1) if p>2 + a, the problem (Ll)-(1.3) has global (nonnegative) solutions whenever initial functions UQ(X) (are nonnegative and) belong to some Sobolev space.
Publ. RIMS, Kyoto Univ. 8 (1972/73), 211-229
Existence and Nonexistence of Global Solutions for Nonlinear Parabolic Equations By
Masayoshi TSUTSUMI*
1.
Introduction
Let @ be a bounded domain in Rn with smooth boundary 9J2, p a real number 2>2
and a a nonnegative real number.
In this paper we
consider the initial-boundary value problems of the form
* dt -= z
du
Q f\ du p-z du ~dx~i
(1.2)
u(x, 0) =
(1.3)
u(x,t) = Q In a recent work pQ, Fujita gave existence and nonexistence theo-
rems for global solutions of the equation
^=Au + ul+a, t>Q,Xeti,
(1.4)
with conditions (1.2), (1.3). In this paper our purpose is to obtain analogous results for the problem (1. !)-(!. 3).1) 1)
Roughly speaking, our results are as follows:
if p>2 + a, the problem (Ll)-(1.3) has global (nonnegative)
solutions whenever initial functions UQ(X) (are nonnegative and) belong to some Sobolev space. Received May 8, 1972. Communicated by S. Matsuura. * Department of Applied Physics, Waseda University., Tokyo, Japan. 1) This problem was proposed by Lions in his book [2],
212
MASAYOSHI TSUTSUMI
2) if p we have
(2.3)
H
where 1^q^np/(n—p)
if n>p and l^g2 + «
Theorem 1. Suppose that u^x}^. W\tp(Q\ p>2 + a.
Then there
exists a function u(x, t) such that (3.1)
ueL~(Q, T;
(3.2) and which satisfies (l.l7) in a generalized sense. If raQ and is a solution of the problem (1. !)-(!. 3).
an
y
EXISTENCE AND NONEXISTENGE OF GLOBAL SOLUTION
217
Remark 3. After eventual modification on a set of measure zero u is continuous from [J), r]-»L2(J2). Proof of Theorem 1.
Put p-2
dv
dv doc
We easily see that A is a strictly monotone hemicontinuous bounded and coercive operator from Wl'p(Q)-+ W~l'pl(p~l\Q). We shall employ the Galerkin's method. Let {«;,-},•= 1,2,... be a complete system of functions in Wl'p(@\ We look for an approximate solution um(x, t) in the form
(3.3)
Um(t)=
Jc gim(t}wi9
e cl(To, r])
gim(t)
where the unknown functions gim are determined by the following system of ordinary differential equations: (3.4)
«(0,
Wj) + a(um(t\ Wj) = (v(um(t)\ wj), l^j^m^
with initial condition (3.5)
M w (0)=H 0 m, uQm=^aimtUi -
>u0 in W
i=l
strongly as TTI->OO. Here
(u y( ^ ' v}= ' i=i)i
p 2
~ du
dv
a:*;. 7
Then we obtain the following a priori estimates: (3.6)
IkmlU^o.r^J^u))^ c,
(3-7)
IKiU 2 (0,
2) For the sake of simplicity, by the symbol ' we denote the differentiation with respect to t.
218
MASAYOSHI TSUTSUMI
where c is a constant independent of m,^ Indeed, multiplying the i-th equation in (3.4) by gfimJ summing over i from 1 to m and integrating with respect to £, we get
0.8)
.co 1
»
-2^rJ
Using Lemma 2 and Young's inequality, we have
d i=l
w
( *=iE =
2p \i=
from which it follows that 5-c
and
L «=i
d
P
0 3 (4.3)
lk(OIU'(Q)^lk(*)IU-(Q)
if
t^
If 7&Q a.e. in £, the solution u(x, £)2SO a.e. in £ for any fixed £>0, hence u(x, t) is a solution of the problem (1. !)-(!. 3). Proof. The Galerkin's method is again employed. Let {w,-}«-=i,2 ••• and an approximate solution um be the same as those stated in the proof of Theorem 1. Let {u0m} be a sequence such that (4.4)
u0meif, u0m=XaimWi f=i
>UQ in r strongly as TTI
> oo.
We have local existence of um(t) i-e. in f^O, ^J5 tm>Q and in this interval (c.f. (3.8)): (4.5)
We will show that
(4.6) Suppose that (4.6) does not hold and let t* be the smallest time for which ww(z*)$^*. Then in virtue of the continuity of um(t) we see that um(t*)£dW. (4.7)
Hence, from Lemma 4 we have J(um(t*»=d
or (4.8)
a(um(t*)) — b(um(t*)) = 0
EXISTENCE AND NONEXISTENCE OF GLOBAL SOLUTION
223
which contradicts the equality (4.5) and the fact that the initial function u0m is contained in ^.
Indeed, when (4.7) holds, the assertion is obvious
and when (4.8) holds, we have T(um(tff*»J(u ))which also implies the contradiction. Then from the equality (4.5) and Lemma 4, we get (4.9)
which implies (4.10)
and
From Aubin's compactness theorem and well known arguments of the theory of monotone operators, we see that there exist a function u and a subsequence {u^} of {um} such that (3.9)-(3.13) are fulfilled and u is a solution of the equation (1.1') with conditions (1.2), (1.3). We now prove (4.3). Since u is contained in ^ from Lemma 4, we see that (4.12)
a(u(0)- 6(^(0)^0.
On the other hand, setting i/r(s) =u(s)
in (3.17) with some modifications,
we easily obtain u (4.13) -k tolli'( fl ) = -|-|k(*)lli'u»fJsa(« Z Z
Hence, the inequality (4.3) immediately follows from (4.12) and (4.13). Proofs of the last two assertions of Theorem 2 are easily obtained by a repetition of the arguments in the proof of Theorem 1. Remark 6. When n0. Then from (5.2) and (5.3) we have (5.16)
—0(zj(£)) — -— 6(a(i))0.
Substituting (5.16) into (5.1) we get (5.17)
1 2 -^||w(£)IL (0)2S((1—
0
P \(l b(u(s))ds + —-\\u 1 \\2 2 , _ )\ 0 L (s)
=
(mes
W)"" 72 ''"^!!^) ds
Here we have used the inequality
From (5.17) we immediately obtain (5.18) where
Hence ||zi(*)IU' ( 0) diverges to +^ dicts that u is a global solution.
as *->^-||M 0 |L?tfl)< T.
This contra-
Thus we have the theorem.
228
MASAYOSHI TSUTSUMI
Remark 7. When p=2, local existence theorem of the classical solutions of the problem (1.1)-(1.3) is of course established without any restrictions upon the growth order a (see Friedman pT|). Theorem 4 gives another approach to "blowing up" of the solution of the equation (1.4) with conditions (1.2), (1.3). Remark 8. If we add the term Au to the second members of the equation (1.1), for smooth initial data, the problem (1.!)-(!.3) has a classical unique solution which may local in £, without any restrictions upon the growth orders p and a (see Sobolevskii (JTJ). Then by the analogous method to that stated in Theorem 4, we can prove the solution blowing up in a finite time if the initial condition satisfies the assumptions stated in Theorem 4.
6.
Final Remarks
In this section, as compared with the equation (1.1), we consider the following equation
9 f\ du »- 2 du \
dt
I
1=1 dx_
l+a
LI
,
fc/U,
Q
.a/tlw/iS,
with conditions (1.2) and (1.3). Then by the analogous methods to those stated in §3, we can easily obtain: Theorem 5. Let 2
