e
a Sobolev
By T h e o r e m
b e done;
~k
with
=
depend
{
on o u r
see
global
! xl
covered
form
if w e
change
shortly,
(18). even
the Hilbert
this has
existence.
Bkul[
in
(17) w e c a n n o t
s p a c e ~ O = D(B) ~ L 2 ( R n ) .
of the
Choose
unfortunate a positive
form
(20) 2
techniques on n.
not
of t h e
existence
inequality
4 and t h e
k will
cases
As you will
ilull
ways
in t h e estimate
local existence
can p r o v e
space with which
problem
a Sobolev
23
of
lemmas
2 and
3 this
can
al-
Now we define
I u eD(B2k+l)
, vs
the norm
ILll 2 = ILB2k+luli 2 + lIB2kvli2 We
let A b e t h e
same operator
D(A)
A is
self-adjoint
introduction. that the
= {
J($)
So,
=
following
and generates
-luP>
the
to get
which
of l e m m a
it r i g h t .
we will
Let
L IJ(~)I[~
D(B2k)}
group
One need
just
side
discussed
we need
B as t h o u g h
just
of T h e o r e m it a c t s
in t h e show i.
Then
= i~i l lB2k(u p) I[
is l e s s t h a n
Kli(Bk~u)
2 or equal
to a sum of terms
of the
,,, (Bk'u)[l 2
where
2k = I k. i=l i
In
on u p b y
use the technique
$ = ~k"
k and the right
W(t)
existence
the hypotheses
treat
it d o e s n ' t .
v
same
local
and A satisfy
B ( u p) = p u P - i B u ,
but now
I u GD(B2k+I),
in o r d e r
calculation
4 to d o
as b e f o r e
and the k i are non-negative
integers
less
than
or
form
-
equal are
t o 2k.
less
Let k I be the
than or equal
-
largest
t o k.
k i.
Thus,
9 9 (Bkpu)[[
KI [ ( B k l u ) .
24
Then
a l l t h e k i for
i > l
we can estimate:
2 ~ ~llBk'ul 12 ~
llBk~ull
! KllB2k+lull,~llB~+k ull
< KIIB2k+IulIP 2
KII~IIp
w
where
we have used
(20)
in t h e
second
step.
Thus,
<
The
other
estimates
Therefore,
Theorem Then g s
we can
6
Let
there
of Theorem
integers
is a n
n > o,
integer
- A + m2)k+T),
differentiable
1 are proven
then
(in t)
p > 2
k so t h a t there
function,
utt(x,t)
- Au(x,t)
if
is a
possible one would
Further,
t g ( - T,T). - A + m2) k + ~
The problem
with
this
for ourselves expect
s a m e way.
which
+ m2u(x,t)
it
)
u(t)s
for e a c h
result
(for o d d p).
and
twice
strongly
satisfies
= - Au(x,t) p
=
f(x)
= g(x)
- A + m2) k+l)
t ~ ( - T,T).
is t h a t w e h a v e n o w m a d e
to prove
~ be given.
~ A + m2) k+l)
T > O and a unique
u(t,x),
ut(x,o)
ut(t) e D((
the
and any m > o and f 6 D((
u(x,o)
for each
in e x a c t l y
state
global
existence
The difficulty
it a l m o s t
im-
in t h e c a s e s w h e r e is t h a t w e m u s t
show
-
25-
that the n o r m In ~ k
ll~(t) ll ~ = lIB2k§
2 § ilB2kutll 2
does not go to infinity in finite time.
From the energy inequality
(for odd p) one only gets that
llBuli~2 § 11utI[22 stays finite. One might try to use this and some higher order energy inequalities to prove that has been able to do this. weak
I [~(t) il~.~ stays finite, but so far no one It is known however that for odd p global
(in the sense of distributions)
solutions exist
(see Section 5)
and also that global solutions exist if the data is small enough. we have the following intriguing situation:
Thus,
e x i s t e n c e of strong so-
lutions locally, e x i s t e n c e of w e a k solutions globally, but no strong global e x i s t e n c e proof.
The use of the space
"~k' so called "escalated energy spaces",
has been r e p e a t e d l y e m p h a s i z e d by C h a d a m [3 ], [ ~ ], [ ~ ], [ 6 ] . In p a r t i c u l a r C h a d a m has used t h e m to prove local e x i s t e n c e for the coupled M a x w e l l - D i r a c e q u a t i o n s
in three dimensions.
We discuss this
further in Section 6.
D.
The s l n e - G o r d o n e q u a t i o n
We can easily apply the e x i s t e n c e theory to the equation
utt - Au + m2u =
when the number of space d i m e n s i o n s
g sin(Re{u}
is
(21)
)
n = 1,2,3,
or 4.
If the in-
itial data are real then the solution w i l l be real and thus w i l l satisfy
utt - ~u + m2u =
which
g sin
is known as the s l n e - G o r d o n equation.
(u)
(22)
We treat the real solutions
-
of
(22) by studying
(21) because
Re{u}
instead of and u
u
is bounded
does not affect the technical details
functions.
complex case,
for all complex
in the imaginary directions.
have the same d i f f e r e n t i a b i l i t y
also treat the real solutions of real-valued
-
sin(Re{z})
z while sin z grows exponentially Re{u}
26
But,
properties.
space of
since most of our terminology (21).
since One could
(22) by using a Hilbert
it is easier to treat
Using
is from the
For ease of notation we will
write Re{u} = a from now on.
~=
To begin with, we suppose D(B) ~ L2(Rn), and
A=
i
(o -B 2
I) o
just as in part A.
D(A)
The estimates of T h e o r e m
=
Ilsin
and define
= D(B 2) ~
B=
D(B)
~ll~
=
g
_< I l u l l
~ _<
II~ll
(sin ~,B2sin u) 2
n = ~ (~isin 0,~isin ~) + m 2 (sin ~,sin 0) i=l *
<
2
1 are proven as follows:
2 = IIAJ(#)II 2 = liB sin ~II 2
--
~
But, now we have
J(#)
IIJc~)ll
m > o
llvull:
KIIBulI~
+m21Jull
~ 2
_< KII+II ~
(23)
- 27 -
{{J(q~) - J(*) {{ = [{sin 5
- sin 5 {{ {
2
_< {{u - 5~ {
w h e r e ~ = 1
and
~ =
1
2
2
Finally,
I[A(J(#)
-
J(*)){l
=
JiB(sin
5
-
I
= II ( B 5 ) C O S
5
1
--
1
1
_< I{ B2u,II2
11+-,{{
sin
1
5 ) { 2
2
-(B5 )cOs 5211 2
2
2
2
1
lIB(u| - u2)I12
2
+ .l'{B(ul - U2 ) I12
ILA+I{ § {{+-.11
In this last computation we have again for ease of exposition treated B as though
it acts by differentiation.
Note that~the next to last
step is the only place where we use the fact that the dimension because we needed the Sobolev
is < 4,
inequality
< KKIBu I{,llBu~ll~ Since the extra hypothesis show that tence.
[l~(t) l] is bounded
Unfortunately,
(for all g,m).
on finite
intervals to show global exis-
(21) does not have a positive
But the fact that the n o n - l l n e a r i t y
us to show apriori boundedness equation we get
(Hi) of T h e o r e m 2 holds, we need only
of
II~(t) 11 anyway.
conserved energy is
mild
allows
From the integral
-
II~(t)
ll < I
Ie- iAt @~
28
fl + II !
-
[te-iA (t-s) J(r
I
t 0
t
Io l IJ(r
_< I I%f
+
_< I(%l
+
(~(s) IIds
Ir
~ IIr
so by iteration
Thus
lie(t) II
is b o u n d e d on bounded
solution exists globally. part B.
intervals so by T h e o r e m 2 the
The mass zero case is handled just as in
We summarize:
Theorem 7 given.
et
Let
n = 1,2,3, or 4 and let
Then for each
m E [o, ~) and ,g geD((-
f 9 D(- A + m2),
e
(-~,~) be
A + m2)/~') the initial
value p r o b l e m
utt - Au + m2u = g sin u
u(x,o)
ut(x,o)
= f(x)
=
g(x)
has a unique global solution u such that u is twice c o n t i n u o u s l y d i f f e r entiable as an L2(R n) -valued function of
t, u ~ D ( -
A + m 2)
and
1
utED((-
A + m2) T)
for each t.
N o t i c e that if we just want to solve the integral e q u a t i o n
~(t) = e -iAt + Ite -iA(t-s) i "O instead of
~' (t) = - iA~(t) + J(r
J(~(s))ds
-
then, by C o r o l l a r y
C.Lo
29
-
1 of T h e o r e m i, we only need the h y p o t h e s i s
IIJcr
- J(r
<_c~IIr
II~- ~I
Since this h y p o t h e s i s holds for the sine - Gordon equatlon in all dimensions
(we only used the Sobolev inequality
IIA(J(r
- J(~)) I [) we conclude that
all dimensions.
(21) has w e a k global solutions
By weak, we mean here that the c o r r e s p o n d i n g
e q u a t i o n has a continuous Y - v a l u e d
E.
in our e s t i m a t e for in
integral
global solution.
A__nnexample when global e x i s t e n c e fails
Let us consider the equation
(24)
utt - Uxx = u p
u(x,o)
ut(x,o)
=
x eR
Uo(X)
= Vo(X)
w h e r e p is an integer ~ 2. We know that local e x i s t e n c e holds and, antic i p a t i n g Section in
CO
(i.e.
3, we can g u a r a n t e e that if the solution u starts out
uO ~Co(R),
vo&C
(R))
then on some finite t interval
the solution w i l l be twice c o n t i n u o u s l y differentiable.
Further,
another result of section 4, it w i l l have compact support.
using
These
r e g u l a r i t y statements don't affect the ideas below, they just a l l o w us to integrate by parts w i t h impunity.
If
uo
and v o are r e a l - v a l u e d
then u will be r e a l - v a l u e d and
E(t) =
{ (Vu) 2 + m2u 2 + ut2
2 u p+l } dx p+l
R
is the c o n s e r v e d energy. any
Thus we do not expect global existence
p ~ 2. We will show that if
u ~ and v o are chosen correctly,
F(,t) = IRU(X,t) 2dx
for then
-
goes to i n f i n i t y initial data
Then
30
in f i n i t e time.
u~
and
vo
-
S u p p o s e that we can find an ~ > o and
so t h a t
(A)
(F(t) -e) " < O
for all
(B)
(F(t)-u) ' < O
at
F(t) -~
w i l l go to z e r o
(B) is a u t o m a t i c a l l y same sign on
(-~,~)
(F(O)-U)'=
It r e m a i n s
satisfied
Q(t)
t = O
in f i n i t e time; by choosing
uo
see the Figure. and
vo
Condition
tO h a v e the
since
- u F ( O ) - I - a F ' (O) = -2eF(O) - I - ~ I U o V o d X
to a r r a n g e
same s h o w i n g t h a t
t > O
for
Q(t)
(A) to hold. > O
Since
F(t)
> O
this
where
- (-u)-IF~+2(F-~)"
= F"F-
(e+l) (F') 2
But, F'(t)
= 2fuutdx
F"(t)
= 2f(UUtt + u~)dx
= 4,o .,-,,f,.,,~dx-,-~f,u,.,t,=-,~o-,-,,,.,,~,oSO~
o,~,.,,o~,,
{Cf'."dx)Cfu,~d-t-{f,.,u, dx)']
is the
-
31-
2F,t{fuutt0x f,2o§ The
first
we need
The
term
only
on t h e r i g h t
arrange
conserved
That
is,
2(2~
+ I) = P
E(t)
that
energy
if
E(O)
= !(n-l) we
scale
is i n d e p e n d e n t
> O
by the
Schwarz
inequality,
so
where
iS
of t.
Thus,
if w e c h o o s e
e so t h a t
+ i, w e h a v e
< O,
then
> O. Now,
= -
~+l)E(t)
+ 2~ lu~dx
=
~+I)E(O)
+
-
H %s a l w a y s
choosing
eventually
F(t)
If we
(241
u ~ by m u l t i p l y i n g
(this w i l l data,
H(t)
for
H(t)
Thus,
is p o s i t i v e
goes
to
consider
u o > O,
infinity
since
v
P+I
in f i n i t e
- Uxx
=-
> O
positive
For
(B)
until any
time.
U p
since
so t h a t
constant
> 2).
the d i f f e r e n t i a l
utt
lu~dx
strictly
by a nositive
happen
instead
2~
(24)
equation
such
is s a t i s f i e d
E(O)
< O
initial
-
then
H(t)
again satisfies
E(t)
= ~
(24),
(u~ +
If P is even then by c h o o s i n g (B)) w i t h
but now the c o n s e r v e d energy is
Uo(X) ~ O,
Vo(X) ~ 0
u ~ s u f f i c i e n t l y large we can obtain
E(t)
E(O)
(thus s a t i s f y i n g < O
and thus the
If, on the other hand, p
is odd,
is always greater than or equal to zero so the above argument
does not work. existence
-
I
solution blows up in finite time. then
32
This
is not s u r p r i s i n g since we have proven global
in this case in parts A, B, and C. Notice that we always had
to choose the initial data large in order to get the solution to b l o w up. Later we will see that if the initial data are small enough then global solutions exist independent of w h e t h e r p is even or odd or the sign of i.
The author learned this simple example from H.Levine ~8]. details are taken from R e e d - S i m o n [~7]. Examples of n o n - e x i s t e n c e of global solutions have been known for a long time. Keller
[|6]
or Glassey[||].
See for example
The
-
F.
The Coupled In part
riate
saw that
A much
proof~5~
and K l e i n - G o r d o n
t w o b y two
T h e n we
can w r i t e
the
(F i)
free
~(t)
We w o u l d
= <~i (x,t)
like
to
solve
g is a r e a l
function with
8~(t).
bounded to
coupling
below
lose by
These and
coupled
constant,
equations
Since
(F
4)
(F 2) w i t h
8 is H e r m e t i a n
As u s u a l
we r e w r i t e
u(t) (F3)
d
(for one
u(t)
denotes
have
Let ~ and 8 be
space
dimension)
function
= u(x,t)
as
on R 2.
is an R - v a l u e d
the dot p r o d u c t
a conserved
not much
use.
energy
in C 2 o f
but
~(t)
it is not
So w e d o n ' t
have
anythimg
defining
= Re(u(t))
u(t)
on the r i g h t
will
remain
as a first
d--t ~(t)
coupled
- igSu(t)~(t)
be c o m p l e x - v a l u e d ,
u(t)
and r e w r i t i n g
ex-
= ~(t). 8~(t)
~(t)'8~(t)
u(t)
.
CZ-valued
- me8 )~(t)
is t h e r e f o r e
letting
of g l o b a l
for t h e Y u k a w a
= -i ( i e ~ x - me 8 )~(t)
= -i ( i e ~ x
on R 2 , and
equation
system
utt - Uxx + m o U
conserved
satisfy
is a
(F 3)
the
8e + e8 = o
p
Dirac
in an a p p r o p -
though
example
existence
, ~2(x,t)>
d ~(t)
where
striking
the
(F 2)
is "mild" even
in o n e - d i m e n s i o n
which
I = 82
d ~-6 ~(t)
~here
more
equations
:
existence
of g l o b a l
Hermetian matrices
e2
Equations
if the n o n - l i n e a r i t y
can get g l o b a l
positive.
is C h a d a m ' s
-
and K l e i n - G o r d o n
t h e n we
is not
istence Dirac
D we
sense,
energy
Dirac
33
real
order
= -iAo~(t)
side if its
system
+ Jo (~(t))
instead
of
initial for
~(t)
u(t).
data
are real.
=
-
where
BO = ~
, Jo(~(t))
34
-
=
(o I1
AO =
-B~
Letting coupled
D e : ia~ first
- me8
order
and
and,
o
combining
(F2)
and
(F4) w e h a v e
the
system"
~' (t) = -iDe~(t)
+ Je (r ( t ) )
$' (t) = -iAor
+ Jo
(F 5)
where
Je (@(t))
Finally,
if we
: -igBu(t)~(t)
set
=(t)
J(=(t))
then w e can w r i t e
(F 6)
where
(F5)
:
= <J
e
($(t)),
is the
four b y
J
o
(@(t))>
as
-' (t} = - i A - ( t )
A
(~(t))
four
+ J(-(t))
operator
matrix
A(Oe o) o
Thus apply take
we h a v e
rewritten
the e x i s t e n c e as our H i l b e r t
our
theory
Ao
coupled
equations
of S e c t i o n
I.
Bet
in a f o r m so t h a t w e can B
e
space
~-~= D(Be) (~ D(Be) ~)D(Bo) ~} L2(R)
=v~-m
r . e
Then we
-
where the norm of ~ = <@i'42'
35
-
u,v>
is
= I IBe@, 1122 + [ IBe@2 I [22 + llBo u1122 + [ I V l ] 22 A is self-adjoint
on
D(A) = D(B~) O D(B~) (~) D(B O) ~) D(Bo)
To see that J is a well-defined equality
mapping on ~ we use the Sobolev
in-
If(x) I I~ < cl If (x) [ I2*/2 llf(x) i [1/2 2
(F 7)
,
valid in dimenslon
n = 1 (see
part
C).
This implies
[ Ifi]~ ! C] IBef]l~ 2
[f]]~2
I Ifl I~ ~ cl[Bofl I ~
Ifll ~
and 2
Now I [J(~(t)) I I 2 has terms of the form IBe(U~i) I I2 and of the form [ [~.8~I I 2 and we ca~ estimate (treating the B's like differentiation 2
as u s u a l ) I IBe(U~i) I12 ~
II@il I. I IBeU112 + IIBe@i1121 lul 1~
< c[ IBe~i112
_
I IBoUl I 2 + I IBe~el
211BoU112
< c11~If 2
and similarly for the other term. We have used the fact that BelBo and B-IB are bounded (by the functional calculus). In fact, using o e this same idea one can easily check that J satisfies hypotheses (H~) and (H~) for m = o,i. Thus we get a local solution of (F6) by Theorem I. Our problem is to get a global solution. Since (H I) is satisfied we need just show that I l~It) I I is apriori bounded. But we cannot use the conserved energy to do this since it is not bounded below so
-
36
-
our only hope is to use tee integral equations directly (as we did for the sine-Gordon equation). The two integral equations are ~(t) = e-iDet~(o)
+ It e_iDt (t_s) je (#(s))ds o
~(t) -- e-iA~
+
it e_iAo(t_s) jo (~(s))ds o
so
II*(t>l
e
<__ c e
+
I*]lJer
lledS
o
(F 8)
[[~(t) l ~ < C 0 + where the
[[" [ I e
and
ll:
I ' ]1 0
12=
I*o
norms are defined by
I,II:+
=
ll,lro 2 + JiBe,2112
I[~11~ = IIBoull ~ Using
llJo(~J(s)) llodS
+ Ilvll ~
(F7) , we have 2 I IJe(~(s))
l e <-- ~ i =Il
lIB e(~u, i>ll
2
2 (F 9)
!c
[ {ITBoOlI
i=l
2
TIBe*ilr~z[l*ill~ +
IBoUl i~ 21 l~I l~al } 2IBe*il I2
and IJ ~ (~ (s))
(F lO)
Io = I1~,~*11
< c{llBe**ll~2][r
I~ 2 § I I B e , z l i ~ l l , 2 1 1 ~ }
-
So far, the situation (F9) and
(FIO)
37
-
looks pretty hopeless
are quadratic
expressions
since the right side of
in the norms
so we can't expect to get anywhere with
we can't get anywhere unless we use more information system
(F2),
(F3).
I I. I Ie and
(F8) by interation.
about the coupled
So far, the only property of the matrices
which we have used is that they are Hermetian Using the other properties
(so that
De
e and 8
is Hermetian).
of e and 8 one can easily show" (see for ex-
ample Bjorken and Drell I t ] o r Chadam IS])
that the total electric
l~1(x,t) 12dx +
Q (t) = [ L=
I I" I 10
In fact,
charge
(x,t) 12dx
J
Q(t)
is a conserved quantity;
= Q.
This
is an immediate held for
(FIO)
can now be written
I IJoC~Cs)) 1 !o _< c {11 Be~, I1~'=+
(F iI)
< cll~r
conservation
}
w~
--
However,
IBe~ll~ ~
e
of charge as it stands
is only a small help for
(F9) which can now be written
(F
2 12)
I 1JeC~Cs)) I le
-< c I i=l
{llBo~ll ~ IIBe~ill
Our only hope to make this better Fortunately,
u(t)
Uo(t)
propagation
is to get an estimate
we can do this by using special properties
gator and conservation
where
of charge(again!),
= Uo(t)
is the first component preserves
Thus,
u(t)
ll~llBehll on
the norm
of
e-iA~
of the propa-
satisfies
the equation
Since the free
I IBoUI I2 + I lutl [22 we have
I1~~lluor
ll[ ~ _< c
}
I ]u(t) I I~.
+ st [B -i O sin Bot ] Jo(~(s))ds 0
1 lUo(t) I1= <_ cl IBoUor for all t.
~= + II~(t)
2
-
(F i31 lluCt) ll. < c
+ st lIFBT~oi
38
sin
-
BoCt-s)l. Jo(~(sllll
Now P B-Isin Bot acts by convolution by a function o is the inverse Fourier transform of (k2+m~) - ~ sin Since
Jo(~(s))
the L* Thus,
is quadratic
norm of if
Jo(~(s))
I I (Bol
for all s and t. properties
~i(s)
H(x,t-s)
which
(~r~t-s))
and charge is conserved,
is uniformly bounded
llH(x,t) nl, ~ c
(F 14)
in the
as
independently
of s.
we can conclude that
sin Bo(t-s))Jo(~(s)) II = _< c
One can compute the inverse Fourier
of B e s s e l functions
to conclude that
transform and use
I IH(x,t) ll~ ~ c
but
the easiest thing to do is to notice that the inverse Fourier transsin kt form of k is uniformly bounded for all t since it is just a fixed constant times the characteristic
function of an interval.
On
the other hand sin t ~
sin t k k
is an L~ function whose L* interval.
norm is uniformly bounded on any finite t
Thus
I IH(x,t-s) for s and t in an finite interval. Then for
CF ~5)
t 9 [- T,T]
I I%C~r
Therefore,
,
Choose such an interval
t lu(t) I I= ~ c,
so
< o{ll~r162
(FI2)
becomes
e,/z + I]~(s) l[e}
if we set f(t) =
g(t)
then
I I~ <__ c
(F8) becomes
the following
=
l~r
[Io e
set of coupled
inequalities
[- T,T]
-
39
-
(F 16a)
g(t) 2 < c e + a ft (f(s)g(s) o
(F 16b)
f (t)
where
into the
t o g(s)ds
s
< Co + b
a can depend
equality
o n T b u t n o t on t. first,
+ g(s) 2)ds
Substituting
the
g(t) 2 < c e + ac ~
(s)ds + a
g(s)2ds
+ ab
o Using
the
Schwartz
inequality
on the
g (t) 2 <_ Ce + d
where
d depends
bounded f(t)
on
on T b u t
[- T , T ]
.
is a l s o b o u n d e d
proven
that the
interval This
the method
Using
the
show the
existence
mensions
energy of
local
However,
is open.
in-
of
second
i
(r)dr ~o
and
fourth
terms,
Therefore, back
into
by
iteration
(Fl6b)
Since T ~as
arbitrar~
is a D r i o r i
bounded
by Theorem
2.
spaces strong
in o n e d i m e n s i o n coupled
solutions
the question
in D a r t
For more discussion,
on a n y
finite
equations.
6.
can easily
dimensions
existence
see S e c t i o n
we have
c, o n e
in t h r e e
of g l o b a l
is
that
is d u e t o C h a d a m [ 5 ]
Maxwell-Dirac
introduced
g(t) ~
we conclude
(F6)
to the
we have
t o g(s) ~ds
globally
existence
is a p p l i e d
escalated
(Chadam[~]).
H(t)
exists
of g l o b a l
where
o n t.
[- T , T ]
solution
and therefore proof
not
Substituting
on
second
we have
in t h r e e d i -
3. Smoothness
of Solutions
As we have remarked before, not completely ple we would smooth
satisfactory
the existence theorems
hypotheses
1 are
For exam-
like to know that if we choose the data ah time zero to be
(say C = ), then the solution of
the equation
in Section
from a classical point of view.
in the classical
are needed.
sense.
(i) will stay smooth and satisfy Essentially
In our examples
A = if~
the powers of A, Where
I 1 ~-m 2
act like powers of the Laplacian
two kinds of further
.
o
So,
if the solution
~(t)
remains
in the domain of high enough Dowers of A then we should get smoothness in the x variables.
To achieve this we require only higher order esti-
mates of the same kind as
(H I ) , (H~) in Theorem
i.
Secondly,
looking
at our equation
~' (t) = -iA~(t)
(6)
+ J(~(t))
we can see that to get higher differentiability to assume some "differentiability" ~(t)
must remain
(Hi) in part
the d e r i v a t i v e s
powers of A.
on J awkward to formulate;
it works out quite easily
hypotheses
of ~ in t, we will have
Further,
in the domain of appropriate
factors make our conditions see,
in J.
in applications.
(a) below follow from
for easy comparison with Theorem 9.
but as you will
As in Theorem (H~).
of
These I, the
We state them thus
We will refer to the hypothesis
in part b below as "condition J " m
Theorem 8 (a)
(local smoothness)
Let A be a self-adjoint
mapping which takes satisfies
D(A 9)
operator into
on a Hilbert
D(A j)
for all
space W a n d 1 ~ j ~ m
J a and which
(for j = O,l,...,m)
(Hj)
I IAJJ(~) I I < C(I l#II ..... I IAJ~I I) I IAJ~II
(H3)
I IAJ (J(~)
- J(~)) I I < c(II~II,II~ll ..... IIAJ~rI,IIAJ~II)IIAJ~
- AJ~II
-
for all ~,@ ~ D ( A j)
where each constant
function
of all its variables.
is a T m
so that
~(t) 9 D(A m )
4 1 -
Then for each ~o ~ D ( A m ) '
(6) has a unique
for all
C is a (everywhere
t&[O,Tm).
solution
~(t)
for
finite)
m ~ I,
t~[O,Tm)
there with
For each set of the form
{~ I I IAJ~I I ~ aj, j = 0 ..... m}, T can be chosen uniformly
for ~o in the
set. (b)
In addition
has the following
to the hypotheses property:
uously differentiable
in (a) assume that
If a solution
with
for each j < m,J
~ is j times
~(k) (t)~ D(A m-k)
strongly
contin-
and Am-k~(k) (t) is con-
tinuous for all k < j, then J(~(t)) is j times differentiable, dJJ(~(t))/dt j ~ D(A mrj-l) , and Am-j-ldJj(~(t))/dtJ is continuous. Then the solution in
t and
Proof
The proof of part
Theorem #(.)
given
in part
(a) is m times
strongly
differentiable
d j ~ (t)/dt j ~ D (Am-j ) . (a) is essentially
1 except that we take
on [O,T m)
so that
X(Tm,e,~ o)
~(t),...,Am~(t)
the same as the proof of to be the set of functions are strongly
continuous
and
m
[
sup l IAJ~(t)
_ e-iAtAJ ~o
II < --
j=o t, [O,•
Then one proves that S is a contraction Part
(b) is proven by induction.
is strongly
continuously
By the same arguments
A~(t)
= Ae-iAt~o
=
A~(t)
(a) that ~(t)
and ~' (t) = - iA~(t)
+ J(~(t)~.
i,
+ A[te -iA(t-s)J(~(s))ds ~o
9 t A ~ o + [te-iA (t-s) AJ (~ (s)) ds e-lA ~o
and from this it follows that
We know from part
differentiable
as in Theorem
as before.
is strongly
(using another continuously
argument
in Theorem
differentiable.
I: see
Therefore
hypotheses on J,J(~(t)) is strongly continuously differentiable, dJ(#(t))/dt G D ( A m-2) , and Am-2dj(~(t))/dt is continuous. Thus, is strongly
differentiable, ~"(t)
d = - A~' (t) + d-t J(~(t))
(IO~
by the #' (t)
-
= (-iA) 2~(t)
#"(t) E D(Am-2), gument again
and
#(t)
-
- iAJ(#(t))
Am-2#"(t)
(dJ(~(t))/dt
know that ~(t)
42
d J(~(t)) + ~-~
is continuous.
is differentiable
is twice continuously
We now repeat the ar-
by hypothesis
differentiable)
is three times strongly differentiable
since we now
to conclude that
and so forth. I
Notice that the interval on which the solution exists depends on m. In particular, have slightly
T m may go to zero as stronger
estimates
m
>
and smoothness.
Theorem 9
and smoothness)
(global existence of part
As in Section
and apriori boundedness
then we get global existence
the hypotheses
~ .
of
1 if we
I I~(t) I I,
Let A, J, and ~ satisfy
(a) of Theorem 8 except that
for j = 1,2,...,m
(Hj) is replaced by
(H~)
IIAJJ(~)II ~c(II~II ..... IIAJ-X~II)IIAJ~II
Let ~ o E D(A m) and suppose that on any finite the solution
$(t),
(6) is global
in t.
I I~(t) I I is bounded. Further,
Then the solution
if J satisfies
m times strongly differentiable
interval of existence
of
~(t) of
condition Jm then
~(t)
is
for all t and satisfies
dd--•j-•(t)
( D(A m-j)
Proof
The idea is the same as in Theorem
existence showed
I I~(t) I I
is apriori bounded.
in T h e o r e m 2 that
IIA~(t) II ~
2.
On any finite
interval of
On this same interval we
IIA~oll
e K~t.
Now for
A2~(t)
we have the estimate
IIA~(t) II < IIA2%If § It I IA2j((~(S))
I Ids
o
<
lIAr%If + It c(l l~(s) il,llA~(s)ll)llA2~(s)llds o
by
(H89
Since we already have
ll#(s) ll and
ilA#(s) II
apriori
-
bounded,
43
-
C(I l~(s) I I,I IA~(s) 11) is less than some constant K 2 on the
interval in question.
Thus,
lIA~Ct~ll ! ttA~o]l §
I]A~Cs~EI ds
20
SO.
iiA2~t) lli 11A2~oltJ ~t
Now we have
I iA2~(t) [ i
bounded so we can continue in the same fashion
to conclude that
i TAJ~(t) i I
of existence for
j = l,...,m.
is apriori bounded on any finite interval
The length of the interval T m in T h e o r e m 6 on w h i c h the solution exists depends only on the constants Therefore,
C(I i%oI I + e ..... 11Am~ol I + e).
as in T h e o r e m 2 we can extend the solution past the end of
any finite interval.
So, the solution is global
in t.
The other state-
ments of the t h e o r e m follow from T h e o r e m 6. D
Corollary each m.
Let A, J, and ~ s a t i s f y
m = 1,2,... Then for each
the h y p o t h e s e s of T h e o r e m 9 for
And suppose~ that J satisfies condition Jm for each ~oE
/~D(AJ),
the equation
(6) has a unique global
solution so that ~(t)
is infinitely often s t r o n g l y d i f f e r e n t i a b l e and
each d e r i v a t i v e
~
~
is in
D(AJ).
First we will apply these ideas to
utt - ~u + m 2 = - u 3
u(x,o)
= f(x)
ut(x,o)
= g(x)
(25)
We use exactly the same set up as in Dart A of Section 2.
We need just
verify the higher order estimates and the h y p o t h e s e s on J in part b of T h e o r e m 6. techniques
The higher order estimates are easy and use exactly the same (i.e. the same Sobolev estimate)
I TAmj(~) If =
I IBmu~ll
2
as in part A.
For example:
-
The
t e r m on t h e r i g h t
form
I I (Bmlu) (Bm2u) (Bmnu) If
largest
II
is less
of
the
m.. 1
2
4 4 -
than
or e q u a l
with
m
< c IlBm+lul[ 1
2, p a r t D ). Checking
(H~)
are
proof
of
condition
t a k e m = 2.
Suppose
a of T h e o r e m
6 in o u r
A@' (t) is c o n t i n u o u s differentiable. The difference
satisfied it w e r e
.
Let m
that
~(t)
case and in t.
Since
(J(~(t+h))
IBmull
as t h e
2
IIBmull
2
for a l l m.
(Note t h a t w e
just differentiation
by
the s a m e
easy.
To see what
= that
is i n v o l v e d
is t h e
solution
~(t) E D ( A 2 ) , ~ ' (t) ~ D(A)
We must
show that
~(t) 9 D ( A 2 ) ,
J(~(t))
u ( t ) E D ( B 3)
- J(~(t)))
= <0,-
sum of three
terms
and
of w h i c h
inequality
we have
I lu(tl~ Cuct+~hl "H- uCtl ) - u t r <_ el IBuCt) I1~ I
[ uCt+hl h - u(t)
of p a r t
and
ut(t) s D ( B 2 ) .
u(t+h) 3 _ u(t) h
one
let us
is s t r o n g l y
for J,
Sobolev
are
- see Section
>
is
<0, u(t)2(u,(,t+h). - u(t) )> h
Thus,
be the
l
(I]~) is s i m i l a r .
J m is a l s o
quotient
2
i
can be written
= m
1
B as t h o u g h
The
s
I]Am-l~ll2flAm~l]
< c --
treating
+ m
2
I I ~ <_ C[ ]Bm~+lul l~l IBm2+lul I~I IBms+lul I 2
--
so t h e h y p o t h e s e s
+ m
Of t h e
Then,
(Bm~u)(Bm2u)(Bm3u)
again
l
to a s u m o f t e r m s
the e s t i m a t e :
I - u ,
-
Since
~(t)
to zero. that
is s t r o n g l y
The
same
J(~(t))
differentiable,
argument
is s t r o n g l y
works
~o
d ~-~ J(~(t)) E D(A 2-I-I)
are
essentially
the
for the
right
other
hand
side
terms,
converges
so w e c o n c l u d e
differentiable,
d d-~ J(%(t))
Therefore,
4 5 -
=
= ~
- 3u(t)2ut(t)>
and
is c o n t i n u o u s .
All
other
cases
identical. the
corollary
to T h e o r e m
7 is a D D l i c a b l e .
Let
us
suppose
that
f(x) E C
Then has
G O =
E ~D(A
the p r o p e r t y
tiable
t.
The
the w e a k
tributions) tives
then
is a C
same.
Theorem cases ~
Co(R
n
I0
in the
).
Then
~(t)
of t and each of
u(t,x)
(i.e.
Further
Therefore,
in the t i m e
Dmu(t,x) we h a v e
by S o b o l e v ' s
strongly
derivative
derivatives
if
=
often
differen-
is in ~
D(B n)
direction
are
in the s e n s e
of d i s -
is one of t h e s e APD~u(t,x)(L2(R
lemma
(see [~7],p.
deriva~)
52)
locally ,
of x and t.
case
m = o and
for O t h e r
p satisfying
(18)
are
we have:
Let
(in
solution
D ~ u ( t , x ) , ~ID(BJ )
Thus,
(18)
g(x) ~ Co(R3)
is an i n f i n i t e l y
derivatives
function
The p r o o f s the
so the
function
u(t,x).
since
for all p and m. u(t,x)
,
L2-derivatives
time
of
j)
(R 3)
u(t,x)
L 2 ( R 3) - v a l u e d
for each just
that
O
m > o,
w there
I > o
and
suppose
D a r t C) w h e r e p i s is a u n i q u e
C
~
n and p are
an odd i n t e g e r .
function
satisfies
utt - Au + m 2 u = - lu p u(x,o)
= f(x)
Ut(X,O)
= g(x)
u(t,x)
in one
Supnose on R ~
of the
f,
which
g, ~
-
46
-
We remark that various bounds on the growth of
u(t,x)
and its d e r i v a t i v e s
(in time)
of the L2-norms
follow from our estimate and the energy
inequality.
Example 2
For the cases of high p in d i m e n s i o n
or the case where the non linear t~rm is
-lu p
n ~ 3 and for p even with
I
T h e o r e m 9 since there is no aDriori estimate on the norm d i s c u s s e d in Section 2 part C.
I I@(t) [ I as
(Notice that for high p when
mean the n o r m in an escalated energy space).
n ~ 3, we
N e v e r t h e l e s s the hypotheses
of T h e o r e m 6 are satisfied for each m as can be easily checked by m a k i n g similar calculations to those in Example
1 and in part C of Section 2.
Thus we can apply T h e o r e m 6 and Sobolev's
lemma as above to conclude
that if the initial data is smooth enough, then the solution continues to have the same degree of smoothness in the interval where it exists and satisfies the a p p r o p r i a t e d i f f e r e n t i a l equation in a classical sense.
One cannot get that
C~
data go into
C ~ data in these cases
b e c a u s e the higher m, the shorter the interval of e x i s t e n c e
(- Tm,T m)
may become. Example 3
(sine-Gordon equation)
For the s i n e - G o r d o n e q u a t i o n the situation is a little d i f f e r e n t in that for high m the term.
I IAmj(r
;I =
lIB m sin ull 2
will have more and more products of
(BmLu) m u l t i p l i e d together.
This
poses no d i f f i c u l t y in one or two d i m i n s i o n s since in those cases I lul Ip ~ el IBu[ I2 for all p < -. for
p ~ 6
and in four d i m e n s i o n s
But in three d i m e n s i o n ~ this only holds for
p ~ 4. However we can also use
the estimate
I IBn~
I
i C[ JBn~
I
(26) 2
which
is valid for
part C).
n m< 4 (see the Sobolev inequalities in Section 2,
In the following we will use just
I [Bn~
(26) and
I~ i el [Bn~
Thus the proof we give s i m u l t a n e o u s l y handles the cases
(27)
n = 1,2,3,4.
We have already proven the e s t i m a t e s of T h e o r e m 7 in Section 2, part D for the cases
m = o,I.
For a general m,
-
I IAm(j(~) We will
show
that
- J(~))ll
the
term
47
-
= l IBm( sin ~
on
the
right
c(llsmG, II2 [ I B m ~ l l 2 ) I {
- sin u ) I f
1
2
side
is
Bm+l (G
r
less
-~
1
2
(28) 2
than
)ll
or equal
to
2
(29)
< C(11Am-l~tl,llAm-l~lI)
This
will
hold
for
prove all
that
m.
the
Let
hyDotheses
~ =
B like
a number
of
and
using
, ~ =
Isin u
- sin
u
we
find
finite
that sum
the
right
of terms
1 < 2
~
- cos ~ 1
2
hand
of the
(taking
~ = o)
we write
out
(28)
2
and
subtracting
the
same
term
estimates:
]
Icos
(H'm )
,v >. F i r s t 2
Adding
the
- ~)ll
and
1
differentiation.
times
(H)
,v > 1
treating
IlAm(r
side
--
{U
- ~
l
I 2
[ s {~ 1 - ~ 2 I
of
(28)
is
less
than
or e q u a l
to
a
form
11 (Bm4w) .,. (Bm'Q)
(w)~t {
(30) 2
where or
m i = m,e i=l - d
~ 1
is a z e r o
. We may
always
or o n e ,
assume
and where
m I = maxj
w
mj.
stands Now,
for either
for m ~
5, w e m u s t
2
m - m. > 3 f o r ] -
all
m., ]
j #
I.
Thus,
we
can
just
use
(26)
P il(Bmlw)'''(Bm'w)
(Q)~i[~
!
IIBm1*ll
P
< c llBm§
in c a s e
u , , u 2,
m > 5.
I IBmwi
-5[ !IBml
to conclude
-
For (27),
m = 2,3,4
or both.
we
For
just
check
example,
1
each
when
of the p o s s i b i l i t i e s
m = 3, t h e r e
are t h r e e
: 2
If (B2w) (Bw)w] i
II
< 2
--
(B2w) (Bw) II
kinds
of terms:
by
2
I I (Bw) (Bw) (Bw)wr I 2 _<
l
(21)
i lw[l
< rlB'wll ]iB~w]r il~'wrl
=
(26),
2
--
m
using
< [IB~wil l[Bwlr
=
m
4 8 -
2
by C27)
2
I I (Bw) 211211Bwl I= I lwi [.
l
!Kir(Bw) 211~ iB~wIi~llB'wTi KIIB2wII~~llB~wll ~ llB~wll 2 The
cases
right
m = 2
hand
side
a term with Thus,
B n§
we h a v e
equation. mates,
global
we h a v e
technical
been
A.
Theorem
ii
equation
domains
assume) but
then
that
ing the
(22)
has
original
Notice
there
is a m o s t
stronger
estimates
smoothness to
for the
leaving
out
B like d i f f e r e n t i a t i o n
ways
that
one
on the
Dower
(H~)
of
hold.
sine-Gordon some
of t h e e s t i -
and we h a v e
of o p e r a t o r s ,
in s i m i l a r
of A j into the
same the
J takes
data
a unique paper
Namely,
estimates.
etc.
All
paid of t h e s e
as the d e t a i l s
each
as
corollary
to T h e o r e m
in
global
C~
solution
he p r o v e s
that
in S e c t i o n
(this
hold. are the
has
same
9 just
then by
difficult
by the
of A i n t o
the
result take
assuming
only way
(H~) ~
the and
we
result one
can
is by h a v -
if one has
can get
the
estimates
themselves
out t h a t
sine-
m = 1,2,3,4.
is an i n t e r e s t i n g since
one
if
the
its d e r i v a t i v e s
is i m p l i e d This
pointed
spaces
Co(R) , t h e n
a more
if J and
of D o w e r s
von W a h l energy
and
other
conclusions
the d o m a i n s W.
are real
[3~],
he shows
two results
in e s c a l a t e d
in the
and
like d o m a i n s
initial
existence large.
the
in a d d i t i o n
can be p r o v e n
8.
in p r a c t i c e
prove
existence that
similarly.
estimates
reason
treating
If the
Theorem
right
are c h e c k e d
We s u m m a r i z e .
In S e g a l ' s than
this
to q u e s t i o n s
details
2, p a r t
m = 4
For
We r e m a r k
no a t t e n t i o n
Gordon
and
of all of t h e s e
same (H') J
global conclusions for j
4. Fin&te propagation
speed and continuous dependence
Recovering classical
smoothness
from the abstract
on the data setting was re-
latively difficult
in that it took more work and estimates.
finite propagation
speed and continuous
dependence
In contrast,
on the data are easy.
Theorem 12 Let A be a self-adjoint operator on a Hilbert space ~ and J a non-linear mapping satisfying (H~). Let ( - T,T) be the interval of existence of the solution of T h e o r e m
I.
Suppose that
#(t) of
(7) guaranteed
{Pt}t r (-T,T)
by Corollary
1
is a family of closed sub-
spaces of ~ so that
(31)
e-iA(t2
- tl):Ptl
) Pt2
if
T > t2 --> tl --> o
(32)
e-iA(t2
- tl):pt1_____9 Pt2
if
-T < t2 --< t, _< o
and J : Pt
Then,
if
Proof
) Pt
for
~ o e Po' we have
#(t) E Pt for all
t ~ (-T,T)
t E (-T,T).
We just use the same proof as for Corollary
cept that we take for
~(T,e~o)
~(t) on
satisfy
and
all
(-T,T)
which
~(t) ~ Pt for each
1 of T h e o r e m
the set of continuous
W-valued
1 exfunctions
~(o) = ~0' sup I ]~(t) - e -It 9 A~o l [ ~ %e(-T,T) t ~ (-T,T). X(T,~,~ o) is again a complete metric
space and if we define
(S~) (t) = e -iAt~o + [te-iA (t-s) j (~ (s))ds -o then all the estimates
are as in the Corollary
just check that S takes ty is concernedl.
~(T,e,~o)
Then by
e
-iA (t-s)
J(4(s))
~ Pt
We must
Then ~(s) ~ P s
on J, J ( ~ ( s ) ) E Ps also.
(31), for each s satisfying
I.
(as far as the Pt proper~
Suppose that ~(.)E ~ ( T , s , ~ o) .
each s and by the hypothesis t > o.
into itself
to T h e o r e m
o < s < t
Now,
for
suppose
.we have
-
and as in the proof of Theorem
50
-
i, it is a continuous
function of s.
Therefore,
I
te-iA(t-s) o
since Pt is closed.
Since
J(~(s))ds
e - ~ A t ~ o ~ Pt we conclude that
for
t 9 [o,T) and a similar proof using
for
t G (-T,o].
so its unique t ~(
- T,T).
Example:
s Pt
Therefore
S is a contraction
fixed point lies in
(S~) (t) e Pt
(32) shows that
(S~) (t) e Pt
on ~(T,u,~ o) C X(T,U,~o)
~(T,~,~o).
Thus,
~(t) 9 Pt for each
|
Let ~ b e
one of the Hilbert
spaces discussed
in Section 2.
That is
where
B = ~- A + m ~
= ~
k/2 = D(Bk+I)
on
R n and
+ D(Bk)
k is any non-negative
Z be a compact set in R n and define Qt to be the set of that the support of u is contained exist
y 9 Z and
z ~ R n with
Izl ~
Pt = (D(Bk+I) ~ Qt ) ~
It is easy to check that conditions
(31) and
in the set
S(Z,t)
integer.
= {xG Rnl there
Itl and
x = y + z } and let
(D(Bk) ~
Qt )
{Pt} is a family of closed subspaces.
(32) are just the statement
Let
u E L 2 ( R n) so
The
that the linear equation
utt - Au + m~u = o
has propagation by parts
(see[@],p.&@~) theorem
speed equal to one.
This can be proven by integration
(for smooth solutions) 3 by the explicit
or by the Fourier transform and the Paley - Wiener
(see ~ 7 ~ p .
linear equation
form of the solution
309).
In any case this is a statement
so we won't reproduce the proof here.
that all the non-linear
terms
Now,
about the it is clear
J(.) which we have considered have the
property J : Pt for each #o e Po
t & ( - T,T). then
) Pt
Thus, we conclude
from Theorem
#,(t) G Pt for each t, i.e. the non-linear
12, that if equation has
-
propagation whether
speed one.
globally
This
51
-
is true w h e r e v e r
in t or only
in a finite
the s o l u t i o n
t interval.
exists,
We summarize
what we have proven:
Theorem
13
In all the examples
propagates remains
Notice
In particular,
in Section
for
2 the solution
C~(R n) data,
the solution
C~(Rn). o
that this
existence ting
at speed one.
in
discussed
shows that
example
large
the blow up of the L 2 - n o r m
in Section
locally,
2, part
not because
E, is caused
in the n o n - g l o b a l
by the function
it fails to d e c a y
sufficiently
get-
fast
at infinity.
Now, data.
we treat
Whenever
the q u e s t i o n
of c o n t i n u o u s
we have the h y p o t h e s i s
dependence
(H~)
on the initial
of T h e o r e m
i, the~,
v
according
to the corollary,
~Cr)
we can at least some
interval
non-linear
=
{~o~J11~oll <_ r
solve the ( - T(r),
on each ball
integral T(r)).
e q u a t i on
For
}
(7)
(for
t G ( - T(r),
~o E ~(r))
T(r))
on
we d e f i n e
a
mapping
M t : ~(r)
,~
by
~(o) Notice, since
that no M t T(r)
M t exists uniqueness
Mt
(except M o = I)
may get smaller
it is s t r o n g l y
as
~ is n e c e s s a r i l y
r ---9
continuous
~.
defined
on all of
We know however
as a function
that w h e r e
of t and by
local
satisfies
MtM s = Mt+ s
Now,
continuous
dependence
on the data
(33)
says that
for each
fixed
t,M t
-
is a continuous
mapping
52
-
(in the topology of ~ )
where
it is defined.
For general non-linear mappings boundedness is not enough to guarantee (H~) it is. Since we are for the continuity but in conjunction with moment
just using
(H~),by "solution exists" we mean a continuous
so-
lution of
#(t) = e-itA# ~ + Ite -iA(t-s) -o
J(@(s))ds
(7)
where we just assume ~o 6~4.
Theorem
14
Let A be a self-adjoinh
operator on a Hilbert space ~ a n d
let J be a non-linear mapping on ~ satisfying hypothesis rem I.
Let D be a {not necessarily
finite interval
so that for
M t iS uniformly
(i)
= Mtd~o.
(7) on
I r,~,. (t)
( - T,T)
Then,
since
continuous
each
<_.. 11~o~
-
Let ~o ' ~o
+
f
Then
satisfies
9 D and define
the
integral
equation
initial data, we have,
lL _< I I ~"o*" - ~"~'1 I +
+ ~11
~o"
on D.
~i(t)
( - T,T) with corresponding
- ~,_ r
a
_< z<(.z,,o)
The proof is almost trivial.
Oi(t)
(H~) of Theo-
and
t ~ ( - T,T) where K depends on T and D but not on
for each t Proof
set in ~ ,
~o s D, Mt~ ~ exists and
I IMt~oll for all
closed)
la(~,. (s))
- J(~:, (s)) 1 Ids
t
oC(I I,~,. (s)I I, I1~,
2
-
11~, ,. (s)
(s) ll)
r
-)
(s) llas
I Ids
SO
(34)
Corollary
,
i
iol(t)
- ~2 (t) ll --< I1~'~--0 O~JII e tc(~'K)
Assume hypotheses
(Hn).
interval of existence of solutions the Corollary to Theorem Then for each
1 for all
t E ( - Tr,Tr) ,
of
Let
( - Tr,T r) be the finite
(7) constructed
~o in ~ (r) = {~oI
M t is uniformly
II
by the method of I I~oI I ~ r}.
continuous
on
~ (r).
-
Proof
satisfied with
Corollary
2
for all D =
solutions
Proof
Let
v e r g e to
the h y p o t h e s e s
bounded
continuous
~n(t)
T h e n by the e s t i m a t e -valued
function
f o r m l y to
J(~(t))
~(t)
on
tion
~n(t)
n
Then
on
for all
( - T,T);
~o
these
- T,T).
of v e c t o r s
converge
in D w h i c h
con-
solutions
on
uniformly
to a c o n t i n u o u s
Since
J(~n(t))
(H~)), and each
> ~ and c o n c l u d e
Since the on
~n(t)
Now,
( - T,T).
converges
~n(t)
continuous
~(t)
bounded,
uni-
satisfies
on D for each
~(t)
blows
(7)
is b o u n -
14 to
t G ( - T,T). I
corollary
for all the e x a m p l e s
the s o l u t i o n
satisfies
applying Theorem
it is clear t h a t the first those where
that
are u n i f o r m l y
( - T,T).
for short t i m e s
2 including
14 are
w i t h the same b o u n d and
t s
( - T,T).
M t is u n i f o r m l y
First,
that
of T h e o r e m
-itA~ + it e _ i A ( t _ s ) J ( ~ n ( S ) ) d s ~o o
ded w i t h t h e same b o u n d
uous d e p e n d e n c e
( - T,T)
~o | be a s e q u e n c e
we can t a k e the limit as
Examples:
on
(by the h y p o t h e s i s
t e ( - T,T).
1 it follows
14.
(7) e x i s t s
be the c o r r e s p o n d i n g
(34) the
~n (t) = e
we get that
of T h e o r e m
of
on ~ for each
~ o G D and let ~o" Let
to T h e o r e m
(r) so the h y p o t h e s e s
D the s o l u t i o n
are u n i f o r m l y
M t is u n i f o r m l y
~oG~
~(r).
Suppose
in the c l 6 s u r e of
for
-
F r o m the p r o o f of the C o r o l l a r y
I IMt~ol I ~ K + ~
~
53
implies
considered
continin Sec-
up after a f i n i t e
amount
of time. The a p p l i c a t i o n
to the s i n e - G o r d o n
equation
is also easy.
In that
case
rr~(t)II ~ [l~o]le t for all
~o @ ~
.
T h u s we just c h o o s e D to be the
I [~oI I ~ r} and a p p l y T h e o r e m time
interval
( - T,T),
14 d i r e c t l y
M t is a u n i f o r m l y
ball
to c o n c l u d e
~(r)
= { #o
I
that on any finite
equicontinuous
f a m i l y of
mappings. T he a p p l i c a t i o n subtle
to the case
and uses C o r o l l a r y
existence
of s o l u t i o n s
2.
J(~)
= ,
Notice that
n = 3, is a l i t t l e m o r e
in this case we p r o v e d g l o b a l
of
~' (t) = - iA~(t)
+ J(~(t))
,
~(o)
= ~o
-
if
~oED(A).
In case
to hold,
lution b e c a u s e
(H~) holds.
bound gy
on
solution
I l~(t) If.
E(t)
Then
for
but the integral However,
equation
we don't
expect
the differ-
(7) has a local
know yet w h e t h e r
since we have no d i r e c t w a y of g e t t i n g The reason
is c o n s e r v e d
we can handle
-
~o is just in 94 then we don't
ential e q u a t i o n
has a g l o b a l
54
is that we can't
conclude
since we can't d i f f e r e n t i a t e
this d i f f i c u l t y
#o ~ D, energy
by u s i n g C o r o l l ~ r y
is conserved.
Let
(29)
an apriori
that
the ener-
Nevertheless
E(t).
2.
so-
D = ~(r) (% D(A).
U s in g the e s t i m a t e
(u(x,o)
=
u o)
luol'dx~ {luo]{~ rluolJ~ 3
! {fuol]~ K IrBuol] 3 ~ llBuo{{ ~ and c o n s e r v a t i o n
of e n e r g y , w e
have
(for all
~oG~(r))
~ l}~(t) l}2 + ii ~ }uCt) r~dx
{;r
3
=
2E(t)
=
2E(o)
,f
= {{,(o){F ~ + ~
lUo r~dx
i {{~(o){t' + K{{~io){[~ < r + Kr 2
Thus,
for every
are satisfied.
finite
Therefore,
tion has a solution Since
this
is true
the e s t i m a t e defined
(35)
This
for all
for all
solutions.
B of Section
Note
the h y p o t h e s e s
~o G D = ~
(r), the
of C o r o l l a r y integral
the solution
of T the family
t is u n i f o r m l y
is g l o b a l
2, we can c o n c l u d e
equa-
{Mr} w h i c h
and since is now
equicontinuous.
for all the cases w h e r e we got global that
2
interval w h i c h has the same bound.
( - T,T),
is i n d e p e n d e n t
same p r o o f works
( - T,T)
for every
on the w h o l e
on all of ~
of strong
interval
(35)
in the case that M t
m = o, considered
is u n i f o r m l y
continuous
existence in part for each
-
t, but only equicontinuous estimate corresponding
to
55
on finite
Finally, we make two remarks.
intervals because the
(H~),
By using the escalated energy spaces 14 applied successively
(H~) hold),one J
m
for
-~(t))ll
< C(t)
j=l
4o' # o G D(Am).
~ llAJ($(o)j=l
~(o))II
So, if a certain number of derivatives
of the ini-
tial data are close enough then the same number of derivatives solution will be close. constants
involved
Secondly,
all of this discussion
15
continuously
(which may depend on t).
in the following
In all the examples on initial data.
of the
since we can explicity estimate the
in all the problems we have discussed,
explicit modulus of continuity
Theorem
j = I,...~,
can conclude that
m
IIAJ($(t)
if
( - T,T)
(35) depends on T.
or by using the trick of T h e o r e m (in the cases where
-
(somewhat vague)
in Section
we have an We summarize theorem.
2, the solutions depend
5. W e a k
Solutions
In t h i s
section
we will
show
utt
has g l o b a l veral the
weak
proofs
same
solutions
problem.
One
global
One
then
(36)
using
the
in a w e a k
sense.
applies
most
tions.
Therefore,
= f(x)
ut(x,o)
= g(x)
the
the
regularized
inequality)
one
on
D(A)
= D ( B 2) ~
sections
r
We w i l l be clear Define
take
from Fn(X)
are
in the
go o v e r the
a way
that
approach
-uP
shows
that
u(t)
of S t r a u s s
satisfies which
to r e a l - v a l u e d
func-
onl[:
0
(B L 2 (R n)
D(B)
of r e a l - v a l u e d
and of c o u r s e
introduction.
initial
the a r g u m e n t
se-
A + ~~
spaces
to this
to be the
then
argument
section
are
of the r e g u l a r i z e d
side
attention
for this
There
all use b a s i c a l l y
{Un(t) } b y a c o m p a c t n e s s By a l i m i t i n g a r g u m e n t
our
L 2 ( R n)
past
hand
(36)
in such
Un(t)
the
and
given
side
follow
D(B)
= e -tA
all n. but
if w e r e s t r i c t
= D(B)
adjoint
right
s u b s e q u e n c e of the energy estimates.
B=
W(t)
hand
solution
B2
where
x eR n
p > 0 and
right
for the
We w i l l
naturally
= - up ,
u(x,o)
regularizes
energy
equation
L i o n s [|gJ, S t r a u s s [ S ~ )
and e x t r a c t s a c o n v e r g e n t a r g u m e n t b a s e d on u n i f o r m (again
- Au + m 2 u
existence lets
the
for all odd
(Segal[30],
idea.
one o b t a i n s
that
case data
that
we
continuous
All
f and could
generates the
so we use
g to be
in
A is skew-
on ~ the g r o u p
considerations
them without
take
function
functions.
C~(Rn),
a much more
of the
comment. it w i l l
general
on R s a t i s f y i n g :
class.
-
xP F
n
(x)
=
57
-
ixL i n
linear
o
n <_ ixi < n + 1
I~I >_ n+1
and let x
G n(x) =
S
F n(y)dy
o
-
~+i}
-~
Finally,
define
Jn(~)
Then, since satisfies
Fn(X) (H~).
= Jn()
is a Lipschitz
=
function,
it is easy to see that
Thus, by Theorem 1 there is a local solution
which satisfies
~n(t) = e-At#o + [te-A(t-S)Jn(~n(S))ds
(37)
Jo
#n(O) =
The function
(38)
Un(t)
u (t) = cos n
satisfies
(Bt)f + sin(Bt) B
Jn
~n(t) =
g + it [B-Isin B(t-s)] Fn(U(s))ds o
-
and fqrmally
58-
satisfies:
(39)
utt - Au + m2u = - Fn(U)
Thus,
Un(t)
(40)
should have the conserved
EnCtl : ~I BUn (t) II~2 +
Notice ded,
that Gn(O)
(40) certainly = o, and C o~(Rn).
and g are
89
makes
Un(t)
[uJ(t) 2 n I I2
However,
f and g are nice,
of the sharp corners Let to
Fn(X),
obtained
(H~),
(H~),
~n(t).
by rounding
~
F
n
SO the solution
f
is coneven
(H~) because
differentiable
off the corners
E(t)
is that,
(H~), not
uniformly.
G n is boun-
show that
The reason
We avoid this difficulty
of continuously to
since
for each t because
we cannot directly
Fn(X).
~m) converges (H)
support
Jn only satisfies
in
~nl(X) be a sequence
and so that
+ !nGn(Un(t))dx
sense and is finite
has compact
stant because we can't differentiate though
energy
as follows.
approximations
so that
x~_%(x) ~ o
For each m, ~ *
n
satisfies
of
(n m) (t) = e-At~o + [te-A(t-S)~n)(#~}(s))ds -o
(41)
is strongly
continuously
differentiable.
Thus we can differentiate F
(42~
~i I IBuT(t) I I
~n'(t)
and p r o v e
that
it
is
is aprior&
bounded
by Theorem
2.
nm'(t ll § 2
conserved.
From t h i ~
it
)Rn
n ( n~ ' )dx
follows
that
tr~kt)
lf
~m1(x) > o) so the solution of (41) is global n [- T,T] be any subinterval of the interval on
solution
l l~mi(t) I I are uniformly trick
89
(since
Now let
which a continuous
2
+
of
(37) exists.
bounded
on
[- T,T]
Then both
(see for example,
Theoreml4
) we can prove that
) o uniformly
[- T , T ~ .
From this
on
I l~n(t) ] I
so by our usual it easily
and
iteration
I I~nml(t) - ~n(t)l~ follows
that
~nl(t) > En(t) for t 9 [- T,T] and thus, since each ~nlt) is constant we conclude that E (t) is constant. Finally, this implies as n usual that I I~n(t) I I is apriori bounded (since Gn(X) > o) and so the solution
~n(t)
of
(37) is global
and
En(t)
is constant
Now we come to the main part of the argument.
Since
for all t. f is nice,
-
59
-
E n(O) = }I IBfll z. + +I Ig]122 + IGn(f)dx
converges
as
n
> ~ to a number
E{O)
Therefore
K }l IBfll 2
the numbers
is constant
2
n
{En(O) } are uniformly hounded.
But since
En(t)
in t for each n, this means that there is a constant
C so
that (43) Let
E (t) < C n
for all t and n.
S(r) be the ball in R n of radius r and choose r o so that the sup-
ports of f and g lie in Then by
(43) and
S(ro).
Let
~
T,T] be a given finite interval.
(40) I fUn(t) I I2 _< / 2C
SO
Un(t)
are a uniformly
with values
in
equicontinuous
L~(S(r ~ + T)).
But
family of functions
(again by
(40) and
on
~
T,T]
(43)) the values
lie in
{v
.(scr o + T ) )
Since this set is compact (see [ ~ , p .
@n(t)) trick
that we have a subsequence Let v be in by
C~(R n)
_<
{Un(t) }
so that
L2 (S(ro + T))-valued
usual d i a g o n a l i z a t i o n
llvll
, llBvll 2 <
in L2(S(r ~ + T)), the A s c o l i - A r z e l a
155 ) tells us that
(which we also call continuous
I
has a convergent
Un(t)
function
converges u(t)
(Un(t),v)
+
o
theorem
subsequence
uniformly
on [- T , T ] .
to a By the
(for larger aBd larger T) we can assume so that this statement holds
for each T.
(again, this is stronger than necessary).
(38),
(44)
}
= (cos
(Bt)f,v)
+ (B-isin(Bt)g,v)
(-B-Isin B(t-s)] F (Un(S)),v)ds n
Then
-
60
-
It (cos(Bt)f,v)
+ (B-isin(Bt)g,v)
+
(-
Fn(Un(S)),B-Isin
B (t-s)v) dS
o Suppose that we can show that
(45)
Fn (Un (x,t))
then since B - I s i n ( B ( t - s ) ) v can take the limit in
(46)
(u(t),v)
=
L' (Rnx [-T,T] )) u (x,t) p
is a
C=
function of all its variables we
(44) to conclude that:
(cos(Bt)f,v)
+ (B-isin(Bt)g,v)
+
( - u (s) P , [ B - l s i n
B (t-s)~v) dx
o Since f and g are nice and the integrand on the right left side is absolutely continuous
d
(u(t),v)
=-
is in L*
, the
and
(B sin(Bt)f,v)
+ (cos(Bt)g,v)
+
(-u(s) p, [cos B(t-s)]v)ds o
Again,
the right hand side is absolutely
d~
(u(t),v}
4
= (c0s(Bt)f,
( - u(t)P,v)
+
-B2v)
continuous,
so
+ (B-Isin(Bt)g,
( - u(s)P,[B-lsin
B(t-s)](
-B2v)
- Bav))ds
o = (u(t),-
for almost all t.
d2 ~
B2V)
+ (-
u(t)P,v)
Thus,
(u(t),v)
- (u(t),Av)
+ m2(u(t),v)
(u(o),v)
= (-
=
u(t)P,v)
(f,v)
-
6 1 -
~t(u(t) ,v) I
= (g,v) t=o
so
u(t,x)
is a weak global solution oZ
utt - Au + m2u = - u p
It remains to prove use of
(43)
Since
Un(t)
(45) by a real variables
(againZ). Let [- T,T] Lz > u(t) uniformly on ~
u
of the
F
a.e. n
in
~
T,T] we have
L 2 ( [-T,T] X Rn)>
u
(again denoted by u n) so that
T,T] X Rn.
It
follows
Fn(Un(t,x))
a.e.
in
[- T,T] X R n.
~
)u
Since
u(x,t) p
IFn(X ) I< 1 + G(x)
IFn(Un(X,t)) I dxdt < 2T Vol [ S ( r ~ + T)] + -T
un
i m m e d i a t e l y from p r o p e r t i e s
that
(46)
pointwise
be a fixed finite time interval.
n
so we can choose a subsequence
pointwise
argument and clever
n
we have
Gn(Un(X,t))dxdt -T
Rn
< 2T Vol [S(r O + T)] + 2TC
where we have used the finite propagation FatoU's
i!
-T
sO
speed and
(43).
Thus, by
lemma,
lu(x,t)
n
p
dxdt <
lim
IT!
-T
ul p E LI ( [- T , T ] X R n ) .
IFn(x,t) I dxdt
Now, by the finite propagation
Fn(U n) and u p have support
in
by E g o r o v ' s
Fn(Un(X,t))
theorem that
<
n
S(r O + T) for
Itl ~ T
converges to
so
speed,
(46) implies
u(x,t) p uniformly
-
62
-
except on a set of arbitrarily small measure 6 in
~ T,T] K S ( r ~ + T).
Therefore to conclude choose 6 so that
, given e, we can
I
(45) we need only show that
I IFn(Un(X't)!I dxdt < c
M
whenever the measure of M in
[- T , T ] K S ( r o + T) is less than 6.
Now,
Fn(X) is only large if Ixl is large so given 2TC/E we can find a constant K so that IFn(X) I ~ K implies Ixl ~ 2TC/E Choose 6 so that
6K ~ s
and for any M write
M'n -- { <x,t>
and
M"n is its complement
M = M~uM ~
where
I IFn(Un(X,t)) I _> K}
in M.
Then
I /IFn(Un) I dxdt = / IIFn(Un) J dxdt + / lJFn(Un) J dxdt M
M '
M"
n
< 4--~
n
lUn(~,t) I JFn(Un) I dxdt + K6
s I [ Gn (Un(X't)) dxdt +e/2 < 4-~
<
s
(by (43))
In the next to last step we have used the fact that for each n and all x.
This holds because
Fn(X)
IxIIFn(X) [ ~ Gn(X)
is monotone decreasing
to the right of n which is why we needed the sharp corner in the definition of F . n As we remarked before,this proof follows the outline in Strauss ~6]. Strauss a c t u a l l y t e n c e holds for
proves
the
more
general
result
that
global
weak
exis-
utt - Au + m2u = F(u) as long as xF(x) < o. m
F(x)
is a continuous real-valued
function satisfying
The general ideas come from Segal's paper Do]but Segal
-
chooses to r e g u l a r i z e tity.
u p by
63
-
j$(u~j) p w h e r e j is an a p p r o x i m a t e iden-
This makes it easy to h a n d l e the c o m p l e x - v a l u e d case but makes
the proof of the c o n v e r g e n c e of
(44) as
n---~ =
more difficult.
We
remark that in these proofs one loses u n i q u e n e s s b e c a u s e of the compaetness argument.
6.
Discussion
Before
going on to s c a t t e r i n g
we have p r e s e n t e d best
aspects
proofs were
of the abstract quite
differential theses -itA e
and to point
theory
equations)
and that
is sometimes
construct an abstract -itA on e We have
chosen
the abstract conditions
special
to compute
theory
which
(the a b s t r a c t
in that the hypo-
properties .
illustrate
of the grou~
As we will
easily
without
what
The
from o r d i n a r y
one needs much more
and its limitations f(x,u,u t)
to discuss
problems.
is simple ideas
it is quite general
scattering
on functions
research
followed
and not
difficult
examples
theory
it is w o r t h w h i l e
are that_it
easy and in general
involve A and J d i r e c t l y which
theory
out w o r t h w h i l e
see,
to
information
the a p p l i c a t i o n s
trying
to give
of
general
so that
utt - Au +m2u = f(x,u,u t)
has
local or global
in Strauss ~ ] f o r T here
are a w i d e
range
can be applied. listed
interest worked
Chu,
but w h o s e
in n o n - l i n e a r of course
these methods
our old
Essentially
as it now stands.
lead,
in my opinion, The
for high
odd p.
new idea
solve
We know that
The
smooth
is
solve this problem,
problems
interesting
where
there
x GR 3
local
to prove that the solution
If one could
of the lack of Sobolev second
strong
and we k n o w that g l o b a l weak
a host of other
because
problem
friend:
is r e q u i r e d
derivatives.
are
to great p r o g r e s s
specific
utt - ~u + m2u = - u p
the data are nice
of p h y s i c a l
theory have not been
and one general w h i c h
equations.
theory
in the paper
can be applied.
one s p e c i f i c
differential
this a b s t r a c t
are many e q u a t i o n s
of the theory
solution w o u l d
partial
may be found
in most of the papers
the r e f e r e n c e s
There
of the e x i s t e n c e
in a p p l i c a t i o n
are two problems
to w h i c h
can be found
See in p a r t i c u l a r
out and to w h i c h
conditions
in C h a d a m [~] for the case m > o.
equations
examples
the details
are p r o b l e m s
difficult
and
and M c L a u g h i n [~9],
for w h i c h
There
Such general
m = o
of other
Specific
in the index.
by Scott,
there
solutions.
the case
solutions
solutions
exist
exist.
does not k e e p then
if Some
losing
I'm sure one could
is no strong e x i s t e n c e
theory
estimates.
question
is to i n v e s t i g a t e
problems
where
-
65
-
either global e x i s t e n c e is false or where s
is unknown and to try to
prove global e x i s t e n c e for certain subclasses of initial data.
As one
example of this we will prove in Section iO that
utt - Au + m2u = lu p
has a global strong solution for high D in three d i m e n s i o n s tial data are small enough.
if the ini-
A more interesting example is p r o v i d e d by
the work of C h a d a m and G l a s s e y on the Yukawa coupled Dirac and KleinGordon e q u a t i o n in three dimensions:
u
(-iV ~u + M) 4 = gr
(48a)
(48b)
utt - ~u + m2u & g~y~ 4
where
M > 0,2 = <~t'
~x I' ~x 2' ~x3 >
, the y's are certain four by
four matrices, and
= <~o(X,t) ,4, (x,t) ,42 (x,t) '~3 (x,t)>
always denotes the complex @ o n j u g a t e . of the y's,
E(t) =
Because of special properties
there is a conserved energy
~ Yo 3
(
+ M) 4 + 1
(Vu) 2 + m2u2 + ut
g
3
but it is not positive definite. d e g r e e of the time d e r i v a t i v e in space to prove local existence.
~%/0 ~ R 3
Furthermore, because of the first (48a) one must use an e s c a l a t e d energy Therefore,
it is not clear how much
good the conserved energy would be even if it were positive. these equations have both the d i f f i c u l t y of
(47) for high odd p and in
addition the fact that the energy can be negative. tions goes back to Gross ~ 3 ] w h o
Work on these equa-
investigated the coupled M a x w e l l - D i r a c
equations where similar problems arise. lutions exist.
Thus,
Gross proved that local so-
C h a d a m [ ~ ] t h e n proved that solutions exist in an arbit-
rary region of space time if g or the initial data are small enough.Then, in [~], C h a d a m showed that the c o r r e s p o n d i n g equations have global solutions
for a r b i t r a r y initial data
in one d i m e n s i o n
(this is the proof
-
66
-
that we gave in Section 2, part F). In three d i m e n s i o n s the q u e s t i o n of global existence
for
(48) is
ppen, but the f o l l o w i n g partial result of C h a d a m and Glassey [ 7 ] i s very suggestive.
They show that w h e n e v e r a solution exists then
! is conserved. - ~3(x,o)
Thus,
{1~
- ~I ~
§ I~ + ~ l ~ } d x
(49)
3
if initially,
~l (X,O) = ~ (x,O) and ~2(x,o)
then the same will be true for all time.
follows that
(in the standard r e n r e s e n t a t i o n of the
~o~
for all time.
=
From this it y's)
= I~,I 2 § l~2J ~ - I~, 12 - l ~ r2 = o
Thus,
for such initial d a t a r satisfies the free Klei~-
Gordon e q u a t i o n and one can use this to show global e x i s t e n c e for
(48).
So, for a certain subsDace of initial data global solutions exist. T h e s e results suggest that in g e n e r a l for systems w i t h o u t p o s i t i v e energy
(and w h e r e global e x i s t e n c e does not or is not known to hold
for all data)
the~e may be w h o l e subspaces of initial data
by some a l g e b r a i c
conditions)
(determined
for w h i c h global e x i s t e n c e does hold.
Such proofs will require the d i s c o v e r y and clever use of new conserved quantities.
It is not clear, of course, what the p h y s i c a l s i g n i f i c a n c e
of these subspaces will be,
but this whole q u e s t i o n seems to me to be
very interesting and worthwhile.
Chapter 2
7.
Scatterin@ Theor[
F o r m u l a t i o n of S c a t t e r i n @ Problems in this lecture we provide b a c k g r o u n d and m o t i v a t i o n
in the rest of the chapter.
for d e v e l o p m e n t s
Let us begin by looking at the equation
utt - Au + m2u = -Xu p
(50)
whose e x i s t e n c e theory for some n > 1 we treated in Chapter d e v e l o p e a scattering theory for
I.
To
(50) one would show that for large
positive and negative times the solutions of
(50) look more and more
llke solutions of the c o r r e s D o n d i n g free equation:
utt - Au + m2u = o
(51)
It is not clear ~ priori why this should be true since the n o n - l i n e a r term
-Xu p not only creates an interaction t h r o u g h o u t all of space but
is clearly very large if u is large. of the free equation like
On the other hand, the solutions
(51) w i t h nice initial data decay
t ~n/2 in n dimensions.
(in the sup norm)
This raises of the p o s s i b i l i t y that the
same decay will hold for solutions of theory might be p o s s i b l e since
(50) in w h i c h case a s c a t t e r i n g
-Xu p is very small w h e n u is small.
Thus, we expect the e x i s t e n c e of a s c a t t e r i n g theory will depend on a d e l i c a t e interplay between the rate of decay, the degree of the nonlinear term, and the sign of the n o n - l i n e a r term since we know from Section 2, part E that some solutions b l o w up in finite time if X < o or if p is even. As in Chapter
1 our t e c h n i q u e is to r e f o r m u l a t e the s c a t t e r i n g
theory p r o b l e m as an abstract Hilbert space problem, prove abstract results, and then return to apnlications. o p e r a t o r on a Hilbert space ~ a n d
So let A be a s e l f - a d j o i n t
J a n o n - l i n e a r m a p p i n g from ~ t o
itself so that
#(t) = e-itA~ O + [ t e - i A ( t - s ) J ( ~ ( s ) ) d s -o has global solutions at least for some initial data in Chapter then
~(t)
(52)
r
I, if J satisfies certain a d d i t i o n a l conditions is d i f f e r e n t i a h ~ e and satisfies
As indicated and ~o ~ D(A)
-
68
-
r (t) = -iAr
However,
in this c h a p t e r we c o n c e n t r a t e
do not w o r r y equation
about
(52).
smoothness,
What we would
of i n i t i a l d a t a
Xscat~
(a)
r
For e a c h
- e-itA@
That
is, as t
(c)
~
r
is that t h e r e
as
r
t
- e -itA r
That
is,
)
~(t) with
(a) and
there
o
@(t)
of
~(t)
(52) so that
like t h e s o l u t i o n @_.
of
)
free s o l u t i o n
+~-
the w a v e o p e r a t o r s
r (o)
n+ : r
;
~(o)
(52) so that
+~.
like the
as t
)
~+ and R
by
like to p r o v e that
~+ = R a n g e
(this is c a l l e d the p r o b l e m scattering
~
~_ : r
Range
~+
t
~ +
(b) h o l d w e d e f i n e
F u r t h e r we w o u l d
also that
is a s o l u t i o n
looks m o r e and m o r e
initial data
is a nice set
)
l o o k s more and m o r e
as
and
integral
properties:
is a s o l u t i o n
o
-~
~Zsca t
~(t)
If
like to p r o v e
w i t h the f o l l o w i n g
)
behavior
just w o r k w i t h the
of the free e q u a t i o n w i t h i n i t i a l d a t a
For e a c h
e-itA~+
on the a s y m p t o t i c
so we w i l l
t there
~(t)
e-itA~_ (b)
+ J(r
and
~_
of a s y m p t o t i ~
~_ are one to one.
operator S : [scat
by s =
(~+)-i~_
)
[scat
completeness)
an~
T h e n we can d e f i n e the
-
(d)
Finally,
69
-
one would like to prove some properties of S.
ample, that S is a continuous m a p p i n g of [scat Basically,
For ex-
[scat onto itself if
has an a p p r o p r i a t e topology.
our a p p r o a c h to the p r o b l e m is to try to solve the initial
value p r o b l e m for
(52) with Cauchy data
~_ given at
t = -~
That
is, t o show that the e q u a t i o n
~(t) = e - i A t ~ _ + It e - i A ( t - s ) J ( # ( s ) ) d s
(53)
has a global solution, that and that there exists a
~(t) - e - i A t ~ _
~+ so that
9 )
o
as
~(t) - e-iAt~+ ~
As we m e n t i o n e d at the beginning,
t o
~
-~,
as
t
) +~.
carrying through this c o m p l e t e
p r o g r a m for highly .non-linear equations w i t h interactions t h r o u g h o u t space is a very d i f f i c u l t problem. a few cases.
However,
the initial data
~
C o m p l e t e results are known only in
two parts of the theory are easier.
at
t = -~ is small
First if
(or if the c o u p l i n g constlat
is small) then one can prove global e x i s t e n c e and for a scattering theory quite easily if the solutions
(53) and d e v e l o p
e-!At~_-
of the free
equation decay s u f f i c i e n t l y rapidly and J has high enough degree. E s s e n t i a l l y the reason in that the n o n - l i n e a r t e r m never gets large enough to d o m i n a t e the equation. for small data in Section
We d e v e l o p
this s c a t t e r i n g t h e o r y
8.
The second part of the p r o b l e m that is fairly easy is to show the e x i s t e n c e of the w a v e operators
~§
and
~_.
(52) have global solutions, that -e-ltA# and that J have high enough degree.
The proof w h i c h uses many of the
ideas of Section 8 is given in Section In Section and
i0
i0.
ii we give applications of the results in Sections 8,9,
What remains in most cases is the p r o b l e m of a s y m p t o t i c com-
pleteness. in Section
This is a really d i f f i c u l t p r o b l e m b e c a u s e
(as we discuss
12) its solution requires a priori decay estimates on solutions
of the non-linear equations. cases.
What is r e q u i r e d is that
decays s u f f i c i e n t l y rapidly,
However,
Such estimates are known in only a few
if one has such an aDriori estimate,
then one can carry
through the entire theory if J satisfies the right properties. we do in Section
This
12.
It is w o r t h m e n t i o n i n g before we start, two t e c h n i c a l d i f f i c u l t i e s which do not occur in q u a n t u m m e c h a n i c a l scattering. ~ave and s c a t t e r i n g operators are non-linear,
First,
since the
it is not sufficient to
pro~e that they are bounded on a dense set in order to conclude that
-
they are continuous. states,
Secondly,
so that
in most applications,
condition are known for such decay. [scat in
be closed
(for example,
-
it is natural to take as s c a t t e r i n g
~scat' the set of ~ in ~
Unfortunately,
70
e-itA~
decays appropriately.
only sufficient but not n e c e s s a r y Thus if we w a n t in a d d i t i o n that
to be a Banach space)
then the n o r m of a
[scat must involve e ~ p l i c i t l y the large time b e h a v i o r of
e-itA~.
In what follows these two d i f f i c u l t i e s will cause quite a bit of technical pain. Finally,
as you will see, we will need quite strong hypotheses on
J in order to d e v e l o p e as abstract s c a t t e r i n g theory, many more hypotheses than we needed for the e x i s t e n c e theory.
This is natural since
the e x i s t e n c e of a s c a t t e r i n g theory reflects a very close r e l a t i o n s h i p b e t w e e n the solutions of the free and interacting equations. requires quite strong h y p o t h e s e s on J. f o l l o w i n g situation sometimes occurs.
Thus,
We remark however, that the In a p a r t i c u l a r application, J
may not fulfill all the h y p o t h e s e s of the a p p r o p r i a t e t h e o r e m below. Nevertheless,
one can o~ten Drove the c o n c l u s i o n of the t h e o r e m by
using special p r o p e r t i e s of the p a r t i c u l a r equations and the idea of the general theorem.
it
We w i l l see an example of this in Section
IZc.
8.
S catterin~
In this directly idea
lecture
&f the
is t h a t
enough
for s m a l l
the d a t a
then
to the
and a s c a t t e r i n g no e n e r g y theorems global
show h o w to c o n s t r u c t at - ~ are
if the d a t a
degree
comparison
we
data
is s m a l l
the n o n - l i n e a r linear
terms.
theory.
The
inequalities provide
existence
fails
sufficiently
The basic
term
remain
From
should this
always
one
point
can
small
data;
in
existence
is that we w i l l
at all.
data
high
small
get g l o b a l
here
boundedness) for
for large
"small".
operator
t e r m has
important
existence
scattering
and the n o n - l i n e a r
(or a p r i o r i
global
the
Thus
in some
for e x a m p l e ,
use
these
cases
where
for
utt - du + m 2 u = u p for
large
p.
This
p a r t E of S e c t i o n get
the
solution
We r e m a r k that
is,
to b l o w
that
if w e
is c o n s i s t e n t
with
2 since we had
up in finite
if t h e r e
are d e a l i n g
the n o n - e x i s t e n c e
to m a k e
the
example
"large"
in
in o r d e r
to
time.
is a s m a l l with
the d a t a
coupling
integral
constant
equation
in front
that
of J,
corresponds
to #' (t) = - iA~(t)
then
the t h e o r e m s
necessarily larger methods
the
be two
small) data
the
of this
So,
in this
section
initial
data
smaller
section)
all d a t a
"norms"
satisfies
all the p r o p e r t i e s
value the
(i)
+~.
We
following
There
that
on ~
except
assume
A, J,
There
enough.
onW.
not
except
handle
I I I Ia and
the (by the
I I ] Ib
all the p r o p e r t i e s that
that
and the n o r m s
However,
(not
g.
Let
imply
for any
can't
fixed
satisfies
need
of a n o r m
existence
so we
for any one
: I [.I ]a
(54)
~ = o;
it m a y
I I .I Ia,
take I I -I [b
] [. ] Ib the satisfy
hypotheses:
is a
c > o
so t h a t
]l~II a _< cl I~[ I
(ii)
be c h o s e n
operator
I I$[ ]a = o
that
global
if g is s m a l l
let A be a s e l f - a d j o i n t auxiliary
imply
g must
of a n o r m
+ gJ(~(t))
are
constants
for all
c I > o, d > o
~ c~
So that
(55)
for
~ e
-
72
-
{{e-iAt~l{ a < c t-d{{~{Ib (iii)
There exist
IlJ(~) 1
if
It{ > z
B > O, 6 > o, and q > I with
(56)
dq > I, so that
- J ( ~ )2l l
(57) 8(I{~ilI a + Jl#x{la)q[{#x
- ~2{ I
{IJ(#x ) - J(#z) l{b (58)
<_ 8{(I[r
for all
a + ll@2[la)q-ljl~z - ~aIla + (II~zll a + II~211a)qll~z-~2[l}
~z'#2 E ~
satisfying
{{#i{l < ~.
In the case
q : 1
we
assume that 8 can be chosen arbitrarily small if ~ is chosen small. We can now define the scattering states and the scattering norm. First, for an 94-valued function
III~()rI![N,N)~
sup
ll~(t) ll +
N
In the case where
N
--
2
R we define
(l+]t{)dl l#(t) I{ a
s.p
N
= - =, N 1
Ill" I J I"
~(t) on
--
2
= + ~ we will denote the norm simply by 2
NOW we define
[scat E {~ e ~
III
e-itA~l I I < | }
and I I~I Iscat 5 }} {e-itA~l I}
That is, the scattering states are just those vectors in ~ w h i c h nicely under the free propagation.
Notice that if
{ le-itA~l la < c (l+[tl)-d(ll~[{ --
where
c
= max {2dcl,2dc 2
+ {{~I {b)
2
},
so
~ ~ ~scat and
decay
I I~Ilb < ~, then
for all t
(59)
-
7 3 -
il~llsc~t < (~+c)II~II --
+c
2
11~tlb
2
We can now state our first main theorem: Theorem
16
(g~obal existence
Let A be a self-adjoint linear mapping I I'll a,
of ~
II "lib
there is an the equation
for small data)
onerator
into itself.
so that hypotheses
no > o
2~ o.
global
continuous
where
and J a non-
(iii) hold. with
Then
] I~ I I ~ ~o'
e -iA (t-s) J(~(s))ds
-valued
For each t, ~(t) E [scat
(b)
ll~(t)
(c)
In case
The basic
X(n,~
so that
(ii), and
~ _ L [scat
(a)
we employed Let
~
space ~
that there exist norms
solution
(6O)
~(-) with
I I I~(') I I I
Moreover,
- e-itA#
- ~_llscat
§ o
) denote
1 except with
~ is chosen
initial
the set of continuous
- e-itA~_l I I ~ ~.
~
Assume
so that hypothesis
to:
as t § -~
idea is to use the contraction
in Section
I I l$(t)
II § o as t § --
q > I, (b) can be strengthened
lle-itA~(t)
Proof.
(i),
so that for all
#(t) = e-itA~_ + it
has a unique
on a Hilbert
Suppose
(iii)
mapping
conditions -valued
that
method which at
t = -=.
functions
~(t)
I I~ I Isca t ~ ~ ~
holds,and
for
~(.)tX(n,~_)
define ft (~)
(t) =
As in the proof of Theorem is a continuous
function
e-iA(t-s)J(~(s))ds
I, it is easy to check that e-iA(t-s)J(~(s))
of s for each t.
I II~(t) I {I ~
(61)
Further.
II le-itA~_I I I + ~ ~ 2n
since
-
74
-
we have,
l lJ(~(s))II <_B f i~(~)Ilaq Jl*(s){f
by (57)
< 8 ( 2 n ) q + l ( l + l s l ) -dq
so, the right hand side of (61) makes sense and
I1(~*~(t) ll <_ it I l e_iA (t-s)J(~(s~) I Ids < 8(2n)q+l [ t (1 + Isl)-aqds
(62)
J
since
dq > I.
Also,
iJ ( ~ )
(t) IIa < I~
IIe-iA(t-s)J(~(s))
lads
t
by (59)
< c ~' (l+ft-s)-a(lIJ(,Cs))flh + IfJ(*(s) ll)ds
--
<
2 J_~
c
2
B
ft
(l+It-s[)-a{ [lr
< C 8(2n)q(l+2n) < m
c 2 8(2n)q(l+2q)c
q I+ 21 I~(s) I I) } ds lla(
(l+It-sl)-d(l+]Sl) -dq ds
(63)
(l+Itl) -d 3
by the lemma proved after the completion of this proof. I I l ( ~ ) (t) IIi < -- We now define (M~) (t) = e - i A t ~
and choose
by (57)
no(and 6 in the case
+ (~)
Therefore
(t)
q = I) small enough so that
8(2~ q+l I_~ (1+Isi)-aqds <_ no/2
(64)
-
75
-
c 8(2no)q(l+2qo)C 2
< n /2
~
3
--
0
it is easy to check that (M~) (t) is continuous. Thus, for ~ ~ no, M maps X(q,~_) into itself. Furhher, it is easy to check using (58) that by choosing q O still smaller
(or 6 in the case q = I) we can guarantee
that M is a contraction.
Thus,
since
X(q,#
space, M has a unique fixed point
~(-)
of M, ~(.)
(60).
is a global
solution of
in
) is a complete metric X(q,~_).
By the definition
Notice also that
I I I~(') I ] I <
2~ O 9 To prove uniqueness,
let ~ (t) be another
solution of
(60) with
1
I I I~ ! (t)I I I < ~.
Then
~(t)-~, (t) T I <
t
<_
s
<
Bcllle(.)ll
B(ll~cs)
I
t l IJ(~(s)) - J(#, r
I a + lie (s) ]a )q lie(s) - e
+ Ille,(')l
t)q(
) l lds
(~)llds
s u p Ilecs)-e -~<s
st ~l+lsl)-dqds
r z
-
SO
sup -~<s
]~(s)
- ~
(s) tf 1
tt
<
{~r
I~(-)l
I + Ill~ r !
11, q I
J_
el§
dqds
sup il Cs,
But this gives a contradiction
for t sufficiently
~(s) = ~ ! (s)
for all
By local uniqueness
~(s) = ~ ! (s)
for all s.
To show that
sup r
s < t.
~(t)G[ scat
Cs,
--m<s
close to
1
-~ unless
(see T h e o r e m
I)
for each t; we fix t and compute:
i ie-irA~(t) [ i < supl le-irAe-itA~I i + it I 1e-iA (t+r-s) J(~(s)) I ads r -~
-
i supl]e-irA~-II + B
76
-
It I Ir
r
ll q I Ir a
-~
IIr
§
sup(1+IrT)Ul le-irAr
1 Ids
~0
I la _< sup(1+Irl)dl le-i(t+r)Ar II -
r
a
r
+ sup(i+lrl)dlt r
lle-iA(t+r-s)J(r eo
! sup {(l+Irl)d(l+It+r[)-dl[r r + sup{ (l+Ir I)d [t (l+It+r-sl)_d(l+iS I)_dqds } 8c2 (l+2no) (4no)g r -= no + ~-- )
<_ sup{(1+Irl)d(l+It+rl)-d}(IIr r Thus, r
& ~scat"
To prove (b) and (c),we estimate:
I Ie-irA (eitAr (t) -*_) I I s it I le_irAeiSAj( r
< ~ ,|
qa l l,Cs~llas
s 8(2no)qno
(l+Isll-dqds
--
) O
Taking
r = o, this proves (b)~
Ifds
Further,
as
t § -=
-
7 7
-
(l+lrl)dl le-irA(eitA~(t)-%_) I la
r
I~ Ile-iACr-s)jr
t c 2 (l+Ir-sl) -d {IIJc~Cs))II < (l+Irl)d I_. + I IJr
--< (l+r)dc2
< 8 C2(2~ O
SO, if
It -. (l+Ir-sl)-ds{2i I~(s)Ilqla l~(s) II
+
.
ds
+ I l~(s) l Iqa}
I)d(l+Ir-sl)-d(l+Isl) -dq ds
q > i, sup(l+Irl)dIIe-irA(eitA~(t)
- ~_)I[ a
as t § -= by part (b) of the lemma below. follows that
o
From this and the above it
lleitA#(t) - ~ IIsca t ~ o
as
t
§
-m
, I
Notice that the solution of (60) constructed above satisfies
~(t) = e-iAt~_ + It -e-iA(t-s)J(~(s))ds
= e -iAt { ~
+ I~ e-iAsj(, (s))ds}
+ [t e-iA(t-s)J(%(s))ds o
so
ds
~(t) satisfies
(52)with ~O = ~-- +
;~
e-iAsj(~(s))ds
-
The following
Lemma
(a)
lemma completes
Suppose that
|
(b)
-
the proof of Theorem
q > I,
d > o,
and
16.
dq 9 I. Then
-dq ds ~ c ( l + J t l ) -d
r162
Suppose that
sup
78
q > 1,
d > o,
and dq > i.
((1+l~l)d It2 (1+Ir-sl ) - d r
Then
~o
t]
as
t ,t 1
Proof.
~
+=
or
2
To prove
t ,t 1
>
(a) it is sufficient to consider the case where t is
large and positive.
The proof for t large and negative
We break the integral
is similar.
into two parts and estimate:
( ~+ I t-s I )-d ( ~+ I ~ t ) -dqds <_ (1+~) -d
and for
-~ .
2
! r 1+1 ~ I ) -dqds
d # 1 ,
I
3~(1+1t-
s
)-d(l+Isl)-dqds
t
(65)
t <
(l+~l-dq
{I
(l+(t-s))-dds t
! 2 (I+~)"aq (r
t + 13~ (l+s-t)-dds} t
r(I+~)-d+I+I) }
-
79
-
< c(l+t)-dq -d+l + c(l+t) -dq
< c (l+t)
since If
dq > 1 and
-d
q > I.
d = 1, the right hand side of (65) can be estimated
by
2(1§ -q log(1+~) < c (i+t) -I
since
q > I
if
d = I.
Combining
these estimates
proves
(a).
We will prove (b) in the case t ,t § +~. We assume that t, is ] 2 large and positive and divide the domain of integration into two parts.
(l+lrl)d
I
.
(l+lr-sl)-d(l+lsl)-dqds
r 3r
It I 't 2]~[~' T ]
r )-d ! (1+Irl)d(1+1~l !~\ (~+lsr)-dq~s [~, ~r [t , T] t
!
and assuming
c
I~t
(l+Isl)-dqds
(66)
!
d # I
(l+Irl)d
!
rr 3r](l+Ir-sl)-d(l+Isl)-dqds
It I t 2 ] n L 2 , 2
J
< (l+Irl)d(l+I~l)-dq
I
(l+Ir-s I)-dds
"
3r Lt t2].[~r] -
r
-
< (l+Ir[) d
80
-
r -dq [c+c(i+(r I)-d+i1 (i+I~()
< c (l+Irl) d(l-q) --
2
< c (l+It
since the integral
The case
d = 1
The fact that part case
q = 1
is actually
I) d(l-q)
is zero unless
Combining this estimate q > i.
special
+ c (l+Irl) l-dq
1
and
+ c (l+It,l) l-dq
r ~ ~ t I.
(66) we see that
(b) holds since
is handled as in the proof of (b) of the lemma holds only if
in all that
false in the case
q
follows.
(a). q > 1
dq > i,
l makes the
To see that the conclusion
= I, notice that
I
t*+l(l+It-sl)-d(l+Isl)-dds t! > (l+It +ll)_d --
!
It l(l+It-sl)-dds +I t
l
= (l+It +ii) -d Ii(l+Isl)-dds !
if
t = t . 1
0
Thus, sup t
rt +I (l+It )d ]ti(l+It-sl)-d(l+Isl)-dds !
l~lhil o(l+isl )_dds l+[ti+l
We now have global existence
and the right properties
To construct the scattering operator we must construct ~(t) - e-iAt~+ ) o as t ) +~.
at
a ~ +
-~ so that
-
81
-
Theorem 17 (the scattering operator Assume all the hypotheses of Theorem
for small data) 16 and let ~(t) be the solution
of (60) corresponding to ~o sufficiently small,
with
(a)
There exists
~ _ i [scat
~+6 [scat
' with
The map
topology)
~_ - - ~ #+
) o
as
(in the
II
{~ & [scatlIl~l Inca t ~ n O } into the ball
{~& [scatlIl~l Iscat ~ 2~o}"
Except in the case
q = i, the following
(c)
- ~+[}scat ---) o
(d)
I leitA~(t)
S is continuous
Proof.
also hold:
as t § +~
]l.llscat -topology.
in the
IIl~(t) lll
From Theorem
16 we know that
I leitIA% (t)
- eit2A~( t ) I I < I I It2eiSA J (~(s))dsl 1 2 Jtl
I
!2no.
Thus,
--
< I 'Bi1 (s) IIq II <s) IIds
--
a
! < 8(2no)q+II~2
(l+Isl)-dqds i
by
(57).
Thus
{eitA#(t)}
is Cauchy in ~ a s
t § +=
L~tting
~+
=
lim t§
eitA~(t)
we have ll~(t)
- e-itA%ll
§ o
for
t + +~
is a one to one and continuous
map of the ball
Then,
l~+llscat ! 2~ o, so that
I l#(t) - e-itA~+l I
(b)
I I~ I Iscat ~ n o .
as t§ +|
since
dq > i.
II
-
by the unitarity of
e -itA.
82
-
To show that
~+ E [scat' observe that
eitA~(t) = ~_ + it eiSAj(~(S))d s
Letting
t § +~
we conclude that
~+ = #_
+ I|174
NOW, by (59) and (57), I Ie-iA(t-s)J(~(s)) lid -< c 2 (l+It-s
< c
B
< for each s and t.
s(1+It-sl~'a~ll~r
R
C
--
~-d~{{ar162
+
{{ar162
q (I+211~cs) II)~
8(2no)q(l+no ) (l+It-sl)-d(l+Isl) -dq
2
Since for fixed t,
e-itA~+ = e-itA#_ + [~ e-iA(t-s)j(~(s))ds
we conclude that
I le-itA~+ IIa < ~
sup(l+ltl)dlle-itA~+lf
and
a
t
sup(l+itT)dlle-itA~ IIa t
+ c28(2no)q(l+4no)SUp{(l+Itl)
t
d I ~-
r162
-
83
-
n0 sup(l+Itl)dlle-itA~_lla + ~-t
by the lemma
(part a) and the choice of ~o
ll%llscat
This proves
Thus
no + ~- ~ 2no
DO
+ ~-
(a).
We can now define S: {# ~ s c a t [
~ ll~_llscat
in Theorem 16.
~_ § ~+
I l~IIscat ~ ~o } into
and it is clear that S takes {~ ~ [scat
[I@l Iscat ~ 2no} "
The proof that S is one to one is similar to the uniqueness proof in Theorem 16.
To prove that S is continuous
proceed as follows. and let ~n(t) and
]l~m(t)-4='(t)ll
< II ~ -~'~'I I_
< I I ~ * ' - ~ ~' II +
-
l~L~'(s) l 11)qlt
(x+Isl)-dql lr
[ I < ] l ~ (1~ "422 I lexp{
By part
[IJ(~'*'(s))
dq > I, interation of this inequality
I I~r
I I" I I-topo~ogy we
ft
J(~'~'(s))!Ids
(z+lsl) -dq] l~U'(s)-@~'(s) 11as
I las implies that
S(4no)q(z+[sl)-dqds}
(a) , eiAt (r
as
It
+ s(111~S"(s) lll + I qt + s(4n o) ;_|
Since
in the
Let ~ I and ~ be in {~I II@[Iscat ~ n O} @21(t) be the corresponding solutions of (&O),Then
- 42'{t))
t § ~ , so we conclude that
]I J l,9 ~i** _ ~+I T,+
-
84
-
(67)
which proves that S is continuous To prove
in the
II'll norm.
(c) we estimate:
(z+[rl)d] ]e-irA(eit~A~( t
) - eitIA~( t )I Ja 2
!
_< (l+Irl) d It2 [ le-iAr tl d
/t2
< (I+)r$> c B| --
2
II ds a
(1+}r-si>-a(li~(s>li q +2)l~r
"t,
i1~r
il>ds
a
_< c 8(2no)q(l+2~ o) 2
{(l+Irl) d ;t2 tl
(l+lr-sl)
-d( l+IsJ)-dqds}
By part (b) of the lemma,the sup of the right hand side goes to zero as t , t § +~ if q > I. It follows in this case that eitA~(t) is 1
2
eauchy in the To prove Let
II.mlscat (d) we use
4 .I (t),@ 2. (t)
norm so (c)
mleitA#(t)
- ~+IIscat + o
and the continuity already proven in (67)
be as in the proof of (b) and define:
ocs)
= r162
-
~'r
lla
and P(t) =
sup Q(s) -~<S
Then, Q Ct) <
(l+ltl)dl
le-itA(~u_~
+ (l+Itl) d It --co
_
as t + +-
~(2f )
II
II e-iA(t-s) cJ r162162)
-
J
(,'2'r
I [a as
-
<
I14 ~'-
~llscat
+ Bc ( 1 + I t l )
9I~|
85
-
d
I~'1'C~ Ila + I I~'~'(~)lla)q-~l
< II~"- ~'llscat + Sc (4no)q-l(l+Itl)dlt
+ 2Bc r
II~'*_' -
where
we
have
lemma
we
see
used
(67)
J~'*'Cs) - ~'(s) I lad~
(l+It-sl)-d(1+Isl)-dqQ(s)ds
~=_'IIscat(l+Itl)dlt(l+l
in t h e
last
step.
t-s )-d(l+Isl)-dqcl8
Thus,
uslng
part
(a)
of the
that
Qr
< c lJ~'- 4~'Ll
+ Bc r su~ Qr
< c I I~l' _ ~ I 4 -
+ ~c P(t)
--
~
--
--
scat
5 -~<s
or P(t)
where made
the
(68)
s
constants
arbitrarily
8 small
I scat
in t h e
c and c just depend on ~o a n d 8c may be 4 5 s small by choosing nO s m a l l in t h e c a s e q > 1 and
case
q =
i.
Thus,
for
no
small
enough
C P(t)
Combining
this
with
~
(67)
(i-8c) 5 we
I I~41~ - ~ f l l s c a t
conclude
that
there
is a c o n s t a n t
c
so t h a t : G
1[l~'(t) - ~x*(t)[tl < c I I~r --
Finally,
we
6
--
estimate
( l + I r l)d 1 le-irA(eiAt#l**(t)
_ eiAt~(21(t))I Ia
42,1[ --
s c a t
(69)
- 86 -
_ II~T <
~t2_'llscat+(l+lrl) d I t I I e-iA(r-s)
-
(J (*r
! c l l~'*J ~'~_'Trscat + c?l I l~m(t)-~'2'(t) I l ] (l+Irl)dI~
< c 8 I 1 ~-'-
usual
estimates
c depends
part
From
and
(69).
From this
- ~iAt~'(t)t Iscat
I ]eiAt~"(t) where
lads
(i+Ir-sl)'d(1+Isl)-dqds
~'~*[I -- scat
--
by the
)I
-J (r
on
no
(and
6 if
(67)
we h a v e
c l I~"_'- 42_'IIscat
<
q =
and
I) but
not
(70)
on t or #(,I, ~ !
(c),
) I I .I Iscat ~ ~L*)
eiAtr
-+
(71)
e
if
iA~
q > i, so in that
I1"11
~l(t )
~2) -+
scat.
case w e c o n c l u d e
that
I I~I'+ - ~'f Iscat -< c I ~'_ - ~='I_Iscat which
proves
Notice q > I, .+ ~Ln _
all
q ~
in the
tinuous
the
following
and
in
[scat
~2~ .+
norm case
in the
We g i v e going
that we have
1 we h a v e
I I .I Iscat only
(d). I
are
uniform
for all
interesting
by p a r t
continuity
finite
times
q > 1 t h a t we
can
of the m a p t
applications
on let me
16 and
17.
priori
estimates
of t h e s e
emphasize
Namely,
again
energy
inequalities
of the
linear
used.
equation
two v e r y
(70)).
f r o m this in this
important
requirement
But
that
case
%n S e c t i o n
non-linear
sufficiently
For and
~_ § eiAt~(t)
is just
of the t h e o r e m s
of the
The only
decay
only
theorems
the h y p o t h e s e s
on s o l u t i o n s
(this
conclude
I I .I Iscat n o r m b e c a u s e
situation.
(a) of the t h e o r e m
in the it is
S is con-
d o e s (71)
II.
hold.
But b e f o r e
aspects
of T h e o r e m s
did
require
not
equation
nor w e r e
was
the
rapidly
all for
that
and
that
any
solutions
the n o n -
-
87
-
linearity be of s u f f i c i e n t l y high degree.
In particular,
the method
w i l l w o r k for cases w h e r e the c o n s e r v e d e n e r g y is not b o u n d e d below. The idea that one can d e v e l o p a s c a t t e r i n g theory for "small data" goes back to the paper by Segal ~3~].
In this paper Segal concentrates
on applications to the K l e i n - G o r d o n equation with many special properties of the kernal of
e -iA(t-s)
up
interaction and are exploited.
S t r a u s s ~ $ ] simplified Segal's W o r k and formulated the p r o b l e m in terms of abstract hypotheses on A and J. of Strauss'
ideas in [%7].
We have followed the e l a b o r a t i o n
-
9.
Global existence There
88
-
for small data
is amother aspect of Theorems
that is deserves hypotheses
(i),
16 and 17 which
to be set out separately. (ii),
is so important
That is, if we have the
(iii), then the initial value problem at
t = o,
namely, ~(t) = e-iAt~o + I I t e -iA(t-s) j (~(s))ds o
(~)
$(o)
=
$o
has a global solution
]Ir
if
t
is small enough.
The proofs of
this and the other parts of the theorem below are almost exactly the same as the proofs of Theorem
16 and 17.
Theorem
for small data)
18
(global existence
operator on a Hilbert space ~ itself.
Suppose that there exist norms
hypotheses
(i),
in Section
8.
(a)
For each
(ii),
(iii) of Section
~o i [scat
Let A be fixed.
existence Further,
8 hold.
' the equation ~(t)
Let
]l~ol]scat
of part {al holds
for all
nO > o
into
~scat be as defined
I lr
- e-lAte II
II$(t)
- e-iAt$+ll
)
''>
(a)-1
~
I [~ol ]scat ! no"
and
~+ in ~scat so that
o
as
t
o
as
t ---~ + ~
(~+) -I ~(o) ~
in the
{c)
(iii)), then
q > 1 (in hypothesis
or ~ is small enough.
so that the global
#o satisfying
#o' there exist
are one to one and continuous If
~
II -II b so that the
(1) has a global continuous
if either
Then there exists
for each such
and the maps
ll- lla,
Then,
[scat -valued solution (b)
Let A be a self-adjoint
and J a non-linear mapping of
9 - ~
r
II'I I norm. (b) can be strengthened
] leiAt~(t)
- ~ I ]scat
~
o
as
t
I leiAt~(t)
- ~+I Isca t
> o
as
t
~
+~
to
-
and
(n+)-1,
(~_)-i
This t h e o r e m
89
are continuous_
-
in the
can be used to show that
utt - Au + mZu = Xu p has global
strong
the sign of X is
solutions
II
llscatnorm.
for small e n o u g h
initial
data
x ~R 3
as long as p is large e n o u g h no m a t t e r w h a t
(see Section
II, part c).
iO.
Existence
of the W a v e o p e r a t q r s
In the case w h e r e data,
global
solutions
we can use the ideas of the
operators
on all of
will denote
[scat'
not
of
~(t)
(63).
is the
)
local s o l u t i o n
estimates
of
a contraction
(52).
in the e x i s t e n c e
The
proof
idea ~s as follows.
of T h e o r e m
+
m a p p i n g w e had to m a k e the r i g h t
( -~,T o) w h e r e T O
(if
~(t)
to an i n t e r v a l
q > i) the r i g h t
are s m a l l e v e n
if
s m a l l enough.
~ is not small.
a l l o w one to e x t e n d
fine the w ~ v e o p e r a t o r 16 and
~(t)
(existence
operator
Suppose
that there
(ii)
t i o n 8)i
Suppose that
for e a c h
uniformly
bounded
If.If-norm)
(a)
For e a c h so t h a t
( - ~,O~ are s i m i l a r
on a H i l b e r t
(i),
(72)
to
on
and g l o b a l
and thus deto t h o s e
in
For c o n v e n i e n c e
we
(72)
of the w a v e o p e r a t o r s )
itself.
(in
local u n i q u e n e s s
+ it e -iA(t-s) j (~ ( s ) ) d s o
so t h a t the h y p o t h e s e s
o < It[ < T.
Then
solution
-~
the i n t e g r a l s
equation
= e-itA~(s)
Let A be a s e l f - a d j o i n t of ~ i n t o
this
just s k e t c h the proof.
integral
is close to
In this way we get a s o l u t i o n
S i n c e the d e t a i l s
17 w e w i l l
the b a s i c
19
~ .
If we are w i l l i n g
sides w i l l be small b e c a u s e
( - ~,T o) w i t h the r i g h t p r o p e r t i e s . existence
mapping
(62)
sides of t h e s e e s t i m a t e s
to r e s t r i c t
Theorem
16 w e r e
( # ~ ) (t)
n
Theorems
As b e f o r e we
~ (t)
s m a l l and we d i d this by c h o o s i n g
restate
initial the w a v e
In o r d e r to m a k e
(M~) (t) = e - i A t ~
then
for all
by M t the m a p
The c r u c i a l and
exist
just on a small ball.
M t : ~ (o)
where
(52)
last s e c t i o n to c o n s t r u c t
and ~,T
space'and exist n o r m s
hold w i t h
the s o l u t i o n s
for all
J a non-linear I I-IIa, I I .If b
q > I (see SecMt~(o)
I I~(o) II ~ n
of
(72) are
and all
Then,
~_ G [scat ~(t) ~ [scat
there
is a u n i q u e
for e a c h t, and
global
solution
~(t)
of
-
i I~(t)
(b)
The m a p p i n g
(c)
which
: r
~+
Proof. Let $--e [scat is not a s s u m e d small). $(-)
on
as t § -~
§ o
as t § -~
is a one to one map of
continuous
statements
and the map
functions
§ r
is u n i f o r m l y
Analogous
t + +~,
- ~ _ilsca t
~_
-
- e-iAt$_l i § o
lieiAt~(t)
[scat
91
as in
on b a l l s
(a) and
in
(b) hold
[scat
into
[scat" for
~+ ~ [scat'
: ~+ § $(o).
be given, w i t h li$_ilscat ~ n (note that n Let X(n,$_,T) d e n o t e the ~ - v a l u e d c o n t i n u o u s
( - ~,T]
so that
II i~(t) - e-itA~_l i I (-|
+
sup i I~ ( t ) - e - i t A ~ _ I I -~
sup ( l + I t t ) d l -~
l@(t)
- e-itA$_I la
< n
For each T, X ( n , ~ _ , T ) . i s
a complete
metric
space.
We d e f i n e
~
by
(61)
and M by (M~) (t) = e - i A t r
The e s t i m a t e s that
(63) of T h e o r e m
ill ~ (~) (t) aiD (_.,T ] can be made
close to same
(62) and
+
-~,
so in that case M w i l l
sort of e s t i m a t e s that we need
the smallness. for each
Just
t ~ ( -~,To]
By the ~ s t i m a t e s
(t)
16 and the f o l l o w i n g small by c h o o s i n g
take
X(~,#_,T)
show that M is a c o n t r a c t i o n
and so M has a fixed p o i n t Notice
(~)
~(.)
in
as in T h e o r e m and that the (62) and
into itself.
in
The -~
fixed T O .
(b) of the lemma to p r o v e
16 one can p r o v e that limits
show
for T close to
X ( n , ~ _ , T o) for some
q > 1 since we need part
lemma
T sufficiently
~(t) C[sca t
(a) hold.
(63) we can use the same T O for all
- 92
r
II~_IIo
with
~ n.
Thus, we can define the map T o 2+ :
on
~q
r
~
r (T o)
§
E {~ E [ s c a t l I l @ I l s c a t ~ q}.
and 17,
-
By the same proofs as in T h e o r e m
is a one to one uniformly
continuous map of ~ n
16
into
[scat" It can easily be checked
that for
t ~ TO
our solution
r
satisfies
r
= e-iA(t-To)~(To ) +
It T
Since J is Lipschitz locally
by hypothesis
in a neighborhood
boundedness uniqueness earlier
hypothesis t ~ To .
(57),(58),
of
r
implies by T h e o r e m 14 that, .
this equation
r
= Mt_ T r
in t.
coincides with the
imply that
r
r
prove that M t is a uniformly
~(t) defined
is in
(72)
[scat for all t.
of M t assumed in the hypothesis (58) and
continuous
Now,
By local
satisfies
for each t, M t is uniformly
This combined with
[scat for each fixed t.
can be solved
o) and by the
is global
It is easy to check that and (59)
J(r
o
(iii)
by
In fact, the uniform boundedness balls in ~
-iA (t-s)
on M t this solution
this definition
for
and that
of T O
e
continuous
on
(59) can be used to easily
one to one mad on b~lls
in
for each ~ we define T o (q)
~+ = That is,
~+ : ~_
By the properties uniformly takes
of
M_T
continuous
[scat
easy argument proves
M _ T o (~) ~ +
(a) and
into
[scat
shows that
#(o)
To(n) , we have that ~+
and
map of ~
)
into [scat"
and is uniformly ~+
~+ is a one to one
Since n was arbitrary, continuous
is one to one on all of
~b); the proof of
(c) is similar.
on balls. [~cat"
[scat" -
The existence
then we can construct
of the scattering operator
An
This
B
This theorem shows that when we have the hypotheses on J and global existence
~+
(i) , (ii),
(iii)
the wave operators on depends
on whether
-
range
93
-
~+ = range
~_
-i
so that we can d e f i n e is d i s c u s s e d in Section hypotheses
(i),
S = ~_. 12.
(ii), and
This
(much more difficult)
proble~
We remark that in a p p l i c a t i o n s not all the
(iii) may be satisfied.
Often one can con-
struct the w a v e o p e r a t o r s anyway by using special p r o p e r t i e s of the p a r t i c u l a r equations and the idea of T h e o r e m 19. of this in Section llc.
We w i l l see an example
ii.
Applications In this lecture we will sketch some a p p l i c a t i o n s of the theorems
in sections 8,9,10.
In most cases we will not give very many details.
Our main purpose is to show how one chooses the norms and
II. ll b
in a variety of situations.
I I" I I, I 1" I Ia,
The typical p r o c e d u r e is as
follows.
The n o r m
II. IIa
is a sup n o r m on some or all of the com-
ponents.
The norm
I I. I Ib
is then the best
which one can prove the decay estimate to be a Hilbert space norm which holds.
(i.e. lowest)
(ii).
Then
is as simple as possible so that
This is usually done by a Sobolev inequality.
norms
If" If,
II'll a,
p r o b l e m alone.
norm for
I Io I I is chosen (i)
Thus, the three
If" IIb are t y p i c a l l y d e t e r m i n e d from the linear
One then checks to see what p r o p e r t i e s the n o n - l i n e a r
term J must have so that
(iii) holds.
is interested doesn't satisfy change the norms
(iii)
if the J in w h i c h one
one may be able to go back and
I I I l,I I I la, l I I Ib
In all our examples we treat
Of course,
so that it does.
B = /- ~ + m 2 as though it acted on
powers of functions like differentiation.
The correct details can be
easily supplied as in part A of section 2. Part A.
The n o n - l i n e a r S c h r S d i n p e r e q u a t i o n
We begin w i t h an easy example,
the n o n - l i n e a r S c h r S d i n g e r e q u a t i o n
in one dimension, u t - iUxx + ku p = o u(x,o)
(73)
= f(x)
because it illustrates nicely the method for c h o o s i n g the norms described above.
The c o r r e s p o n d i n g
free equation
is
u t - iUxx = o u(x,o)
with
A
=
-
d 2 ~ .
The
= g(x)
solution can be written e x p l i c i t l y as
dx 2
u(x,t)
=
(4~it)'I/&I ei(X-Y)K/4tf(y)dy
-
95
-
and thus, t-~/2
I lu(x,t)i Therefore,
we
cannot
rem
flu[I|
thus
satisfied
choose
L2(R)
[ lU[ {~ ~
Ilfll
choose
11ul[a: we h a v e
I. <_ T-~.
C{IU{ I 2.
4 in part
,
llullb:
]Is[I,
hypothesis
(ii) w i t h
as our H i l b e r t
space
However,
I
d = ~
because
in one d i m e n s i o n
c of s e c t i o n
.
Notice
it is not
it is t r u e
that
that true
as u s u a l
2):
Thus,
we take
+
B = ~/':-A
(i)
is s a t i s f i e d .
2
To check
for w h i c h
we compute,
I ld(u 1 ) - d(u 2 )11 = KIIB(uP 1 = KP[I(Bu
uP) ll 2
-
1
)u p-].1
_< KPII(Bux)(u~
§ KPlI(Bu
< cllBu
(74)
m 2.
l]ull : IIBull so t h a t h y p o t h e s i s
that
(see T h e o -
I lulloo ! cl IBull 2V2 l[ulI2~ -< c i IIBull where
we
1
(Bu)uP-I'll 2
2
2
- u~)P(u,,u2)Jl2
- Bu)uP-Xll 2 2
1
II,llu,
+cilBCu
2
2
- u I[~lIPcu
- u )2 l l
2
2
Ilu
p-I
1
II ~o
,u)ll| 2
p
(iii)
holds,
--
< cllBu
--
1
I1
IIB(u
2
+cllBcu~ er
llu,ll and
for
with
holds
I IJr
1
lla + Ilulla
g = p-2.
= I luP1 - u~ll
< Bllu
we must
have
and
q
17 p r o v i d e
equation The p is d u ~
Part
B.
of
1
II
- u
the
first
hypothesis
in
r
)11
IIU2
- u 2 )11
data
dq
global
> i.
1
(llu, II 2 +llu, tl)(lilu,
2
II.
1
(iii) a l s o h o l d s
> 2 so t h a t small
1
- u 2 II(llu
1
application to S t r a u s s
of t h e s e
+ Ilu~ll2
with
if
I1| p-2
2
p-2
q = p-2.
Therefore
existence
ll.+ll'.
Now,
since
d =
p > 4, T h e o r e m s
and a s c a t t e r i n g
theory
16 for
small
utt - U x x + m Z u = lu p
need
data
techniques
to
(73)
for h i g h
[38].
to discuss
the
utt first
+ I1%.11=) p-2
(73).
In o r d e r
we
Ilu
Thus,
- u)Q(u 2
1
--
part
)p-2
small.
< cllBr
second
(tlu.,ll,=
2
Similarly,
= IIr
so the
- u 2 )11
- u~)ll~ Ilu~ll~ -~
llull
) - J(u 2 )lib
1
96--
a decay
equation
(75)
- U x x + m a u = lu p
estimate
utt
, one d i m e n s i o n
-
for the
Uxx
linear
+ m2u
= o
U(X,O)
= f
Ut(X,O ) = g
equation:
(76)
1
-
Although
this
is a fact about
vial so w e w i l l o r o v i d e Lemma with
1
Suppose
Ilu(x,t)[I.
Proof
.
a linear equation,
the p r o o f
is n o n - t r i -
and let
u(x,t) u(t)
u(x,t)
be the s o l u t i o n
of
(76)
Then z +
~ Ct-ua{]]f][
For each t,
-
a sketch.
f,g(~(R)
initial data
97
[If'll
x +
= u(t)
If"ll * + ]lg'l]
*+
llgll *}
(77)
is g l v e n by
= cos(Bt)f
+ sin(Bt) B
g
or
sin(/-~/~t) ~(k)
A
u(t)
Thus
u(t)
= cos(/--~t)
~R
= /~
(k 2 + m 2 ) ' ~ 2 s i n
The convolution There
follows
analyticity
of
Second,
of
that
differentiating
and s u b t r a c t i n g
since
R(x,t)
R 9 /'(R)
the
function
theorem
t h a t we w r i t e
1
r~
J-we
twice with respect
the r e s u l t s ,
R(x,t)
R(x,t)
Thus;
for
ik x
in the
that
in two d i m e n s i o n s .
--
g ~ ~(R). is.
Here
x 2 < t 2.
for d i s t r i b u t i o n s
(k 2 + m2)-Zl2sin ~/~-~+~t
Suppose
and
is zero e x c e o t w h e n
we can c o m p u t e d i r e c t l y
H( t~-T~-x 2 ) - R(x,t)
x
dk
in the s e n s e of d i s t r i b u t i o n s . sense
transformations t 2 - x 2.
transform
sin~~t
to f i g u r e out w h a t
and g r o w t h
Rig
Fourier
from the P a y l e y - W i e n e r
under Lorentz function
makes
F i r s t we n o t i c e
k directions.
Then,
+
I ~_ e i k x
/k 2 + m2t
R~g
are m a n y w a y s
is one. This
= ~ f
for each t , R is the i n v e r s e
R(x,t)
of
+
can be w r i t t e n
u(t)
where
f(k)
and the
imaginary is i n v a r i a n t
R(x,t)
is a
x 2 < t 2,
sin /k 2+m2 t
Wt~'+m2
dk
to t and t w i c e w i t h r e s p e c t
one finds that
H(t2~--x2 ) satisfies:
to
-
m2H,,(
tZ_x 2) +
98
1 H'( t2-x 2
-
t2-x 2) + H(
tZ-x 2) : o
SO
H(
t2-x 2) : CJo(m
where J is the first Bessel function. 0 1 that c = ~ . Thus, 1 R(x,t) = ~ X
(78)
{xlx2!t 2 }
(x)
t2-x 2) Setting
x = o, one determine%
Jo(m ~/~-~-x %)
Therefore, we have the representation:
z/t
(79)
(R~g) (x,t) = 2
To analyse the decay of R i g
-t Jo(m ~ - y % )
we need the estimates
(2
(8o)
g (x-y) dy
Jo(~) : .V~- o
cos(~ - ~ )
(see, for example,
+ 0(p'~)
J 1 (.) = a(p -"~) as p ) ~ We write (79) as an integral over {Y[IYl ~ ~ } and an integral over {YI~ ~ IYl ~ t}. Using IJo(p) I ~ cp -*12, the first can easily be estimated by
ct' ,-t/2[t/=
fdy
_
l I.gl
There are two integrals left one of which is
1
(~)
1 (~)
%u2 rt ]t/2Jo(m ~---~-~) g(x-y)dy
V2 It
COS ( m / ~ - ~ - ~ )
t/2 (t2-y 2) V~
t
g (x-y) dy +
I
t/2
O( (t2-y 2)'~) g (x-y) dy
(8z)
-
99
-
For the second term we have
i
t O((t 2 - y2)'31~)g(x - y)dy t/2
! ct-'"llg11| t/2 (t
- y) "31~dy
< ct-"2Jlg, II --
I
To handle the first term, we integrate by parts obtaining:
(t2-~ 2) U~ -
] y=t sin (m ~
g (x-y)
+ ~ )
my ~
+
] y=t/2
I t sin(mt*~-~ + ~ ) ~y [(t2-~2,)~Wg(x-y) } dy
I
m2Vr- t/2
Y
ct-U2(11gll
Both terms may be easily estimated by Combining this with (81) we have
IIR-gl I. ! ct'"~ (I IgIl, To treat the
~R
~-~f
+
(82)
~R
(~f)
+ llg'll
1
).
IIg'II )
term, notice that
DR = 51 (6(x+t) + 6(x-t)) + m ~-t so
I
i[ f(x+t)
(x,t) = ~
+ f(x-t)
t
J (m t~/~T~-~)
]
+ 5m It_t ~-~t--L"- j, (mt~/~_y,}f(x_y)dy
First we estimate the integral over {yly 2 ~ t 2} as before. Then we integrate the remaining integral by parts, observe that the boundary terms at
y = +t cancel the first term in (82), and estimate the other
boundary terms and the remaining integral just as we did for
R ~g.
- I00-
The result
is
aR I I (-,~*
The extra
f) (x,t) I I|
derivative
tion by parts. For
c t - ~ ( I Ifll
i
on f o c c u r s
This
proves
f and g nice,
this
the
IIf'll
+
1
because
1
IIf"{I 1 )
+
there was
one extra
integra-
lemma.
lemma gives
us a d e c a y
estimate
and
leads us
to define
IIl[ a =
[lu][~
II {b = I l u l l , + We take
as o u r H i l b e r t
W o=
Then,
by
(74),
since we
~ ~
with
[1~
- ~nl Ib
and
linear
since
(i) holds.
,it
and
follows
this holds p
I l J ( r l)
J(~b )1
_< c l ~ l '{ I j"u '
J r 1 62 2 - u
[1~
holds.
!
Ixl
< --
that we don't quite have
on
D = ~(R) X~(R).
b
=
- ~nl I
) o.
Since
(ii) yet
However,
given
~ n G D so t h a t -itA e is c o n t i n u o u s
that
_< Ixl
I IJcr 1
Notice
for e a c h n.
(iii)
llv'll I
IfBult, + llvll ~ < |
I [~II b < " ,we can find a s e q u e n c e
for which
-
II1~11 ~ =
the estimate
) o
I +
space
{~ =
only know
+ flu II + llvll I
I{u'{{
Thus we have
Since
J(~)
Ilu p1 - uPl{ 2
{ x l ( l l u P 1- u P l f
2
It r e m a i n s
to check
2
Ilu, - u~ II ~ ( l l u l l l ~
clxl(ll~,lla+
(ii).
= < o , k u p>,
+
l u 11.) p-1
1~211a )p-1
lu I - u 2 II
1
+ l I D ( u P1 -
uP) I{ 1 ) 2
I~ +11,*'-, u'lll(llu~ ,11~+ Ilu~ I~)(llu, ll.+llu~ll,.) p-2
-
Since
16,
17, and
data and the e x i s t e n c e p > 4. N o t i c e p is either
that
In the case w h e r e
18, global
of the s c a t t e r i n g
this
even or odd
have global
result
Furthermore
energy
is b o u n d e d Mt
in
cases we have the e x i s t e n c e
Theorem
20
(a)
initial data consta n t
If
of T h e o r e m
solutions
ll~olIscat
Further,
p is odd and
19 are s a t i s f i e d operators.
of
norm
so
The com-
We summarize:
(75)
exist
if the
(or the c o u p l i n g
the s c a t t e r i n g
I is n e g a t i v e
(uniformly
of lemma
II. Ilscat
operator
the w a v e
exists
operators
continuous
1 we used the exnlicit
in terms of the Riemann
derivative.
This
are other
is the s t a n d a r d
fancier ways
function "old
to d e r i v e
exist
on balls)
fashioned"
However,
for c in terms
n o r m on the
of a t r a c t a b l e
to use the old methods. to the case
in von Wahl
of
if we want
n = i.
A large number and Costa
technique
[46].
(see[9
is the proof of d e c a y
then
])
llull~.
an e x p l i c i t
initial data
of the
and its time
ct -v2 d e c a y of
The proof we give
[42], [43]
representation
of the e q u a t i o n
the
See for e x a m p l e [ ~ ] , a n d [ , ~ ] .
found
bounded
itself.
In the proof
adapted
(like we did
is u n i f o r m l y
on such small data.
If in a d d i t i o n
There
~(t)
is an open question.
~o has small enough
and are one to one maps
into
)
of the wave
D > 4, then global
I is small enough).
and is c o n t i n u o u s
soluti o n
the h y p o t h e s e s
operators
then we
fact that the term
c I ul Ip+l to show
: ~(o)
in t he s e
of the wave
~ and w h e t h e r
dx
by
on balls
pleteness
Thus,
we can use the
u p+I
4) that the m a p p i n g ~o"
for small d a t a if
the sign
(or fractional).
~
in Section
operator
for small C a u c h y
p is odd and the sign of I is negative,
existence.
in the c o n s e r v e d
existence
holds w h a t e v e r
I
[scat
{I~ , - ~ 2 {l
the e s t i m a t e s in h y p o t h e s i s (iii)are satisfied w i t h q = p-2. 1 d = ~ and dq > 1 we must choose q > 2 so p > 4. We have thus
proven by T h e o r e m s
(b)
-
{I~ 2 lla )p-2
s (ll~,l{ a + Thus,
i O 1
estimate
it is easiest
in Strauss
estimates
[212
can be
-
Part
C~
u~t
- Au + m 2 u
In o r d e r dimensions
Lemma
to h a n d l e
we
2
first
Let
= lu D
, three
dimensions
the n o n - l i n e a r
need
Klein-Gordon
a lemma w h i c h
f,g G C = ( R 3)
'-
1 0 2 -
O
And
let
equation
is a n a l o g o u s
u(x,t)
be the
in t h r e e
to l e m m a
I.
solution
of
"
utt
- AU + m 2 u = o
u(x,o) = f(x) Ut(X,O)
Then,
there
is a u n i v e r s a l
constant
= g(X)
c so t h a t
(83)
luCx,t){[. ~ ct-"2llJlb where
{ {i . ,b I
is d e f i n e d
as the
sum of the L
norm
of all the
1
derivatives
The proof [~|]);
of f of o r d e r
of this
only
lemma
< 3 and
is s i m i l a r
the d e t e r m i n a t i o n
complicated.
The
cause
R(x,t)
itself
extra
twice
for the
all the d e r i v a t i v e s
to the
of the
derivative
involves
J
proof
f o r m of
on the . Thus,
of g of o r d e r
of L e m m a I
R(x,t)
initial
(see S t r a u s s
is a l i t t l e
data
One m u s t
< 2.
comes
integrate
more
about
be-
by p a r t s
1
So, we
g terms
choose
and t h r e e
, l~i I I ,b
times
for the
to be as d e f i n e d
f term.
in the
lemma
and
II~ la = llul]. Then,
(ii)
longer
use
is s a t i s f i e d
for n l c e
the H i l b e r t
snace
ci IBul I 2 in t h r e e so we
can use ~ .
~o
dimensions. That
is,
because
then
(i) holds.
with mension
As
I i~I] b < -.
if we
show that 7
in part
B one
that
However true
w e can no
that
I lul I,
i lul I~ _< cl IB2ul r 2
set
+
ii~ii
=~IIirl
Further,
it is not
It is__ t r u e
liii 2 = IfB2ulI, ~i
3 d = ~ .
data with
can n o w
similar
~
< | ] extend
calculations
(83)
to all
to t h o s e
~ 6~S
in one di-
- 103
-
l lJ(4~,) - J(~){{ = 1~1 [lB(u puP) ll 2 l 2
(84)
<_ Ix (II~ , [[ +.I[r , ll)(I[r T h e r e are m a n y t e r m s highest
order
llJ(#,) - J(~2)ll,.
in
in D (denote by
<
-
Let us look at one of
D i any p a r t i a l d e r i v a t i v e ) .
I{(D[lu
,u)II
-u))Plu
+ 21 [ (D i(ul
+
a + I I~ z l la)P-2lI~-, ~,II
- U2 ) )DiP(uI'u2) I I I
EIIu~- u~)D[P(u,u)ll,
<__C({[Bu 1[2+ ]]Bu2{[ )(]{u []=+ []uz{[=)P-2
IlB=(u,
- u)l{
(85)
+cc{{Bu ii + lIBu [121~cfiu E{.+ {lu~li~) D-3 L1u-u
i[.
<_ fl { ( [ l ~ x i l a + l l ~ 2 I i a ) P - 3 1 I # , - ~ 2 1 1 a + ([I~,II a + l l r
Thus,
(iii)
is s a t i s f i e d w i t h
t h a n in one d i m e n s i o n in all d i m e n s i o n s ) .
q = ~-2
I I~,- ~2iI
for s l i g h t l y d i f f e r e n t
(you s h o u l d not a s s u m e that Notice
)p-2
in the case
q = p-2
reasons
is all r i g h t
q = 1 , the c o n s t a n t
~ in
(iii)
if I I~ I i + I ]~ 11 is small as r e q u i r e d (see (84) and (85)). 3 i 2 d = ~ we n e e d o n l y c h o o s e q ~ i, so o _> 3. For all such p,
is s m all Since
T h e o r e m s 16 and
17 give a small d a t a s c a t t e r i n g
utt - Au + m 2 u = lu p
independent
of w h e t h e r
the r e s u l t s
ere s o m e w h a t
For of the
p > 3 integral
solutions c).
p ~s
Theorem equation
initial data existence
of g l o b a l w e a k
x e R3
(86)
in the two cases
18 g i v e s g l o b a l corresponding
strong
is s m a l l e n o u g h
for the e q u a t i o n
e v e n or odd and the sign of I.
different
are s t r o n g l y d i f f e r e n t i a b l e
Thus we h a v e g l o b a l
,
theory
existence to
(86).
of
and
that
p = 3.
strong solutions these
(see S e c t i o n
2, part
of 86 for all p ~ 3 if the
(or I is s m a ll enough).
solutions
Notice
Furthermore,
in t l o c a l l y
solutions
p > 3
for all d a t a
We a l s o k n o w the
(Section
5).
What
-
1 0 4
-
remains open is the d i f f i c u l t p r o b l e m of proving global strong solutions for large data. Notice that as the d i m e n s i o n is increased three)
(in our case from one to
the s c a t t e r i n g theory gets easier because the decay of free so -
lutions is better
(though
I I II b
is a little more complicated)
but
the global e x i s t e n c e theory gets harder because the Sobolev e s t i m a t e s are weaker.
This puts us in the following peculiar p o s i t i o n w i t h regard
to the wave operators.
To use T h e o r e m 19 to guarantee the e x i s t e n c e
of the wave operators we need to k n o w global e x i s t e n c e of strong solutions.
In three d i m e n s i o n s we only know this for
and I negative).
p ~ 3 (with p odd
On the other hand the hypotheses of T h e o r e m 19 ex-
clude the b o r d e r l i n e case
q = p-2 = 1 and thus require
p > 3.
There-
fore, as it stands, T h e o r e m 19 says n o t h i n g about the e x i s t e n c e of the wave operators
in three d i m e n s i o n s if D = 3.
This provides us with an o p p o r t u n i t y to illustrate a very important point.
Namely, the h y p o t h e s e s of the abstract theorems
in t h e s e lec-
tures are quite general in that they depend only on estimates r e l a t i n g A and J
(and energy inequalities).
Therefore,
the conclusions are some-
times not as strong as those one can obtain by e x p l o i t i n g special properties of the e q u a t i o n being studied. of proof as in T h e o r e m s
Typically,
one uses the same idea
16, 17, 18, 19, but the step which fails on the
general level is carried through using the special property. To see how this works
in the case
p = 3 (where we know global ex-
istence) notice that the r e a s o n that T h e o r e m 19 cannot handle the case q = 1 is that (l+Itl) d times the e x p r e s s i o n (63) on page 7 ~ does not go to zero as
t
case
Thus we need a new way to estimate:
q = i).
> - ~ (because part
I le-iA(t-s)J(~(s)) I la =
(b) of the lemma excludes the
I I ~ -Isin B(t-s)]u(s)'I I.
< Cll (k 2 + m2)- *12(sin / ~ ( t - s ) )
< CII (k 2 + m2)-l11211 (k2+ m 2 ) ~ 2 ( 9 )
<_ cl IB(ucs)')112
/% u"(k) II
(k) I12
_
105
_
Using this estimate
in place of the ones before
through
This how Segal originally
as before.
the wave o p e r a t o ~ for
(63) the proof goes
proved the existence
p = 3 in three dimensions
(see ~ ] ) .
of
We summa-
rize: Theorem
21
~
If
p > 3,then global
tial data has small enough is small). tinuous ~
I l#ollscat
Furthermore
-norm
the scattering
of
(86) exist
if the ini-
(or the coupling
operator
exists
constant
and is con-
on such small data.
In the case
p = 3 and I negative,
Part D. The Coupled
the wave operators
Dirac and Klein-Gordon
In order to discuss in three dimensions, itself.
solutions
the coupled
we will
first
Equations
Dirac and Klein-Gordon look at the non-linear
We can write the free Dirac equation
(x,t) = -i(i~.V
equations Dirac equation
as
(89)
+ iSM)~(x,t)
-;De~ (x,t)
=
(x,o)
exist.
= f(x)
where ~(x,t)
=
<~o(X't) ' ~z ( x , t ) , ~ 2 ( x , t ) , ~ 3 ( x , t ) >
f(x) =
The
e i s!
and
a formally
On
~
~
8 are certain
self-adjoint
f (x), f2(x), I
f (x)> 2
~
anti-Hermetian
operator
on
4M4 matrices.
i~oL3(RS).
L2(R ~) then the anti-commutation
properties
If
we
let
Thus,
D e is
Be = ~
of the ~i's and 8 (see
[ [ ]or [~ ]) imply that
2
D2e =
Further
De
I OBe
is self-adjoint
0 B2e B2e
~ ~2e
on the domain
(88)
-
106
D(D e) =
and since
D e commutes with
-
.e
D(D e)
--ZBe it commutes with all powers of
Thus, we can take for our Hilbert space any of the escalated
Be"
energy
spaces: 3
9~ : (*I II,II~ ~ [ liB,,ill ~ < | i=o
Further,
the group
into themselves operator on
e -itDr
and this
~k
generated by
implies
D e takes each of these spaces
(~2~,p.269)
that
D e is a self-adjoint
with domain _k+l. ~o D(B e )
D(D e ) =
By the properties
2
of the
u's and
satisfies the Klein-Gordon
8, each component
~i(x,t)
of
~(x,t)
equation ~2 I
2
~i + Be~ i = O
~t 2 ~i(x,o)
= fi(x)
(x,o) = gi(x)
where
gi is the
.th component of I
-iD f. e
II~i(~,t)]I| a ct"~ where
I fll b
of all the
denotes
fi's.
Thus, by lemma 2 in part c,
IIfIIb
the sum of the L I norms of all derivatives
Thus,
~ 3
if we define 3
II~IIa =_~
II~i(x,t) II|
i=o we have
II~lla _< ct -'~ Ilfllb We are now ready to treat the non-linear
~t + iDe~ = AJ(~)
(89)
Dirac equation (90)
-
107-
w h e r e we will assume that each component of ~i's
each of w h o s e terms has order p.
J(~)
is a p o l y n o m i a l in the
The a p p l i c a t i o n of T h e o r e m 16,
17, and 18 differs in one respect from the application to the n o n - l i n e a r K l e i n - G o r d o n equation in part c. J()
=
IIJ(~) il b
The n o n - l i n e a r term of part c ,
was zero in the first term so the worst terms
looked like
llB2uPi]z.
Here J looks like ~P(symbolicallv)
in each component so the worst terms in liB~Pi]z._ thesis
in
I IJ(~) I ib
will look like
Thus, we cannot hope to satisfy the second part of hypo-
(iii) unless we choose as our Hilbert space ~
so that the n o r m
3 3
2
rl~il' : 11,1123 : i -[- o lIBe~iIE has three d e r i v a t i v e s on each component. example, that This term
But, this means,
just as in part c but now we will have we must require
I IB3(~P) I I 2~
(iii)) can be e s t i m a t e d
q = p-3
(instead of
p - 2) so
p ~ 4 in order to apply T h e o r e m 16, 17, and 18.
Suppose that each component of
J(~)
~i each term of w h i c h has degree at least 4. equation
for
IIJ(~) II w i l l be a sum of terms of the form
(and the other terms in h y p o t h e s i s
T h e o r e m 22
2
is a p o l y n o m i a l in the
Then the n o n - l i n e a r Dirac
(90) in three d i m e n s i o n s has global strong solution
Qauchy data is s u f f i c i e n t l y small
(in the
if the
II.T Jscat norm). F u r t h e r m o r e
on these small data the scattering operator exists and is continuous. Now we can set up the spaces and norr~for the coupled D i r a c - K l e i n Gordon equations:
d J (~,u) T 0 + iDe~ = Xe e (91) utt- Au + m~u -- XoFo(~,u) w h i c h we rewrite as ~t + iDe~ = XeJe (~'~) (92) Ct + iAor = loJo (~'r
where
# = ,
B O = ~- A + m O ,
Jo(~,~)
Je (~,u) ,and A~
-B o
o
= , Je(~,~)
-
as usual.
1 0 8 -
We take as our Hilbert space
with the norm
on
~ = <~,~> given by 3
2 + liB2uti22
2
II II~- i=o [ lIB'~ill 2
IBsuII2
+
Then the operator A =
ID e
o
o is self~adjoint
1
A~
on
D(A) = 4i_~o D(B~)) (~ (D(B ~) (9 D(B3))
and if we set
J(-)
= then we can write
(92) as
-' (t) = -iA---(t) + J(-(t)) which
is in the right
We define of
I IHI Ib
~i' i=o,i,2,3,
(93)
form to apply the theorems of these
lectures.
to be the sum of the L* norms of all the derivatives and u of order
vatives of v of order
< 2.
~ 3 plus the L* norms of all deri-
And, we set
3 I---~Ia = ~. I I~il I~ + [lul I~ i=o The three norms with
I I I I, I I "I Ia , I I "I Ib satisfy hypotheses
d = 3/2, so it only remains
must have so that
(iii)
linear Dirac equation wer.
Theorem
23
(ii)
From the calculations
on the non-
like the calculations we have already done.
16, 17, 18, we have:
Suppose that
are polynamials Je
is satisfied.
(i) and
Je and Jo
and part c you should be able to guess the ans-
The proofs are exactly
So, from Theorems
to check what propert•
Fo(~,u)
and each component
of
Je(~,u)
in the ~i and u so that each term in the components
of
has order at least 4 and each term in F o has order at least 3. Then the coupled equations (91) have unique global solutions if the I I I Iscat
- 109norms of the initial data are small enough data in
[scat
if
1o
and
le
(or for auy fixed initial
are taken small enough).
Furthermore
the s c a t t e r i n g operator exists on these small initial data and is continuous. This t h e o r e m does not cover the case of a Yukawa i n t e r a c t i o n
Je(H)
= leU~u r
9
Jo (H) = lo~Yo~
because the degrees are too small, but it does cover g e n e r a l i z e d Yukawa interactions of the form
Je(- ) = leU(~7o~) k
for any
k ~ 2.
,
Jo (-) = lo(~Yo~) k
You can easily formulate for y o u r s e l f the analogous
t h e o r e m for two coupled Fermi~ns
mddt ~m _ i~2,e~m = IE2|e~e(~m,i,,~,)
w h e r e degree four is
required in both terms.
C h a d a m applied these small
data ideas to the classical v e r s i o n s of the equations of q u a n t u m field theory in [ 6 ] .
He uses more d e l i c a t e
(Lp) decay estimates and more
i
special p r o p e r t i e s of the Dir~c and K l e i n - G o r d o n p r o p a g a t o r s handle more cases.
I
For example, I
he only requires degree 3.
so he can
in the F e r m i o n - F e r m i o n case above,
12,
Asymptoti 9 Completeness
We come n o w to a r e a l l y h a r d q u e s t i o n , completeness. satisfied
Let us s u p p o s e
so that t h e w a v e o p e r a t o r s
to o n e m a p s of that is, if
~scat
i n t o itself.
~+ exist ~f
the s c a t t e r i n g
of T h e o r e m
19
are
and are c o n t i n u o u s
are a s y m p t o t i c a l l y
~
Range R ~ = Range
t h e n w e can d e f i n e
the p r o b l e m of a s y m p t o t i c
t h a t the h y p o t h e s e s
one
complete,
~_
operator
s = (~+)-i~_ T o see w h a t is a
is i n v o l v e d
~ _ E [scat
let
#o
be in the r a n g e of
and a s o l u t i o n
.
Thus there
of
r
= e - i A t ~ _ + it
r
=
e - i A (t-s) j (~ (s))ds
SO t h at
r
and
lib(t)
- e-itA~_Jl
W h a t we m u s t p r o v e
is t h a t t h e r e
(94)
l[~(t)
If
is true t h e n
(~)
)
- e-itA~+I[
o
as
is a )
t
)
~+ ~ [ s c a t
o
as
t
-~
so that )
+~
#+ = l i m eitA~(t)
since
e
-itA
show that
is u n i t a r y ,
elAte(t)
is a
so the n a t u r a l w a y to c o n s t r u c t
Cauchy s e q u e n c e in W .
~+
By h y p o t h e s e s
w e h a ve l leitlA*( t ) - e i t 2 A * ( t * z
< --
'I l=r t 2
<_, ,3
I 2
l laqr
I Ids
is to (iii)
-
i i i
-
In general we get an upper b o u n d on
II~(s) II from an energy inequality,
so what we need to know, to insure that the right hand side goes to zero as
t , t $
---)
+~, is that
2
l" For example,
II~(s) ll~,~s < -
in the case of the equation
(95)
utt - Au + mZu = -u 3
x~R 3
the required estimate is
e~
What is needed t h e r e f o r e is an apriori estimate on solutions
of the
n o n - l i n e a r equation w h i c h guarantees that solutions w i t h nice initial d a t a decay s u f f i c i e n t l y rapidly in the Furthermore,
I I -I Ia n o r m as
t
> +-
.
if we expect to be able to prove c o n t i n u i t y of the scatter-
ing operator we need to estimate the constants in this decay in terms of the decay of the c o r r e s p o n d i n g solution of the free equation.
For
most n o n - l i n e a r w a v e equations no such apriori e s t i m a t e s are known (or only very weak estimates)
so one cannot even b e g i n to attack the
p r o b l e m of asymptotic completeness.
However,
in the case of
three d i m e n s i o n s this p r o b l e m has been solved by M o r a w e t z [~t)].
(95) in
and Strauss
Their t h e o r e m states:
T h e o r e m Z ~ Let
~
denote the closure of
C o ( R ' ) X C o ( R 3) in the n o r m
II112scat = suPt {!I u~ + IVu[2 + m2u2)dx}
+ sup sup t
where
u(x,t)
u(x,o)
= f,ut(x,o)
(95) exists and is a continuous
Further, of
_~ J x
denotes the solution of the free e q u a t i o n u t t - A u + m 2 u = o
w i t h initial data for
lu(x,t) l 2 + | suplu(x,t) I2dt
x
if
e~
and
(95) w i t h initial data
Vf
= g.
Then the s c a t t e r i n g operator
one to one map of ~
onto itself
has finite energy, the solution
satisfies
~(x,t)
-
112-
II~(x,t) l l . <_cr
-3'~
The crucial fact w h i c h made this t h e o r e m possible was a new apriori estimate w h i c h was derived from a weak apriori estimate p r e v i o u s l y o b t a i n e d by M o r a w e t z [ ~ .
I r e c o m m e n d this argument to anyone who wants
to see how b e a u t i f u l and d i f f i c u l t these n o n - l i n e a r theories are in case you are not already convinced).
(just
The same arguments go through
for a fairly r e s t r i c t e d class of other n o n - l i n e a r terms d e s c r i b e d in an a p p e n d i x in [~|3. M o r a w e t z and Strauss prove further p r o p e r t i e s of S in [~]. Basically,
there are two kinds of arguments in [~|]. The arguments
used to derive the apr~ori e s t i m a t e and other n e c e s s a r y e s t i m a t e s use the e x p l i c i t r e p r e s e n t a t i o n of the Riemann function for the free equation and methods from partial d i f f e r e n t i a l equations.
These t e c h n i q u e s
are n e c e s s a r i l y d i r e c t l y related to the p a r t i c u l a r d i f f e r e n t i a l equation being studied and t h e r e f o r e do not g e n e r a l i z e the abstract
level.
However,
in a natural way to
the second part of the M o r a w e t z - S t r a u s s
argument is e s s e n t i a l l y a functional analysis argument w h i c h shows that, given the estimates,
one can c o n s t r u c t the s c a t t e r i n g operator.
This part of the argument can be formulated on the abstract
level and
it is the purpose of the rest of this section to outline how this may be done.
Since the most important thing is the general s t r u c t u r e of
the argument we will just outline the ideas.
Details may be found in
Reed [I~. Since there are quite a few hypotheses, we will collect t h e m all here rather than refer back to previous
sections.
The h y p o t h e s e s
fall
n a t u r a l l y into four parts: I (Existence) (with n o r m
I I" I I) and let J be a n o n - l i n e a r m a p p i n g on ~ w h i c h
[96~ Then,
Let A be a self-adjoint operator on a Hilbert space
IIJr for each
-Jr
~o & ~
I 1 ~ - ~11
' the c o r o l l a r y of T h e o r e m
I gives a local so-
lution of [97)
satisfies
~(t) = e-iAt ~o + I t e-iA (t-s) j (~ (s)) ds o
-
We denote
by
is a p r i o r i implies
Mt
that
: D
the
~(t)
is a d e n s e
of free D
I IJ(~)
for some
set of
§ #(t)
result
= Mt# ~
C~
D wou~d Cauchy
solutions)
that
: D
be of the
compact
there
which
Finally, )
we
Doo and
form
~
v%~4
D(A n )
support.
is an a u x i l i a r y
norm
so t h a t
r > o
D-valued
and all function
,t I
e -iAt
typically
We a s s u m e
inequality)
in t.
so that
IIMt~oJ I
that
of an e n e r g y
data with
- J(4) I I _< c(I I~II ,1141 I)
IIl~(')lllt
and a s s u m e
is g l o b a l
set D in ~
-
(Decay
norm)
: ~(o)
(typically
solution
there
to the
II.ll a on
(98)
the
Mt
) D. In a p p l i c a t i o n s
or e q u a l
II
bounded
that
assume
M t the m a p
113-
= 2
#,~ ~ D. on
sup t
I1~ - ~II
If
tl,t2,
~(-)
--
I1 ~(t) ll 'r +
IIII
(in the
sup llg~(t) ll r + [t211~(s) r t t
2
When
t = -- and t = -,we denote 1 2 E D, w e a s s u m e t h a t
--
ll
a
ds a
2
the n o r m
Ille-itA~ll
(99)
is a c o n t i n u o u s
we define i
(I 1411 ra + 11411 r)
1
simply
by
II1-III.
If
I < -
and d e f i n e
II~llscat The
Banach
closure
III
space
of s c a t t e r i n g
of D in the
(the a D r i o r i
IV.
f is a l o c a l l y
(Kernel
functions
on
Estimates) It I, t2].
that
function
~(.)
Define
1
the
for all
~ e D,
~ f(IT~Ilscat)
Let
[[,~(.)] ]rt
is by d e f i n i t i o n
[scat
We a s s u m e
bounded
~eD
norm.
IIIMtr
'(100)
where
states
I l-llscat
estimate}
= Ille-itA~lll
,t
on
and
for each
= 2
t
s
t
(o,-).
4(')
be
pair
(tl, t2), r
~11~(t) I I a !
continuous
ds
D-valued
-
114
-
and Jt ! ,t 2
(~) ( t ) =
[~2 e-iA (t-s)
J(~(s))ds
i We assume that
Jtl,t 2 satisfies:
lllJt ,t (~) - Jt ,c (~)III ~cr162 i
2
I
(lol)
,t 'lll~(')lllt ,t)
2
I
"([[~]]t
,t 1
9 ( sup
+ [[~]]c 2
Ilk(t)
,t 1
- ~(t)
2
I
)o~, II I,~(t)
- ~(t)
ll It'
2
ll
2
2
')
t
(102)
IIIJt ,t r
_~ c(IIl*(-)ll It ,t ) [[*]]t ,t I
I
where the
~i (which are independent of
#(-) and
2
I
2
~(.)) satisfy
ui > o, u I + u3 -> I, ~2 + u3 -> i. (iOl)and (102)are further assumed to hold ~n the case where t 2 = t on the left and t2= = on the right and similarly for
If we let
t I = t and
Xtl,t 2
t I = -~.
denote the closure of D in the
norm, then what we are essentially assuming is that H61der continuous , norms~ from on and
and
Jtl,t 2 is locally
in both the
Xtl,t 2 to
I~l~tl,t2
Ill Ill tl,t2
I II I IItl,t 2 and the s u p II I I tl!t!t 2 X.~,~) where the constant depends appropriately
llI~]Iltl,t2, since
sup I I#() I I ! III~( )IIltl,t 2
tl<_t<_t1
e2 + ~3 Z I, Jtl,t 2 is actually Lipschitz in the
I I III Itl,t 2
norm. In applications, such estimates are typically proven by expressing e -iA(e-s) as an integral operator and using L p estimates on the kernel and non-llnear term J. A simple example of such an estimate appears in Section ii, part c. For other examples, see S e g a l [ ~ ] , ~ ] , Chadam [ ~ ] , [6], Morawetz and Stauss[~|], and Strauss[3F]. The proof of the existence of the scattering Qperator begins by investigating the properties of
{M t}
and
{e-iAt}.
-
Lemma 1
115
The families of mappings,
uniformly equicontinuous
on
-
{e -itA},
{M t}, and
{~itAM t}
, are
I I.I Iscat-balls in D.
The proof of Lenuna 1 proceeds by first showing that continuous by using the kernel estimates and iteration.
M t is I I ,I IThen this is
used to show that {eitAMt } is an equicontinuous family similarly to the proof of continuity in Theorem 17. Since e -itA is, for each t, linear, bounded and of norm one on shows in particular continuous map of
[scat
the integral equation to
into itself.
Eemma 1
extends uniquely to a uniformly Since the extension satisfies
(97) it coincides with the restriction of
M t on
[scat"
The ~ollowing to
[sc9 t the lemma follows.
that for each t) M t
lemma shows that the apriori estimate also extends
[scat"
Lemma 2
There exists a locally bounded function
I I IMt~l I I ~
~(I I#I Iscat )
for all
~
on
(o,~) so that
~ ~[scat"
Lemma 2 is proven by choosing a sequence
~n ~ D
so that
I I~n - #Ilsca t > o. First one shows that Mt$ n converges to Mt~ and then one takes the limit in the apriori estimate which gives lemma 2 with ~(x) = lira f(y) We can now prove the existence of asymptotic states: Theorem 25
The maps [scat Proof
For each
~
into
~ & [scat there exist
~+ and
~_ in [scat so that
I IMt~ - e-itA~+11
~ o
as
t
~ +~
llMt~ - e-itA~
) o
as
t
) --
~ ~+
9
~
II
~
#
are continuous
and one to one from
[scat"
We will give the first part of the proof since it shows how
the apriori estimate and the kernel estimates are used. be given and fix t I and t 2.
Let
~ ~ [scat
Then,
I leit~AMtl ~ - eit~AMt2~l Iscat = I I le-iUA(eit~AMtl~-eitzAMt2~) If I
-
=
116
rjt2 e_iA(u_s)
Ill
-
J(Ms~)dsl[[
tI
<_ I1 t [Jtl,t a (Ms~') ] (u) II 1 I+~ 4
! c(111%*11tt1,%)
[[Ms*33t,,t= i+~ 4
! C(I I~1 I scat ) [[Ms*]]tl,t
2 IIl~t~ll
By the apriori estimate we know that
I < - which implies that
l+u 4 o
[[Ms*]ltl,t 2 Thus as
eitAMt~ t
~ -~
[scat so we can define
The convergence e -ira
.
lim eitAMt ~ t++~
statement~
By lemma I, the
formly equicontinuous proof that
as
is Cauchy in
#+ =
as tl,t 2
,
t
)~
~ +~ and the same is true
~_ = lim
eitAMt~
t~--~
in the theorem follow from the unitarity of
.. maps
a21
a21
and
are pointwise
limits of uni-
families of maps and are thus continuous.
are one to one uses the ~ernel estimates
as in the one to one proof in Theorem In order to construct
The
and same trick
16.
the scattering operator we need to know that
the maps ~+I just constructed take [scat ont___~o [scat and that are continuous. To prove this we must solve the Cauchy p r o b l e m at
•
~.
Given
~+ E.;scat, the solution of
II~(t)
- e-iAt#+II
)
(97) which satisfies
o
as
t
should be the solution of
(103)
~(t) = e-itA~+ -
e-iA(t-s)J(~(s))ds t
> +~
~
-
There are two difficulties.
But, this
it as a lim•
closure
of D in the
~N(N)
= e-iAt~+
= e-iAN~+
In particular,
be proven
is that as
to a solution 3
(104).
< ~
To conclude
of vectors
,
(97) with Cauchy data
Lemma
]lle-itAr
that
in D since
I I " Isca t norm.
~N(t)
in I.
,
~(o)e[sca t
_[scat
we must
was defined
Thus, we define
as the to be the
#N(t)
of
(104)
Since
|
(|03) has a solution
that is,
is not quite enough.
exhibit solution
Ill<
-
First we must show that
with the right decay properties,
][1~(t)
117
Let Then,
of
- [Ne-iA(t-s)J(~(s))ds ~t
~N(t)
e-iNA#+ if
~+~D,
is just the unique at
t = N
then
N --> ~, ~N(t)
global
guaranteed
~N(t) E D converges
solution
of
by the hypotheses
for all t. (Dointwise
What must in
[scat )
(103).
@+ E D
and let
@N(t)
be the corresponding
solution
of
if T is large enough,
(a)
] l'l~N(t) I I IT ~ ~ 2[ I [e-itA~+l [ IT,~
(b)
[[~N(t)]]T, ~
< 2 [[e-itA]] --
T,~
The point of this lemma is that the right hand sides are independent of N and thus give us some control Lemma in
3 is proven
by defining
of the limit of the
the space
B(T)
as N § ~.
to be the set of
~(-)
XT, ~ so that
I ] l$(t)
- e -itA~+ I IT,~ -< 1!le-itA@+llIT,~
[[~(t)-
e-itA#+]]T,
< [[e-itA~ --
and then showing that lies in the
~N(t)
~f.
B(T) Next
for all we h a v e ,
for T large enough N > T.
L
]] +I~T,
the solution
~N(t!
The proof uses the strict
~
(104)
pg~$vity
of
-
Lemma
4
(a)
Let
~N(t)
as
N § = ,
which
be the solutions ~N(.)
satisfies
-
discussed
converges
in
(c)
~(t) 9 [scat
to a function
~(t)
for each
t E IT,=)
][]eitAo(t)
and
- #+)IIscat--9 o
t --~+~.
To prove
lemma
in ~emma
4 one first uses the kernel
3 to show that
to check that the pointwise (b) follows
statements
Then,
(103).
I I I~(t) I l IT,. ~ 211 le-itA~+l I IT,.
formity
above.
XT, =
(b)
as
in
118
#N(.)
limit
estimates
is Cauchy
~(t)
satisfies
from the uniform estimates
~+ ( D
and the uni-
XT, ~.
It is easy
(103) and the estimate
on the
in (c) also use the uniform estimates
For fixed
in ~N.
The proof of the
from Lemma
3.
we can now define
n+T : r
)
~+ : ~ +
) M_T~#
r (o) +
~+ is thus a map from D into [scat and (by Theorem 24 and its proof) ~ I ~ + ~+ = ~+. Similar definitionsand statements hold for ~T_ ,~_. What remains to be shown is that ~+ can be extended and that the extension is continuous. Theorem 26 fudction~(.) (b) into
[scat
(a) Let # + E [scat; then there is a T and a [scat-Valued which satisfies (103) and parts (b) and (c) of Lemma 4.
The map
T > M_T~+~ + is a continuous
~+ : ~+
map of
[scat
[scat"
If ~+ were uniformly proof of Theorem from D.
on
ll#+llsca t but also on
- ~Ilscat
)
o.
on T. Let
is a T so that
in D then the
just extend
First one chooses ~n(t)
balls
~+ directly
since the choice of T depends
[[e-itA~]]T, ~.
Thus,
a sequence
be the corresponding
Then one first shows that there
that there
ll.llscat
26 would be easy; we would
some local uniformity (103).
continuous
But, this is not at all obvious
not only on II~
to all of
one needs n ~+ 9 D so that
solutions
of
is an N so that n > N implies
- 119
If e
-itA. n
-
-itA n
~+I11 <_ 2k
r247174 <--~o
lie
for a c o n s t a n t k and a small constant 8 o. This u n i f o r m i t y and the fact that show that of
#n(.) are Cauchy in
#n(t)
satisfies
(103)
allow one to
XT, m and c o n v e r g e to a solution
#(t)
(103) w h i c h has the right properties. To prove c o n t i n u i t y one uses the same idea to choose a small
so that for all
qo
~+ in the ball
B(no'~+) = (~+r
II~+ - ~+llscat !no}
one can use the same T and u n i f o r m estimates
11 [~(t)I I IT,. _< [[~(t)~,.
hold.
21 l~+I Iscat
< 2 [[e-itA~+]]T,.
With these u n i f o r m e s t i m a t e s the proof of c o n t i n u i t y proceeds T ~+ is
by iteration much like the proof of T h e o r e m 17 to show that u n i f o r m l y c o n t i n u o u s on ~+ = M _ T ~ ~
B(no,~+).
is u n i f o r m l y continuous on
continuous on
Thus,
T h e o r e m ~7
B(no,~ +) since
M t is u n i f o r m l y
[scat balls for each t.
Of course, analogous .
F r o m this one concludes that
s t a t e m e n t s to those on T h e o r e m 25 hold for
c o m b i n i n g T h e o r e m 25
and T h e o r e m 26
The s c a t t e r i n g o p e r a t o r
tinuous map of
[scat onto
S =
we have:
~
is a one to one con-
[scat"
I have two remarks to m a k e about this theorem.
First, a l t h o u g h
it looks very nice, r e m e m b e r that we assumed the e x i s t e n c e of an apriori estimate
(hypothesis III).
If the e x p e r i e n c e of M o r a w e t z and Strauss
is any guide r the proof of such an aDriori e s t i m a t e is the h a r d e s t part of the problem.
Secondly,
there is no reason to think that our choice
of norms, spaces, and estimates
in h y p o t h e s e s
II and IV give the best
general a b s t r a c t result or are the only choices possible.
In fact,
in
a p a r t i c u l a r application, one may have an apriori e s t i m a t e but some of the h y p o t h e s e s
in II or IV may fail so that one can't apply T h e o r e m
-
27 directly.
1 2 0
-
In such a case one will have to choose ~hher norms and
spaces w h i c h are b e t t e r suited to the p r o b l e m at hand.
Some t e c h n i c a l
details of the c o n s t r u c t i o n of the s c a t t e r i n g o p e r a t o r w i l l then be d i f f e r e n t but the general idea should follow the o u t l i n e p r e s e n t e d here.
13. D i s c u s s i o n
It should be clear theory
for n o n - l i n e a r
partially
solved
and discuss
First of all,
problems.
there
since one must the norms
would
second
operators
general
(seeing])?
problem
but t r a c t a b l e
of the w a v e
as functions
consider
the coupled
(ul)tt - ~u
+ m2u 1
(u) 2
T hese
1
- ~u tt
equations
have
2
the wave
operators
investigate
right hand
symmetries Another has the tively, should
that
of various
1
operators
given by T h e o r e m
of the theory.
2
+ ~u )3_ 28u u 2 l
z
conserved
2
energy
properties
various
if
].
I > o,
in Section
of ~+ as f u n c t i o n s
internal
scattering
coupled
is to prove
of
c
operators
have the same
is broken.
non-linear scattering
such a d e c o m p o s i t i o n
equations
It w o u l d
that the s c a t t e r i n g
for the small data
to
I,~,~.
Dirac
symmetries.
the s v m m e t r v
19 is another
8 > o and
Ii, part
It should be i n t e r e s t i n g
form S = I + T w h e r e T is a "small"
Whether
com-
the b e h a v i o r
parameters
2
= -41e(u
a case w h e r e
this must be true
on [scat
+ ~u )3 _ 28u u 2
~
problem
groups)
equations
the small d a t a
interesting
scattering and to inves-
and i n v e s t i g a t e
1
display
or to e x h i b i t
be proven.
symmetry
in the case of n o n - l i n e a r
sides w h i c h
understan-
w o u l d be to take more
can be shown to exist.
imagine
be nice to prove
to exist
and u s i n g the t e c h n i q u e s
the a n a l y t i c i t y
One can easily
not advance
do they commute w i t h the n a t u r a l
terms
= -41(u
a positive
is any real number
and choose
greater
small data
(or other
1
+ m2u 2
provide
are known
question
non-linear
operators
For example,
that
group
but not trivial
Such work w o u l d
is to take the
interesting
and e n g i n e e r i n g
interest.
For example,
of the Lorentz
Another
we will
problems.
of them can be applied.
free e q u a t i o n
but w o ul d
physical
to harder
straightforward for the
correctly.
operators
properties.
representation
18 or v a r i a n t s
estimates
of direct
or the w a v e
their
plicated
in the physics
17,
theory very much,
ding of equations
tigate
equations 16,
or
to point out
For convenience,
from easier
I I I ] ,I I I]a,[ I I Ib
the m a t h e m a t i c a l
of u n s o l v e d
it is w o r t h w h i l e
explicitly.
be r e l a t i v e l y
prove d e c a y
that the s c a t t e r i n g
mostly
progressing
are many
to w h i c h T h e o r e m
sections
consists
Nevertheless,
four parts,
Such a p p l i c a t i o n s
The
equations
some of these problems
group them into
literature
from the p r e c e e d i n g wave
is true
more d i f f i c u l t
operator
operator. operator
Intuibut
for the wave question.
it
-
122
Ideally one would like to show that
S = I +
-
) can be e x p a n d e d as
S (or ~
~ InT n n=l
w h e r e I is,for e x a m p l e , a small coupling constant and the T n are least for low n) simple operators.
the scattering o p e r a t o r approximately. tations are w e l l - k n o w n
(at
This wo~id allow one to calculate Such expansions or represen-
in linear theories
(for example,
see[~in
the
q u a n t u m m e c h a n i c a l case a n d [ i T ] f o r the case of classical linear wave equations).
It is clear that w e could go on and on with this list of
q u e s t i o n s about S and ~+L but the above examples give the idea.
Theorems
17 and 19 guarantee the--existence of certain n o n - l i n e a r operators.
The
p r o b l e m is to investigate the p r o p e r t i e s of those n o n - l i n e a r o p e r a t o r s and how the properties reflect the structure of the n o n - l i n e a r i t i e s
in
the o r i g i n a l equation. The third general p r o b l e m is to d e v e l o p new techniques for h a n d l i n g the small data s c a t t e r i n g theory and the existence of the wave operators when
the n o n - l i n e a r i t y is not s u f f i c i e n t l y high or the decay is too
slow to allow a p p l i c a t i o n of the techniques we have presented. ample,
For ex-
consider the e q u a t i o n
(105)
utt - Uxx + m2u = -u 3
in one-dimension.
In order to prove the existence of the wave o p e r a t o r s
by the t e c h n i q u e s we have outlined,
one must have that
(see Section
Ii,
part c)| le-iA(t-slj(,(s)) . adS =
I T
I IB(u(s) s) I I ds 2
~
( --
S frBu(s) II 1lu(s) II~ds T
2
)
The t e r m
{ ]Bu(s) I {
o
as
T
~
)
~.
is of course b o u n d e d by the energy, but in one 2
d i m e n s i o n free solutions
u(s) only d e c a y like
so we can't expect this convergence to hold.
s -Vz in the sup n o r m Nevertheless,
it is clear
that there should be a s c a t t e r i n g theory for(lO5) i n t e r m s of solutions of the linear e q u a t i o n
-
(106)
- u utt
1 2 3 -
+ m2u = o xx
The rate of c o n v e r g e n c e solution
of(iO6)
will be slower;
use other norms b e s i d e s w here
the d i v e r g e n c e
cases w h e r e and
This
it really
example,
The best
this
fourth
pleteness.
but w h e r e
approach
class
fusion.
lately
wave
and there
My point that
I want
does
two cases
to consider.
not
in the Hilbert approach reason
that
spaces
non-zero
theory
case most n a t u r a l l y cussed.
they are not The more the Hilbert at
x = f~
data w h i c h
only
in one
be very
important.
is
there
of the
form
equation
u(x+t). much
literature
here
of the p r o b l e m
of a p p l i c a t i o n s
In this
for data w h i c h
the soliton
x
x = Z=,
are
are
) ~ to be solutions is no apriori
solutions
space m e t h o d s
solutions
There
solutions
as
case there
is small at
(see~).
of soliton
theory.
(many of the soliton
of the sol~ton
keeps
among physi-
is that the p r e s e n c e
that the soliton
+~).
which
Soliton s o l u t i o n s
interest
is no s c a t t e r i n g
suppose
There
seems to be some con ~
of a n o n - l i n e a r
h a n d l e d by the Hilbert
Essentially,
com-
estimates
is very difficult, are known
is they are not small enough
at
decay
would
to think that the p r e s e n c e
the s c a t t e r i n g
of a s y m p t o t i c
not
is a g r o w i n g
constants
on a p a r t i c u l a r
theory t h e r e ~ a n d
for any equations
have g e n e r a t e d
First,
in these
problem
not mean that there
"normalized",
first two b e c a u s e
on this
to e m p h a s i z e
solutions
should n e v e r t h e l e s s
apriori
this p r o b l e m results
17
techniques.
the q u e s t i o n
complete
a solution
equations
lots of other
to c o n c e n t r a t e
of d e r i v i n g
equations,
an i l l u s t r a t i o n
those d e s c r i b e d
about new m o r e g e n e r a l
before,
the a p p r o p r i a t e
of T h e o r e m s
than the
to get a s c a t t e r i n g
is a solution
for example
of n o n - l i n e a r cists
I think,
and S t ~ a u s s [ ~
soliton
are
theoty
go beyond
of this p r o b l e m ~bout w h i c h
A
its form,
is,
Any p r o g r e s s
by M o r a w e t z
one aspect
which
is, of course,
of n o n - l i n e a r
of examples.
handled
a scattering
of the n e c e s s i t y
and as we have m e n t i o n e d
There
in the methods
is much harder
is n e c e s s a r y
problem
Because
on solutions
area
suggests
We have picked
is borderline~
of integrals
techniques
do w h a t e v e r
then see what The
faster,
third p r o b l e m
requires
~ectures.
of(iO5)
of(lO5)to
in fact that one may have to
the energy norm.
the d i v e r g e n c e
19 is much
exist.
of solutions
so slow
should which
affect
is the
we have dis-
should play no role b e c a u s e
in the class of initial data under discussion. interesting space
or b e c a u s e are
case
is w h e r e
under d i s c u s s i o n we choose
large at infinity
the solitons
either
because
our Hilbert
solutions
they
are in
are small enough
space n o r m so that
initial
are allowed. If ~o is the initial
data
-
124-
for such a soliton solution, then we would not expect the soliton Mtr ~ to decay into free equations at
t = •
since the wave keeps its shape.
But this does not preclude a complete scattering theory, that we should expect that contained in [scat"
Range ~+
and Range ~_
it just says
w i l l be strictly
If one has asymptotic completeness,
Range ~_ = Range ~+
then one has the scattering operator and setting r
= Sr
then,
S = ~i~_.
the distant past, we will get out a free wave future.
Given a ~ _ ~ [ s c a t ,
if we send in a free w a v e
e-iAt~_
in
e-iAt~+ in the distant
This s i t u a t i o n is similar to the situa~cion in q u a n t u m m e c h a n i c s
where one expects that the ranges of the wave operators equal the part of the Hilbert space c o r r e s p o n d i n g to the absolutely continuous part of the s p e c t r u m of the interaction H a m i l t o n i a n
HI .
In general,
H I will
have bound states w h i c h will not decay to free solutions but this does not prevent the c o n s t r u c t i o n of
a
scattering theory.
Of course,
in
the q u a n t u m m e c h a n i c a l case one stays in the Hilbert space, the free and i n t e r a c t i n g d y n a m i c s are given by unitary groups, and the b o u n d states are n a t u r a l l y s e p a r a t e d from the s c a t t e r i n g states since they are orthogonal.
In the case of n o n - l i n e a r w a v e equations it is not
clear how to separate the initial data in [scat w h i c h c o r r e s p o n d to soliton solutions from the initial data which are s c a t t e r i n g states; that is part of the p r o b l e m of proving
Ran~+ = Ran~
, but
Ran~ C [scat"
To find an example of a n o n - l i n e a r w a v e equation w h i c h illustrates these points and to d e v e l o p a complete scattering theory for such an e q u a t i o n seems to me to be an e x t r e m e l y important and interesting problem.
Bibliography
[i]
Bjorken, J. and S. Drell, New York,
[2]
R e l a t i v i s t i c Q u a n t u m Fields, McGraw-Hill,
1965.
Browder, F.,
"On n o n - l i n e a r w a v e equations", Math.
Zeit. 80
(1962)
249 - 264.
[3]
Chadam, J., Ann.
[4] [5]
u = m2u + G(x,t,U,Ux,Ut) , I,II",
sup., Pisa,
26
equations",
J. Math. Phys.
13
(1972), 597 - 604.
Chadam, J., "Global solutions of the Cauchy p r o b l e m for the coupled M a x w e l l - D i r a c equations (1973),
in one space dimension", J.
13
173 - 184.
Chadam, J.,
"Asymptotic b e h a v i o u r of equations arising in q u a n t u m
Chadam, J. and R. Glassey,
3 (1973),
223 - 237.
Corindalesi,
coupled K l e i n - G o r d o n - D i r a c equations in Rat. Mech. Anal. 54
E. and F. Strocci,
R e l a t i v i s t i c Wave Mechanics,
New York,
1962, p. 695.
[i0] Friedman, A., Partial D i f f e r e n t i a l Equations, Winston, New York,
Math.
132
Holt-Rinehart
and
1969, p. 24.
R., "Blow up theorems
Zeit.
[12] Glassey,
North-
1963.
R. and D. Hilbert, Methods o f M a t h e m a t i c a l Physics, Vol.
2, Interscience,
[II] Glassey,
(1974)
9
Holland, Amsterdam,
Courant,
377 - 402.
"On certain global solutions of the Cauchy
(classical)
one and three sDace dimensions", Arch.
[9]
(classi-
Func. Anal.
p r o b l e m for the
[8]
33 - 65, 65 - 95.
"On the Cauchy p r o b l e m for the coupled M a x w e l l - D i r a c
field theory", J. Applic. Anal.
[7]
(1972),
Chadam, J.,
cal)
[6]
"Asymptotic for
Scuola Norm.
(1973),
for n o n - l i n e a r wave equations",
183 - 203.
R., "On the asymptotic b e h a v i o u r of n o n - l i n e a r wave equa-
tions", Trans. A.M.S.
182
(1973),
189 - 200.
-
126
-
[13~ Gross, L., "The Cauchy p r o b l e m for the coupled M a x w e l l and Dirac equations",
[143 Jost,
Comm.
Pure.
and Appl. Math.
(1966),
1 - 15.
R., The General T h e o r [ of Q u a n t i z e d Fields, Amer. Math.
Providence,
[157 J~rgens,
Soc.
1965.
K., "Das A n f a n g s w e r t p r o b l e m im GroBen fur eine Klasse nicht-
linearer W e l l e n g l e i c h u n g e n " ,
[16~ Keller, J.,
Math.
Zeit. 7 7
(1961), 295 - 308.
"On solutions of n o n - l i n e a r wave equations",
Appl. Math.
i0
Comm. Pure
(1957), 523 - 532.
[17] Lax, P. and R. S. Phillips, York,
19
S c a t t e r i n @ Theory, A c a d e m i c Press, New
1967.
[18] Levine, H.,
"Some n o n - e x i s t e n c e and i n s t a b i l i t y theorems
for solu-
tions of formally p a r a b o l i c equations of the form Pu t = -Au + F(u)", Arch.
Rat. Mech. Anal.
[193 Lions, J.,
51
(1973),
371 - 386.
"Une r e m a r q u e sur les probl~mes d ' ~ v o l u t i o n non lin~aires
dans les d o m a i n e s non cylindriques", ~,
ii
-
[20] Morawetz, Proc.
Rev. Roumaine Math.
C.,
"Time decay
Roy. Soc. A 306
21] Morawetz,
for the n o n - l i n e a r K l e i n - G o r d o n equation",
(1968), 291 - 296.
C. and W. Strauss,
"Decay and s c a t t e r i n g of solutions of
a n o n l i n e a r r e l a t i v i s t i c wave equation~', Comm. (1972),
[221
Pure Appl. Math. 2 5
1 - 31.
Morawetz, C. and W. Strauss, Comm. Pure Appl. Math.
[233 Morse,
Pure Appl.
18.
26
"On a n o n - l i n e a r s c a t t e r i n g operator",
(1973), 47 - 54.
P. and H. Feshbach, Methods of T h e o r e t i c a l Ph[sics, ~,
McGraw-Hill,
[24] Reed, M.,
New York,
1953, p. 622.
"Higher order estimates and smoothness of solutions of
n o n l i n e a r wave equations", Proc. Amer. Math.
[25] Reed, M.,
Soc. 5 1 ( 1 9 7 5 ) , 7 9
- 85.
" C o n s t r u c t i o n of the scattering o p e r a t o r for abstract non-
linear wave equations",
Indiana J o u r n a l of Math.
(to appear).
-
1 2 7 -
[26] Reed, M. and B. Simon, Methods I: Functional Analysis,
Academic Press, New York,
[27] Reed, M. and B. Simon, Methods II: Fourier Anal~sis
of Modern Mathematical
Ph[sics, Vo!.
1972.
of Modern Mathematical
and Self-ad~ointnesg,
Physics, Vo!.
Academic Press, New York,
1975. [28] Reed, M. and B. Simon, Methods of Modern Mathematical III: Analysis
of Operators,
Physics, Vol.
Academic Press, New York,
(to appear
1977). 29] Scott,
C., Chu, F., and D. McLaughlin,
in applied [30] Segal,
science",
Proc.
IEEE,
61
"The soliton:
(1973),
1443.-
a new concept
1483.
I., "The global Cauchy problem for a relativistic
field with power
interaction",
Bull.
Soc. Math.
France
91
scalar (1963),
129 - 135. [31] Segal,
I., "Non-linear
[32] Segal,
I., "Quantization
equations", Cambridge, [331 Segal, Ann.
I9
Proc.
2 (1968), [35] Strauss,
Ann. Math. 78
and dispersion
Conference
on Math.
(1963),339
for nonlinear
Theory Elem.
- 364.
relativistic
Part., MIT Press,
1966, 79 - 108. "Dispersion
,
Sci. Ecole Norm.
[34] Strauss,
semi-groups",
W.,
for nonlinear relativistic Sup.
(4)~ (1968),
"Decay and asymptotics
for
equations,
II"
#
459 - 497. u = F(u)", J. Func. Anal.
409 - 457. W.,
"Decay of solutions
calized non-linear
terms",
of hyperbolic
Symp. Math. VII,
equations with lo-
Ist. Naz. Alte Rome
(1971), p. 339 - 355. [361 Strauss,
W., "On weak solutions of semi-linear
Anais Acad. [371 Strauss,
Brazil,
Ci~ncias
W., Energy Methods
Notas de Matem~tica,
42
hyperbolic
equations",
(1970), p. 645 - 651.
in Partial Differential
Rio de Janeiro,
1969.
Equations,
-
[38] Strauss, W., "Nonlinear in Mathematical Pub., Holland, [39] Strauss, data",
128-
scattering
Physics,
theory",
in Scatterinq Theory
ed. J. A. Lavita and J.-P. Marchand,
Reide
1974, p. 53 - 78.
W., "Analyticity
of the Scattering Operator
for small
in preparation.
[40] Von Wahl, W., "Klassische im GroBen", Math.
Zeit.
L~sUngen nichtlinearer
112
[41] Von Wahl, W., "Uber die klassische f~r nichtlineare das asymptotische
Wellengleichungen Verhalten
Wellengleichungen
(1969), 241 - 279. L~sbarkeit des Cauchy-Problems bei kleinen Anfangswerten
der L~sungen",
Math.
Zeit.
und
114 (1970),
281 - 299. [42] Von Wahl, W., "L p - decay rates for homogeneous Math.
Zeit.
120
[43] Von Wahl, W., "Decay estimates Func. Anal.
9 (1972),
[45] Royden, ~46] Costa,
J.
"Zu einem Satz von F. E. Browder ~ber
Wellengleichungen",
H., Real Analysis, D., "Decay Estimates
Ph. D thesis,
for nonlinear wave equations",
490 - 495.
[44] Heinz, E. and W. yon Wahl, nichtlineare
wave equations",
(1971), 93 - 106.
Math.
Macmillan,
Zeit.
1972.
(1975),
33 - 45.
1963.
for Symmetric
Brown University,
141
Hyperbolic
Systems",
