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Existence and homogenization for semilinear elliptic equations with noncompact nonlinearity
Nonlinear Andysir. Theory. Printed in Great Britain.
Methods
& Applicanons.
Vol. 8. No. 1. pp. 5-15,
0362-546X/84 $3 00 + .OO @ 1984 Pergamon Press Ltd.
1984.
EXISTENCE AND HOMOGENIZATION FOR SEMILINEAR ELLIPTIC EQUATIONS WITH NONCOMPACT NONLINEARITY * DANIELA GIACHETTI Istituto di Matematica, Facolta di Scienze, Universita di Salerno, 84100 Salerno, Italy and MYTHILY RAMASWAMY INRIA, Rocquencourt,
B.P. 105, 781.53 Le Chesnay, France and T.I.F.R. Centre, Bangalore, India (Received
Key words and phrases: Homogenization,
12 November 1982)
G-convergence
0. INTRODUCTION IN THIS paper
we consider
the problem
of the existence Au =f(x,
of a weak solution
for
u)
P>
u E a(Q), where A is a uniformly elliptic A less than the first eigenvalue
linear operator and f is a Caratheodory of A and for some q(x) E L2(Q), f(x,.s)
SZ-0,
f(x, s) 3 As - V(X)
s d 0.
function
such that for
Here we give a very simple existence proof, using a result of [14]. The existence of a classical solution using maximum principle when f is &-Holder continuous in the first variable and locally Lipschitz in the second variable, is proved in [l] and weak solution in [6]. Then we consider the problem of convergence of the solutions for AEuE =f(x,
u,) I
UEE HA(Q), to a solution
(PE)
of the problem Aou = f(x, u) u E HA(Q),
1
(PO)
G when A, are uniformly elliptic linear operators such that A E-+ AC,, in the sense of G-convergence [12], [13], introduced by Spagnolo. The difficulty lies in the fact that f is not a compact perturbation between L2(Q) and L2(Q), since indeed it does not induce any map from L2(Q) to L2(Q). In [ll], homogenization of equations of this type, if f is Lipschitz in the second variable, is treated using maximum principle. Here the convergence of the solutions to a * This work was carried out when the first author was in Paris VI, partially supported by C.N.R., Italia and the second was in INRIA under deputation from T.I.F.R., India. 5
D. GIACHETTI and M.
6
RAMASWAMY
solution of the homogenized problem PO is shown without any regularity assumptions. Since the proof, both in the case of existence and homogenization does not use any characteristic properties of second order operators, it works for higher order also. 1. ASSUMPTIONS
Let Q be a bounded operator in the class
domain
in RN with sufficiently
smooth
&I and let A be an
boundary
laij(X) 1s p, Xaij(X)EiEj 2 cUI&I’, E E RN a.e. in Q Uii=Uji,l~i~j~~,O
w
I and A1 be the first eigenvalue of the operator A. Let f: Q x IR -+ IF! be a Caratheodory function (measurable in x E Q for any t E R and continuous in t for almost every x E S2) satisfying the following condition: There exists n(x) E L2(Q) and A. < Al such that for almost all x E 52 f(x, s) G ?Ls+ q(x)
s 2 0
f(x, s) 2 As - V(X)
SGO
(1.1)
1
and ;ug If@, s) I E L’(Q), We will consider
0 s t < m.
(1.2)
I
(1.3)
the problem Au = f(x, u) 24E a(Q),
and look for a solution
in the following
u~Hb(Q),f(.,u) (Au.o)=l/(.>
sense: EL’(Q),f(.,u)u
u ) u f oreachu
EL’(Q) EH&Q)
and
nL”(Q)
for u = u where
(. , .) denotes
the duality
between
H&Q)
(1.4)
and i
and H-r(R).
2. EXISTENCE
We state the following. THEOREM
u EH~(Q),
1. Under the assumptions in the sense of (1.4).
Proof. The problem
(1.3) is equivalent
(1 .l),
to
(A-A)u=f(x,u)-hi u E H&2).
(1.2)
the
problem
(1.3)
has
a solution
Existence
Denoting
and homogenization
for semilinear
elliptic
equations
with noncompact
nonlinearity
by B = A - A, g(x, s) = h - f(x, s),
the problem
is Bu + g(x, u) = 0 I
u E ffh(Q), where
the function
g(x, S) satisfies g(x, s) signs
We note that each function
which satisfies
2 -q(x).
(2.3)
(2.3) can be written
as
g(x, s) = g1(x, s) + gz(x, s) where
gl (x, s) and gz(x, s) are CarathCodory
functions
(2.4)
such that
gl(x, s)s * 0, Jgz(x, s) 1S 217(x) for almost allx E Q] andforsE (note
that v 2 0 because
of -q(x)
6 f(x,
0) s q(x)).
s 20
-g(x,O))-
s ‘co
1
-(g(x.s)
g2(x7s) ={ (g(x,s) by the hypothesis
-g(x,O))_ -g&O))-
(2.5)
In fact we can take
(g(x,.$ -g(x,O))’
gl(x,s) = -(g(x,s) Moreover
1
R
+g(x,O) -tg(x,O)
s 20 s
so.
(1.2)
(2.6) Furthermore
B is coercive
for all A < A,. In fact
the existence of a solution can be obtained using the following version of the theorem of [ 141. Let B : Wa+‘(S2) -+W-m~p’(Q) (1 < p < x, (l/p) + (l/p’) = 1, m 2 1) be uniformly elliptic function satisfying (2.4), linear operator of order 2m and g(x, t) : Q X F! -+ R, a Carathkodory (2.5), (2.6) and fE W-m3p’(S2). Then there exists u lWy.P(i2) such that g(. , u), ug(., u) E L1(S2) and
Therefore
W, u) +
1g( . , u>u= If-u
for all u EW$P(Q) n L”(Q) and for u = U. (See also [6] in the case of an operator of second order and [5] in the case where
q(x) = 0.)
‘% uo a~erugsa
ue uy$qo
11:~
aM
MON ‘(~‘2) us SB lgds pue (1’~) liq pauyap
‘W:H i
3
an
(“n ‘x)X + Wg
0 =
.(On ‘Onov) = (“n ‘WV)
‘%uo.Ils (ig)r 7
u!
Bu0.w (b)r7
e siyxa
uq
(On ‘ . )JOn t
(“n ‘ . )pn
(On ‘.)Jt
(“n ‘.)S
u!
‘(d&w
(Z’E)
3 On
r (On ‘x)J = OnOv 30 uoynlos r2 ‘On 01 sa%awo:, iCIy2aM ygy~ ‘~3~ (“n) icq palouap u@e ‘aDuanbasqns alayi ‘(I ‘5) uralqold ayl30 suogn[os 30 333( %) axranbas yxa .103 ‘0~ t3 v pue 0~
30 anpzAua2!a
1s.y aqi ST ;y a.IayM ‘;y> y 103 (2.1) ‘(1.1) suogdwnssE
ay] lapun
.%u!MoI~~~ ai.p aaold
‘k@H
(T’E)
i (“n
~33,~( s”v) awanbasqns
e s! alay
.awa%aAuoy)
I! aq g’“(“v)
‘E MI~~IO’~HJ,
01 s! alay urge Ino
3n
3
‘x)4 = “n’v
30 uoynlos B ‘% rapysuo3 sn ia7 ‘0~ 01 sa%aAuoD-3 s3v ~eq~ yns ‘MI UI 0~ lolelado ue pue ‘m 30 slowado 30 3sa(sv) aDuanbas yxa 10~ ‘z MSXOXHL
30 uo!iou
ayi say&
([L] ‘[ET] ‘[zT]) waloayi ‘VaM-W~H
a3uanbas
y (s ‘x)2 a.IayM
la7 ‘2 30 acwanbasqns
u! .Qv--s~Jv
%u~Mo~~o~ayL ‘(7.s)~-H
3 s
.(a ‘d ‘a) n = ,y UTslowtado 30 e ,g pue (0) n {N 3 U: (U/I) = 3) = 2 la?
NOI.LVZIN39Ot’IOH
‘E
Existence and homogenization
for semilinear elliptic equations with noncompact nonlinearity
By (3.4) we get
By (3.3), (2.9,
we get
and therefore Cl
I/~Ell~h(n) s -
d
= C2, YE E E.
We have also
(3.5) Then,
there
exists a subsequence,
again denoted
by (u,),~~
U&--‘ uo
in
u,+
a.e. in Q,
gl(.
u.
, u3
-+
gl(
by Lebesgue’s
We now prove
theorem,
uO such
that,
H& S2)-weak,
*, ~0)
a.e.
in
Q,
g2(.,u,)+g2(~,uo)a.e.inQ. It is clear,
and
(3.6) I
that
g2(.,G---,g2(.,u0)
in
L2(Q2>.
(3.7)
gd~,uJ-gl(.,u~)
in
L’(Q).
(3.8)
that
In fact, for each 6 > 0,
By (34, (U&E
(3.6) and Vitali’s theorem, we obtain is bounded in HA(Q), we have also
and so, for a subsequence,
Agu,-
x in H-l(Q)-weak.
A&u, - Au, = Aau, is also bounded
(3.8). Since A, E M, V’EE E and the sequence
in the space L’(Q). Apu,+
x
(gl( . >~3
By theorem in
H-1,4(Q)
+ gd . , ~3) 1 of [8], we get Vq < 2.
(3.9)
10
Then
D. GIACHETTI and M. RAMASWAMY
by lemma
14 of [4], x = Aouo,
(3.10)
lim inf (AEuE, u,) 2 (Aouo, u,,). By (3.7), (3.8) and (3.10), G E H:(Q) nL”(Q),
we can now pass to the limit in the following
equation,
for each
and get (3.11)
gz(~,uo,)@=o
(mono> 4) + ogl(~,u(,)@+ I
where B. denotes the operator AtI - J.. Let us call T = - Bou,, - gz(. , UO)= g,(. , u,,). We have T E H-‘(Q) a.e. for LQ)E HA(Q) and so by theorem 1 of [5], TUOE L’(Q) and
n L’(Q)
with Tzq, B 0
which gives, (Bouo, u,,) +
IR
g,( . . ~u)k +
IR
g2(
> uo)u,,
= 0.
(3.12)
By (3.11) and (3.12), (3.2) is proved. We now prove that (AA. u,S(. Obviously
it will be sufficient
kg(. n, = (BFuC, uJ, b, =
. ur) -
to prove @A.
Calling
u,) + (Ac,uo, u,,). uof( . . kl)
(3.13) in
L’(R).
in
L ‘( Q).
that
u,) + U&U,,. u,,). 3u,> -+ kg( . , 4)
g,(. . u,)u,, I 61
we have by (3.7), (3.12).
respectively, lim (a, + b,) = a,, + b,, r-0
lim inf b, 2 b,, E- 0 hence
it follows
that lim a, = a(), lim h, = b(,. E--r0 F-o
(3.10) and Fatou’s
lemma,
D. GIACHETTI
12
and
M.RAMASWAW
Now we want to point out an example in which we do not have almost everywhere convergence in x, for fixed t, of {f’} to f”, but still we can obtain the homogenization result. This example suggests that perhaps we can improve theorem 4, by weakening the hypothesis (iii). 5. Let f&(x, S) = aE(x)f(x,
THEOREM
s). We assume
that
a, are L” functions such that 0 < yl s uE G y2 < or,, in L”(Q)-weak *, at -a f(x, s) is a Caratheodory function satisfying (1.2) and the following condition: of Ao) with ( w h ere A: is the first eigenvalue r](x) E L*(n) and x <($/y~),
Then there exists a subsequence, converges to uo, a solution of
~(x,S)~As++(x)
sao,
f(x, s) 1 XF - i(x)
S G 0.
again denoted
by (uJEEE of solutions
there
exists
of (4. l), which weakly
Aouo = a!(~, uo), (4.2)
z&JE iY& Q).
1
Furthermore and
(A&u,, u,) + (AOUO,uo)
(4.3) In In order
to prove
aF(M.7
the theorem,
u,)u,+
we need the following
LEMMA. Let {ad and {he} be a sequence (i) 0 s yl s a, s y2 < ~0 and us-(ii) h, are L’ functions converging Then
JR
uo)uo. 1
a(.)&
of a.e. nonnegative
functions
such that
a in L”(B)-weak *. a.e. in Q to h E L’(Q).
we have liminf_/a,h,dxSjahdx.
Proof. Denoting
by xE, the characteristic aE(hE- h) dx = 2=
IR
function
of {x E Q : hE(x) G h(x)}, we have
aXhE - h)xE dx +
a@,-
udhc - h)(l - xc) dx
h>xE dx.
Since aE are bounded in L”(Q) and h F-+ h a.e. and -h(x) s (hF(x) - h(x)xE(x) c 0, by Lebesgue’s theorem, we can pass to the limit in the last relation and get the result. This reasoning is true even if {h,} are not uniformly bounded in L’(R). Then in that case the lim inf can be + m. Proof of theorem 5. The function u$ satisfies the condition of type (1.1) with A as y$t and r~ as yz~. Hence the existence of a solution for (4.1) follows from theorem 1.
12
D. GIACHETTI and M. RAMASIVAMY
Now we want to point out an example in which we do not have almost everywhere convergence in x, for fixed t, of {f’} to f”, but still we can obtain the homogenization result. This example suggests that perhaps we can improve theorem 4, by weakening the hypothesis (iii). THEOREM 5.
Let f&(x, s) = a,(x)~(x,
s). We assume
that
ae are L” functions such that 0 < y1 4 a, G y? < CTJ, in L”(R)-weak *, a, -a ’ d ory function satisfying (1.2) and the following condition: f(x, s) is a C ara th eo ( w h ere A:‘is the first eigenvalue of A,,) with q(x) E L’(Q) and 1 <(Avyz),
Then there exists a subsequence. converges to ug, a solution of
f(X,S)dAsS
i(x)
.f(x,.+&--_(x)
SGO. by (Up) FEN of solutions
again denoted
there
exists
sso,
of (4.1), which weakly
AOUO= @(x, UO). (4.2)
no E &A(Q).
I
Furthermore (AA,
u,) -+ MO+
and
~0)
(4.3) IR
aA.)f(.,
the theorem,
u&,+
In order
to prove
LEMMA.
Let {ad and {A,} be a sequence
we need the following
(i) 0 < yl G aF s y2 < m and up(ii) h, are L’ functions converging Then
Proof.
iR
a (.)A., UO)Q
of a.e. nonnegative
functions
such that
a in L”(R)-weak 1. a.e. in 52 to h E L’(Q).
we have
Denoting
by xF, the characteristic uE(hF - h) dx = 3
function
of {x E 8 : h,(x) G h(x)}, we have
aF(ht-- h)xE dx +
I a& R
aXhp - h)(l - xc) dw
- h>xFdx.
Since aE are bounded in L”(Q) and h, + h a.e. and -h(x) c (hF(x) - h(x)xF(x) c 0, by Lebesgue’s theorem, we can pass to the limit in the last relation and get the result. This reasoning is true even if {hF} are not uniformly bounded in L’(Q). Then in that case the lim inf can be + 0~. Proof of theorem 5. The function a$ satisfies the condition of type (1.1) with A as yzx and n as y2~. Hence the existence of a solution for (4.1) follows from theorem 1.
Existence
and homogenization
Now using the assumptions
for semilinear
elliptic
equations
with noncompact
nontmeariry
on f, we can split g(x,
sj = AS- f(x, S)
as in (2.4), g(x, s) = where
gl and g2 satisfy
(2.5).
We introduce
g& Then
(4.1) can be written
Denoting
g1(x,
by B, =A, - xy2, the above
some other
equation
+ %YZ - a,)~,
II& along
s G?
with
gz(x,
the functions
(1.2)
jR
+ g&4
g; and g’f as g2(x,
sb,.
obvious
splitting
+ g&4
= 0.
for 1~0)
(4.4)
2 0 and gh and g’, satisfy conditions
similar
gxu,> u, s C% *Rl(lldUF i C6. j
and the a.e.
convergence
gr(u,) 3 gl(u0)
in
-
44
of ~(uJ
to of
gives,
L’(Q).
Since (3.9) and (3.10) are true in this case also, using weak, *, we can pass to the limit in (B&LI,. @) + 2 j 4~2
s>,
is
The operator B, is again coercive and A( yz -a,) to (2.5). So from (4.4) we get as before,
The last estimate theorem 3,
+
s) = g,(x, S)UE,.6(x, s) =
as (for A 20;
By,
s>
as in
(4.5)
(4.5) and the fact that uF-
+ j&)4
= -
a in L”
jgi@J$
and get @GU, @) + 2 j 4~2 Now we can prove
as in theorem ,”
vh~o,
Moreover
UC,) +
by the previous
J
J
lemma
-
~14
+ j ag,(uo)@
3, using theorem r
uo(
y2 -
a>41
+
J
= -
j ag2(4@.
1 of [5], r ag,(uo)k
=
-
J
(4.6)
~g2(@4,.
and by (3.10)
ug,(uo)uo, ug,(u,)u, 3 I I lim inf (A,u,, u,) L (A+q,, u,,)
lim inf
respectively.
Combining
these with (4.6) (again
by the same arguments)
(4.3) follows.
5. REMARKS
1. We want to point out that the difficulty arises because f is not a compact since it does not even induce a map from L2 to L2 or from HA to H-‘.
perturbation,
14
D. GIACHETTI and M. RAMASWAMY
2. In [ll], the homogenization of the same type of equation was proved when fis Lipschitz in the second variable, using the maximum principle. 3. The present proof goes through for higher order operators also as we have not used any property characteristic of the second order operators. 4. A, can be taken to be nonsymmetric also. In that case we take Af, as the best coercivity constant, characterized by G = tlf$-$ Then
{A?}converges
to A: as in [3], defined
-,
by,
A’I= t”f$$ since the characterisation 5. If A,:A”,
is the same as that of the first eigenvalue
(s for “strong”
A,u+Aou
and it means
for all u EH&Q)),
strongly in H&Q), since A,5 A0 and by the theorem, (A&, u,) 6. In fact we have proved in theorem 3, also the homogenization AEuE + g(uJ
in the symmetric
(AwI,
case.
then
u,+
~0
~0).
result
for the equation,
= f.
u, E &(Q), where fE H-‘(Q), A, z A0 in M and g(x, t) satisfies Caratheodory function satisfying g(x,t)
=$3(x,4
the hypotheses
([9])
- Di(a~(X)DjUJ u,-
uo
xE+xO
I then there
exists a sequence
= xE, E E E U {O),
in
H&Q)-weak,
in
w -i,q, q < 2,
a$DiU,Dju,+
of matrices
I
aj:DiuoDjuo>
P, such that {Ps
grad U, = P,grad where r,+ 0 strongly in (L’(Q))%. The matrices P, are obtained
a.e. in Q, for all t E R and
for 0 < t < cQ.
Tup lg(x, s)i E L’(R) s result:
it is a
+gz(x,r)
such that gi(x, t)t B 0, jg2(x, t)I =Zh(x), h(x) E L*(Q),
7. Let us recall the following if
of [14], namely,
in the
following
are bounded
in L2(Q)“,
and
uo + r,
way:
for
a vector
h E [w”, we define
Existence
PJ
and homogenization
= grad wff, where
for semilinear
w$ is the solution
elliptic equations
with noncompact
nonlinearity
15
of
-Di(a&(x)Diw$J
= 1$1 DXa~{x) .Aj)
in
Q,
wj-A*xEH$Q). This result is in fact a definition of a “corrector” for grad uE, because we have replaced grad U, by the sum of two terms, one of which is P, grad ug, simple to calculate and the other is rs, going to 0 strongly. In the case where the a0 are given by a;(x) =aij(x/~) Ulj(y) Y-periodic for i, j = 1 . . . N. we can construct P, as follows:
where the functions xj The above result is (3.13), the hypotheses hence the existence of Acknowledgements-The
VAE [WN,VXE
51,
P,(x)
A;(grad,X,) (x/E)
= A -
$
are defined over Y as in [2]. a variant of the case q = 2 which is proved in [13], [9]. By (3.9) and of this theorem are satisfied in the case of theorem 3, 4 and 5 and correctors follows.
authors
want to thank
L. Boccardo
and F. Murat
for very useful discussions
REFERENCES 1. AMANN H., Nonlinear elliptic equations with nonlinear boundary conditions, in New Deuelopmenrs in Differentipl Equations (Edited by ECKHAUS) North-Holland, Amsterdam (1976). 2. BENSOUSSAN A.. LIONS J. L. & PAPANICOLAOU G., Asymptotic Analysis for Periodic Sfruc~ures. North-Holland. Amsterdam (1978). 3. BOCCARDO L. & MARCELLINI P.. Sulla convergenza delle soluzioni di disequazioni variazionali. Annali Mat. purer uppl. 110. 137-159 (1976). 4. BOCCARDO L. & MURAT F., Nouveaux rCsultats de convergence dans des problkmes unilatCraux, in Nonlineur Partial Differential Equations and Their Applications. Coil&e de France Seminar, Vol. II (Edited by H. BK~.ZIS & .I. L. LIONS) Research Notes in Mathematics. No 60. Pitman. London, pp. 64-85 (1982). 5. BREZIS H. & BROWDER F. E.. Some properties of higher order Sobolev spaces. J. math. pures appl.. to appear. 6. HESS P., Variational inequalities for strongly nonlinear elliptic operators, J. marh. pures uppl. 52, 285-298 (1973). 7. MURAT F.. H-convergence, SCminaire d’Analyse fonctionnelle et numCrique de I’Universite! d’AlgCrie (1977. 1978). 8. MURAT F., L’injection du cone positif de H-’ dans W-’ 4 est compacte pour tout 4 < 2. J. marh. pures uppl. 60. 309-322 (1981). 9. MURAT F., HomogCnCisation d’inCquations variationnelles avec contraintes unilatCrales. Seminaires 2 la Scuola Normale Superiore di Pisa, unpublished (November 1978). 10. NATANSON I. P., Theory of Functions of a Real Variable. F. Ungar. New York (1961). 11. RAMASWAMY M.. On a nonlinear elliptic equation with periodic coefficients, SIAM J. uppl. Mmh. 40. 409-418 (1981). 12. SPAGNOLO S., Sulla convergenza di equazioni paraboliche ed ellittiche. Annali Scu. norm sup. Piscl 22. 577-597 (1968). 13. TARTAR L.. Cours Peccot au ColEge de France (March, 1977). 14. WEBB J. R. L., Boundary value problems for strongly nonlinear elliptic equations, J. London math. Sot. 21. 123-132 (1980).
Methods
& Applicanons.
Vol. 8. No. 1. pp. 5-15,
0362-546X/84 $3 00 + .OO @ 1984 Pergamon Press Ltd.
1984.
EXISTENCE AND HOMOGENIZATION FOR SEMILINEAR ELLIPTIC EQUATIONS WITH NONCOMPACT NONLINEARITY * DANIELA GIACHETTI Istituto di Matematica, Facolta di Scienze, Universita di Salerno, 84100 Salerno, Italy and MYTHILY RAMASWAMY INRIA, Rocquencourt,
B.P. 105, 781.53 Le Chesnay, France and T.I.F.R. Centre, Bangalore, India (Received
Key words and phrases: Homogenization,
12 November 1982)
G-convergence
0. INTRODUCTION IN THIS paper
we consider
the problem
of the existence Au =f(x,
of a weak solution
for
u)
P>
u E a(Q), where A is a uniformly elliptic A less than the first eigenvalue
linear operator and f is a Caratheodory of A and for some q(x) E L2(Q), f(x,.s)
SZ-0,
f(x, s) 3 As - V(X)
s d 0.
function
such that for
Here we give a very simple existence proof, using a result of [14]. The existence of a classical solution using maximum principle when f is &-Holder continuous in the first variable and locally Lipschitz in the second variable, is proved in [l] and weak solution in [6]. Then we consider the problem of convergence of the solutions for AEuE =f(x,
u,) I
UEE HA(Q), to a solution
(PE)
of the problem Aou = f(x, u) u E HA(Q),
1
(PO)
G when A, are uniformly elliptic linear operators such that A E-+ AC,, in the sense of G-convergence [12], [13], introduced by Spagnolo. The difficulty lies in the fact that f is not a compact perturbation between L2(Q) and L2(Q), since indeed it does not induce any map from L2(Q) to L2(Q). In [ll], homogenization of equations of this type, if f is Lipschitz in the second variable, is treated using maximum principle. Here the convergence of the solutions to a * This work was carried out when the first author was in Paris VI, partially supported by C.N.R., Italia and the second was in INRIA under deputation from T.I.F.R., India. 5
D. GIACHETTI and M.
6
RAMASWAMY
solution of the homogenized problem PO is shown without any regularity assumptions. Since the proof, both in the case of existence and homogenization does not use any characteristic properties of second order operators, it works for higher order also. 1. ASSUMPTIONS
Let Q be a bounded operator in the class
domain
in RN with sufficiently
smooth
&I and let A be an
boundary
laij(X) 1s p, Xaij(X)EiEj 2 cUI&I’, E E RN a.e. in Q Uii=Uji,l~i~j~~,O
w
I and A1 be the first eigenvalue of the operator A. Let f: Q x IR -+ IF! be a Caratheodory function (measurable in x E Q for any t E R and continuous in t for almost every x E S2) satisfying the following condition: There exists n(x) E L2(Q) and A. < Al such that for almost all x E 52 f(x, s) G ?Ls+ q(x)
s 2 0
f(x, s) 2 As - V(X)
SGO
(1.1)
1
and ;ug If@, s) I E L’(Q), We will consider
0 s t < m.
(1.2)
I
(1.3)
the problem Au = f(x, u) 24E a(Q),
and look for a solution
in the following
u~Hb(Q),f(.,u) (Au.o)=l/(.>
sense: EL’(Q),f(.,u)u
u ) u f oreachu
EL’(Q) EH&Q)
and
nL”(Q)
for u = u where
(. , .) denotes
the duality
between
H&Q)
(1.4)
and i
and H-r(R).
2. EXISTENCE
We state the following. THEOREM
u EH~(Q),
1. Under the assumptions in the sense of (1.4).
Proof. The problem
(1.3) is equivalent
(1 .l),
to
(A-A)u=f(x,u)-hi u E H&2).
(1.2)
the
problem
(1.3)
has
a solution
Existence
Denoting
and homogenization
for semilinear
elliptic
equations
with noncompact
nonlinearity
by B = A - A, g(x, s) = h - f(x, s),
the problem
is Bu + g(x, u) = 0 I
u E ffh(Q), where
the function
g(x, S) satisfies g(x, s) signs
We note that each function
which satisfies
2 -q(x).
(2.3)
(2.3) can be written
as
g(x, s) = g1(x, s) + gz(x, s) where
gl (x, s) and gz(x, s) are CarathCodory
functions
(2.4)
such that
gl(x, s)s * 0, Jgz(x, s) 1S 217(x) for almost allx E Q] andforsE (note
that v 2 0 because
of -q(x)
6 f(x,
0) s q(x)).
s 20
-g(x,O))-
s ‘co
1
-(g(x.s)
g2(x7s) ={ (g(x,s) by the hypothesis
-g(x,O))_ -g&O))-
(2.5)
In fact we can take
(g(x,.$ -g(x,O))’
gl(x,s) = -(g(x,s) Moreover
1
R
+g(x,O) -tg(x,O)
s 20 s
so.
(1.2)
(2.6) Furthermore
B is coercive
for all A < A,. In fact
the existence of a solution can be obtained using the following version of the theorem of [ 141. Let B : Wa+‘(S2) -+W-m~p’(Q) (1 < p < x, (l/p) + (l/p’) = 1, m 2 1) be uniformly elliptic function satisfying (2.4), linear operator of order 2m and g(x, t) : Q X F! -+ R, a Carathkodory (2.5), (2.6) and fE W-m3p’(S2). Then there exists u lWy.P(i2) such that g(. , u), ug(., u) E L1(S2) and
Therefore
W, u) +
1g( . , u>u= If-u
for all u EW$P(Q) n L”(Q) and for u = U. (See also [6] in the case of an operator of second order and [5] in the case where
q(x) = 0.)
‘% uo a~erugsa
ue uy$qo
11:~
aM
MON ‘(~‘2) us SB lgds pue (1’~) liq pauyap
‘W:H i
3
an
(“n ‘x)X + Wg
0 =
.(On ‘Onov) = (“n ‘WV)
‘%uo.Ils (ig)r 7
u!
Bu0.w (b)r7
e siyxa
uq
(On ‘ . )JOn t
(“n ‘ . )pn
(On ‘.)Jt
(“n ‘.)S
u!
‘(d&w
(Z’E)
3 On
r (On ‘x)J = OnOv 30 uoynlos r2 ‘On 01 sa%awo:, iCIy2aM ygy~ ‘~3~ (“n) icq palouap u@e ‘aDuanbasqns alayi ‘(I ‘5) uralqold ayl30 suogn[os 30 333( %) axranbas yxa .103 ‘0~ t3 v pue 0~
30 anpzAua2!a
1s.y aqi ST ;y a.IayM ‘;y> y 103 (2.1) ‘(1.1) suogdwnssE
ay] lapun
.%u!MoI~~~ ai.p aaold
‘k@H
(T’E)
i (“n
~33,~( s”v) awanbasqns
e s! alay
.awa%aAuoy)
I! aq g’“(“v)
‘E MI~~IO’~HJ,
01 s! alay urge Ino
3n
3
‘x)4 = “n’v
30 uoynlos B ‘% rapysuo3 sn ia7 ‘0~ 01 sa%aAuoD-3 s3v ~eq~ yns ‘MI UI 0~ lolelado ue pue ‘m 30 slowado 30 3sa(sv) aDuanbas yxa 10~ ‘z MSXOXHL
30 uo!iou
ayi say&
([L] ‘[ET] ‘[zT]) waloayi ‘VaM-W~H
a3uanbas
y (s ‘x)2 a.IayM
la7 ‘2 30 acwanbasqns
u! .Qv--s~Jv
%u~Mo~~o~ayL ‘(7.s)~-H
3 s
.(a ‘d ‘a) n = ,y UTslowtado 30 e ,g pue (0) n {N 3 U: (U/I) = 3) = 2 la?
NOI.LVZIN39Ot’IOH
‘E
Existence and homogenization
for semilinear elliptic equations with noncompact nonlinearity
By (3.4) we get
By (3.3), (2.9,
we get
and therefore Cl
I/~Ell~h(n) s -
d
= C2, YE E E.
We have also
(3.5) Then,
there
exists a subsequence,
again denoted
by (u,),~~
U&--‘ uo
in
u,+
a.e. in Q,
gl(.
u.
, u3
-+
gl(
by Lebesgue’s
We now prove
theorem,
uO such
that,
H& S2)-weak,
*, ~0)
a.e.
in
Q,
g2(.,u,)+g2(~,uo)a.e.inQ. It is clear,
and
(3.6) I
that
g2(.,G---,g2(.,u0)
in
L2(Q2>.
(3.7)
gd~,uJ-gl(.,u~)
in
L’(Q).
(3.8)
that
In fact, for each 6 > 0,
By (34, (U&E
(3.6) and Vitali’s theorem, we obtain is bounded in HA(Q), we have also
and so, for a subsequence,
Agu,-
x in H-l(Q)-weak.
A&u, - Au, = Aau, is also bounded
(3.8). Since A, E M, V’EE E and the sequence
in the space L’(Q). Apu,+
x
(gl( . >~3
By theorem in
H-1,4(Q)
+ gd . , ~3) 1 of [8], we get Vq < 2.
(3.9)
10
Then
D. GIACHETTI and M. RAMASWAMY
by lemma
14 of [4], x = Aouo,
(3.10)
lim inf (AEuE, u,) 2 (Aouo, u,,). By (3.7), (3.8) and (3.10), G E H:(Q) nL”(Q),
we can now pass to the limit in the following
equation,
for each
and get (3.11)
gz(~,uo,)@=o
(mono> 4) + ogl(~,u(,)@+ I
where B. denotes the operator AtI - J.. Let us call T = - Bou,, - gz(. , UO)= g,(. , u,,). We have T E H-‘(Q) a.e. for LQ)E HA(Q) and so by theorem 1 of [5], TUOE L’(Q) and
n L’(Q)
with Tzq, B 0
which gives, (Bouo, u,,) +
IR
g,( . . ~u)k +
IR
g2(
> uo)u,,
= 0.
(3.12)
By (3.11) and (3.12), (3.2) is proved. We now prove that (AA. u,S(. Obviously
it will be sufficient
kg(. n, = (BFuC, uJ, b, =
. ur) -
to prove @A.
Calling
u,) + (Ac,uo, u,,). uof( . . kl)
(3.13) in
L’(R).
in
L ‘( Q).
that
u,) + U&U,,. u,,). 3u,> -+ kg( . , 4)
g,(. . u,)u,, I 61
we have by (3.7), (3.12).
respectively, lim (a, + b,) = a,, + b,, r-0
lim inf b, 2 b,, E- 0 hence
it follows
that lim a, = a(), lim h, = b(,. E--r0 F-o
(3.10) and Fatou’s
lemma,
D. GIACHETTI
12
and
M.RAMASWAW
Now we want to point out an example in which we do not have almost everywhere convergence in x, for fixed t, of {f’} to f”, but still we can obtain the homogenization result. This example suggests that perhaps we can improve theorem 4, by weakening the hypothesis (iii). 5. Let f&(x, S) = aE(x)f(x,
THEOREM
s). We assume
that
a, are L” functions such that 0 < yl s uE G y2 < or,, in L”(Q)-weak *, at -a f(x, s) is a Caratheodory function satisfying (1.2) and the following condition: of Ao) with ( w h ere A: is the first eigenvalue r](x) E L*(n) and x <($/y~),
Then there exists a subsequence, converges to uo, a solution of
~(x,S)~As++(x)
sao,
f(x, s) 1 XF - i(x)
S G 0.
again denoted
by (uJEEE of solutions
there
exists
of (4. l), which weakly
Aouo = a!(~, uo), (4.2)
z&JE iY& Q).
1
Furthermore and
(A&u,, u,) + (AOUO,uo)
(4.3) In In order
to prove
aF(M.7
the theorem,
u,)u,+
we need the following
LEMMA. Let {ad and {he} be a sequence (i) 0 s yl s a, s y2 < ~0 and us-(ii) h, are L’ functions converging Then
JR
uo)uo. 1
a(.)&
of a.e. nonnegative
functions
such that
a in L”(B)-weak *. a.e. in Q to h E L’(Q).
we have liminf_/a,h,dxSjahdx.
Proof. Denoting
by xE, the characteristic aE(hE- h) dx = 2=
IR
function
of {x E Q : hE(x) G h(x)}, we have
aXhE - h)xE dx +
a@,-
udhc - h)(l - xc) dx
h>xE dx.
Since aE are bounded in L”(Q) and h F-+ h a.e. and -h(x) s (hF(x) - h(x)xE(x) c 0, by Lebesgue’s theorem, we can pass to the limit in the last relation and get the result. This reasoning is true even if {h,} are not uniformly bounded in L’(R). Then in that case the lim inf can be + m. Proof of theorem 5. The function u$ satisfies the condition of type (1.1) with A as y$t and r~ as yz~. Hence the existence of a solution for (4.1) follows from theorem 1.
12
D. GIACHETTI and M. RAMASIVAMY
Now we want to point out an example in which we do not have almost everywhere convergence in x, for fixed t, of {f’} to f”, but still we can obtain the homogenization result. This example suggests that perhaps we can improve theorem 4, by weakening the hypothesis (iii). THEOREM 5.
Let f&(x, s) = a,(x)~(x,
s). We assume
that
ae are L” functions such that 0 < y1 4 a, G y? < CTJ, in L”(R)-weak *, a, -a ’ d ory function satisfying (1.2) and the following condition: f(x, s) is a C ara th eo ( w h ere A:‘is the first eigenvalue of A,,) with q(x) E L’(Q) and 1 <(Avyz),
Then there exists a subsequence. converges to ug, a solution of
f(X,S)dAsS
i(x)
.f(x,.+&--_(x)
SGO. by (Up) FEN of solutions
again denoted
there
exists
sso,
of (4.1), which weakly
AOUO= @(x, UO). (4.2)
no E &A(Q).
I
Furthermore (AA,
u,) -+ MO+
and
~0)
(4.3) IR
aA.)f(.,
the theorem,
u&,+
In order
to prove
LEMMA.
Let {ad and {A,} be a sequence
we need the following
(i) 0 < yl G aF s y2 < m and up(ii) h, are L’ functions converging Then
Proof.
iR
a (.)A., UO)Q
of a.e. nonnegative
functions
such that
a in L”(R)-weak 1. a.e. in 52 to h E L’(Q).
we have
Denoting
by xF, the characteristic uE(hF - h) dx = 3
function
of {x E 8 : h,(x) G h(x)}, we have
aF(ht-- h)xE dx +
I a& R
aXhp - h)(l - xc) dw
- h>xFdx.
Since aE are bounded in L”(Q) and h, + h a.e. and -h(x) c (hF(x) - h(x)xF(x) c 0, by Lebesgue’s theorem, we can pass to the limit in the last relation and get the result. This reasoning is true even if {hF} are not uniformly bounded in L’(Q). Then in that case the lim inf can be + 0~. Proof of theorem 5. The function a$ satisfies the condition of type (1.1) with A as yzx and n as y2~. Hence the existence of a solution for (4.1) follows from theorem 1.
Existence
and homogenization
Now using the assumptions
for semilinear
elliptic
equations
with noncompact
nontmeariry
on f, we can split g(x,
sj = AS- f(x, S)
as in (2.4), g(x, s) = where
gl and g2 satisfy
(2.5).
We introduce
g& Then
(4.1) can be written
Denoting
g1(x,
by B, =A, - xy2, the above
some other
equation
+ %YZ - a,)~,
II& along
s G?
with
gz(x,
the functions
(1.2)
jR
+ g&4
g; and g’f as g2(x,
sb,.
obvious
splitting
+ g&4
= 0.
for 1~0)
(4.4)
2 0 and gh and g’, satisfy conditions
similar
gxu,> u, s C% *Rl(lldUF i C6. j
and the a.e.
convergence
gr(u,) 3 gl(u0)
in
-
44
of ~(uJ
to of
gives,
L’(Q).
Since (3.9) and (3.10) are true in this case also, using weak, *, we can pass to the limit in (B&LI,. @) + 2 j 4~2
s>,
is
The operator B, is again coercive and A( yz -a,) to (2.5). So from (4.4) we get as before,
The last estimate theorem 3,
+
s) = g,(x, S)UE,.6(x, s) =
as (for A 20;
By,
s>
as in
(4.5)
(4.5) and the fact that uF-
+ j&)4
= -
a in L”
jgi@J$
and get @GU, @) + 2 j 4~2 Now we can prove
as in theorem ,”
vh~o,
Moreover
UC,) +
by the previous
J
J
lemma
-
~14
+ j ag,(uo)@
3, using theorem r
uo(
y2 -
a>41
+
J
= -
j ag2(4@.
1 of [5], r ag,(uo)k
=
-
J
(4.6)
~g2(@4,.
and by (3.10)
ug,(uo)uo, ug,(u,)u, 3 I I lim inf (A,u,, u,) L (A+q,, u,,)
lim inf
respectively.
Combining
these with (4.6) (again
by the same arguments)
(4.3) follows.
5. REMARKS
1. We want to point out that the difficulty arises because f is not a compact since it does not even induce a map from L2 to L2 or from HA to H-‘.
perturbation,
14
D. GIACHETTI and M. RAMASWAMY
2. In [ll], the homogenization of the same type of equation was proved when fis Lipschitz in the second variable, using the maximum principle. 3. The present proof goes through for higher order operators also as we have not used any property characteristic of the second order operators. 4. A, can be taken to be nonsymmetric also. In that case we take Af, as the best coercivity constant, characterized by G = tlf$-$ Then
{A?}converges
to A: as in [3], defined
-,
by,
A’I= t”f$$ since the characterisation 5. If A,:A”,
is the same as that of the first eigenvalue
(s for “strong”
A,u+Aou
and it means
for all u EH&Q)),
strongly in H&Q), since A,5 A0 and by the theorem, (A&, u,) 6. In fact we have proved in theorem 3, also the homogenization AEuE + g(uJ
in the symmetric
(AwI,
case.
then
u,+
~0
~0).
result
for the equation,
= f.
u, E &(Q), where fE H-‘(Q), A, z A0 in M and g(x, t) satisfies Caratheodory function satisfying g(x,t)
=$3(x,4
the hypotheses
([9])
- Di(a~(X)DjUJ u,-
uo
xE+xO
I then there
exists a sequence
= xE, E E E U {O),
in
H&Q)-weak,
in
w -i,q, q < 2,
a$DiU,Dju,+
of matrices
I
aj:DiuoDjuo>
P, such that {Ps
grad U, = P,grad where r,+ 0 strongly in (L’(Q))%. The matrices P, are obtained
a.e. in Q, for all t E R and
for 0 < t < cQ.
Tup lg(x, s)i E L’(R) s result:
it is a
+gz(x,r)
such that gi(x, t)t B 0, jg2(x, t)I =Zh(x), h(x) E L*(Q),
7. Let us recall the following if
of [14], namely,
in the
following
are bounded
in L2(Q)“,
and
uo + r,
way:
for
a vector
h E [w”, we define
Existence
PJ
and homogenization
= grad wff, where
for semilinear
w$ is the solution
elliptic equations
with noncompact
nonlinearity
15
of
-Di(a&(x)Diw$J
= 1$1 DXa~{x) .Aj)
in
Q,
wj-A*xEH$Q). This result is in fact a definition of a “corrector” for grad uE, because we have replaced grad U, by the sum of two terms, one of which is P, grad ug, simple to calculate and the other is rs, going to 0 strongly. In the case where the a0 are given by a;(x) =aij(x/~) Ulj(y) Y-periodic for i, j = 1 . . . N. we can construct P, as follows:
where the functions xj The above result is (3.13), the hypotheses hence the existence of Acknowledgements-The
VAE [WN,VXE
51,
P,(x)
A;(grad,X,) (x/E)
= A -
$
are defined over Y as in [2]. a variant of the case q = 2 which is proved in [13], [9]. By (3.9) and of this theorem are satisfied in the case of theorem 3, 4 and 5 and correctors follows.
authors
want to thank
L. Boccardo
and F. Murat
for very useful discussions
REFERENCES 1. AMANN H., Nonlinear elliptic equations with nonlinear boundary conditions, in New Deuelopmenrs in Differentipl Equations (Edited by ECKHAUS) North-Holland, Amsterdam (1976). 2. BENSOUSSAN A.. LIONS J. L. & PAPANICOLAOU G., Asymptotic Analysis for Periodic Sfruc~ures. North-Holland. Amsterdam (1978). 3. BOCCARDO L. & MARCELLINI P.. Sulla convergenza delle soluzioni di disequazioni variazionali. Annali Mat. purer uppl. 110. 137-159 (1976). 4. BOCCARDO L. & MURAT F., Nouveaux rCsultats de convergence dans des problkmes unilatCraux, in Nonlineur Partial Differential Equations and Their Applications. Coil&e de France Seminar, Vol. II (Edited by H. BK~.ZIS & .I. L. LIONS) Research Notes in Mathematics. No 60. Pitman. London, pp. 64-85 (1982). 5. BREZIS H. & BROWDER F. E.. Some properties of higher order Sobolev spaces. J. math. pures appl.. to appear. 6. HESS P., Variational inequalities for strongly nonlinear elliptic operators, J. marh. pures uppl. 52, 285-298 (1973). 7. MURAT F.. H-convergence, SCminaire d’Analyse fonctionnelle et numCrique de I’Universite! d’AlgCrie (1977. 1978). 8. MURAT F., L’injection du cone positif de H-’ dans W-’ 4 est compacte pour tout 4 < 2. J. marh. pures uppl. 60. 309-322 (1981). 9. MURAT F., HomogCnCisation d’inCquations variationnelles avec contraintes unilatCrales. Seminaires 2 la Scuola Normale Superiore di Pisa, unpublished (November 1978). 10. NATANSON I. P., Theory of Functions of a Real Variable. F. Ungar. New York (1961). 11. RAMASWAMY M.. On a nonlinear elliptic equation with periodic coefficients, SIAM J. uppl. Mmh. 40. 409-418 (1981). 12. SPAGNOLO S., Sulla convergenza di equazioni paraboliche ed ellittiche. Annali Scu. norm sup. Piscl 22. 577-597 (1968). 13. TARTAR L.. Cours Peccot au ColEge de France (March, 1977). 14. WEBB J. R. L., Boundary value problems for strongly nonlinear elliptic equations, J. London math. Sot. 21. 123-132 (1980).