Elliptic & Parabolic Equations

Preliminary

Knowledge

15

then (ft is called the weak derivative of u with respect to the variable a^, denoted by du a axi

=9i

'

or DiU = gi. If for any i = 1,2, • • • , n, u has weak derivative <7J with respect to Xi, then we call g = (gi, • • • ,gn) the weak gradient of u, denoted by Vu = g or £>u = p, and u is said to be weakly differentiate, denoted by u £ W 1 (fi). Similarly we may define weak derivatives and weak differentiability of higher order. If u is weakly differentiate up to k order, then we denote u £ Wk(tl). 1.3.2

Sobolev spaces W fe 'P(ft) and W 0 fe,p (ft)

Definition 1.3.2 functions

Let k be a nonnegative integer, p > 1. The family of

{u £ Wk(n); Dau £ LP{Q), for any a with \a\ < k] endowed with the norm IMIiv*.-(n)= ( /

\Dau\pdx\

£

n

V H<*

(1-3.1)

/

kp

is called a Sobolev space, denoted by W ' (Cl). It can be proved easily that for p > 1, Wk'p(Q) is a Banach space. We always denote Wk'2(Q.) by Hk(Q), which is a Hilbert space with the inner product («.v)ff*(n) = / Definition 1.3.3

H

Dau-Davdx,

u,v £ Hk(Sl).

W%,p(ft) denotes the closure of Cg°(fi) in

Wk'p(£l).

Proposition 1.3.1 Wk>p(Rn) = W0fc'p(Rn), W°'p{Sl) = W°' p (^) = L p (fi). However, for the bounded domain 0, and k > 1, W0'P(Q) is a proper subset ofWk'p(Q). Proposition 1.3.2

C°°(ft) D Wk'p{n) is dense in Wk>p{Q).

This proposition means that Wk'p{n) is the completion of C°°(ft) with the norm (1.3.1).

16

Elliptic and Parabolic

Equations

It is to be noted that, in general, we can not replace C°°(fi) by C°°(Q) in Proposition 1.3.2. However for a large number of domains Q. including those having Lipschitz continuous boundaries, it is certainly the case. Definition 1.3.4 A domain Cl is said to have the property of segment, if there exist a finite open cover {C/j} of dd and corresponding nonzero vectors {y1}, such that for any x G Q, f~l U% and t G (0,1), we have x + tyi e $1 Proposition 1.3.3 / / the domain CI has the property of segment, then C°°(fi) is dense in Wk'p{Q). For the proof of Proposition 1.3.2 and Proposition 1.3.3 see [Gilbarg and Trudinger (1977)] Chapter 7 and [Adams (1975)] Chapter 3. Proposition 1.3.4 Ifl
=0

uniformly in f € X; Hi) There holds lim

/

\f(x)\pdx

=0

uniformly in f S X. For the proof see [Adams (1975)] Chapter 2. We note that iii) is satisfied automatically if Cl is bounded. As corollaries of Proposition 1.3.4 and Proposition 1.3.5, we have Proposition 1.3.6 For 1 < p < +oo, a subset ofWk'p(Q) weakly compact if and only if it is bounded in Wk'p(Q).

is (relatively)

Proposition 1.3.7 Let Q, C R n be bounded and 1 < p < +oo. / / the subset X of Lp(£l) is bounded in Wk+1'P(Q), then X is (relatively) strongly compact in Wk,p(Q).

Preliminary

17

Knowledge

Here we merely present a sufficient condition for a subset of Wk+1'P(Q) to be (relatively) strongly compact in the case of bounded domain fi, which is enough for our later usage. 1.3.3

Operation

rules of weak

derivatives

Some operation rules in calculus can be extended to weak derivatives by the approximation theorem(Proposition 1.1.1). P r o p o s i t i o n 1.3.8

Let u, v G H ^ f i ) . Then

d(uv)

dv

du

OXi

OXi

OXi

Proposition 1.3.9 Let Q,D be domains ofRn, u(x) G W1^) and $ = ($i, • • • , $„) : D —> f2 be a continuously differential mapping. Then du($(y)) d

Vk

_ ^

d$j

du

d

dXi'

JT[ Vk

k = 1

n

Proposition 1.3.10 Let f(s)be a continuous function on M with f'(s) piecewise continuous and bounded. Then u G W 1 (fi) implies f(u) £ W 1 (fi) and

a/(«) = f/'( w )^> dXi

\o,

t/uGL,

uViere L is £/ie se£ of jump points of 1.3.4

Interpolation

«/w^L-

f'(s).

inequality

Definition 1.3.5 A domain Q is said to have the property of uniform inner cone, if there is a finite cone V, such that every point x G ft is the vertex of a finite cone Vx C ft congruent with V. Theorem 1.3.1 (Ehrling-Nirenberg-Gagliardo's Interpolation Inequality) Let ft C Mn be a bounded domain having the property of uniform inner cone. Then for any e > 0, there exists a constant C > 0 depending only on p > 1, k, £ and ft, such that for any u G Wk,p(fl), f \D0u\pdx < e J2

Y^ \0\
Jn

f \Dau\pdx + C f

\a\=k

Jn

jQ

\u\pdx.

18

Elliptic and Parabolic

Equations

This inequality exposes such an important fact as that the IP norm of any intermediate derivative of functions in Wk'p(Q) can be estimated by the IP norm of the function itself and its derivatives of the highest order. We refer to [Adams (1975)] Chapter 4 for a detailed proof of this theorem. The basic idea can be shown by the following description for the special case k = 2, n = 1, 9, = (0,1), u € C 2 [0,1]. 1 2 Let 0 < £ < - , - < ? 7 < l . By the mean value theorem, we have |u'(A)| =

u{r)) - u{£) ri-Z

<3|u(0|+3|uft)|

for some constant A £ (£, rf). Hence for any x G (0,1), \u'{x)\ = i'(X)+

f u"{t)dt J\

<3|«(OI+3|«(»?)|+ / Jo

\u"{t)\dt.

Integrating this inequality with respect to £ over (0,1/3) and with respect to J] over (2/3,1) yields \\v!{x)\ 9

< [13\u(0\d£+

[ J2/3

Jo

< f \u{t)\dt + \ f Jo 9 Jo

Wrj)\dr,+ \9 f

\u"(t)\dt

Jo

\u"{t)\dt.

Using Holder's inequality we further obtain \u'(x)\p<2p-1-9p

[ \u(t)\pdt + 2p~1 [ Jo Jo

\u"{t)\pdt.

[ \u"{t)\pdt + Kp f Jo Jo

\u{t)\pdt,

Thus / \u'(t)\"dt
where Kp = 2P~1 • 9P. From this, by a change of variables, we are led to the following inequality for an interval (a, 6) I \u'{t)\pdt
f

\u"(t)\pdt

Ja

+ Kp(b-a)-p

f \u(t)\pdt. Ja

(1.3.2)

Preliminary

Knowledge

19

Let e € (0,1). Choose a positive integer N, such that 1, 2 1 (~ \KP/

!

VP

)

^

f£ '

i/p

UP

7 1 Let aj = j^(j = 0,1,--- ,N). Then Oj - Oj_i = —. Using (1.3.2) for (flj-i, flj) and summing on j from 1 to N, we arrive at N r1 rai \ \u'(t)\pdt = Y^ /

\u'(t)\pdt

j = l^a3-l

JO

^ p E J ^ r wwdt+w n \u(t)\pdt) <£ / |u"(i)| P rfi+ Jo 1.3.5

Embedding

£

£ / |lx(i)|P
theorem

Now we proceed to state the most important theorem in the theory of Sobolev spaces - embedding theorem, for its proof, the reader may refer to [Adams (1975)]. Theorem 1.3.2 (Isotropic Embedding Theorem) Let ft c bounded domain and 1 < p < +oo.

R" be a

i) If fi has the property of uniform inner cone, then, when p = n, Wl'p{£l) c Lq(Q), and for any u e

l
+oo,

Wl'p{£l),

IMUnn) < C(n,q,Q,)\\u\\wi,v(a),

l
+co;

when p < n, Wl'p{9)

c L«(n),

l < ? < p * = np n—p

and for any u € WX'P{£1), IMU«(fi) < C(«,P, n)||u|| w i, P ( n),

1 < ^ < p*

ii) If <9f2 is appropriately smooth, then, when p > n, W 1,p (ft) c Ca(U),

0 < a < l - - ,

20

Elliptic and Parabolic

and for any u €

Equations

W1,p(fl),

n 0 < a < l - - . V Here p* is the Sobolev conjugate exponent of p. The constant C in the above three inequalities is called embedding constant. \u\a;n <

Remark 1.3.1

C(n,p,Q)\\u\\wi,p(n),

The above embedding theorem can be expressed as ' L«(fi), Lq(fl),

W 1 ' p (fi)

= np n — p' 1 < q < +oo, l
Ca(n), Remark 1.3.2

p
0 < a < l - - , P

p> n.

The embedding

whp(n) «-> ca{U), means that one can change the value of any function of W 1,p (ft) on a set of measure zero so that it becomes a function in Ca(Cl). Applying Theorem 1.3.2 for k times repeatedly leads to Corollary 1.3.1 ' L«(fi), Wk'p(Q)

q

- < L (Cl),

e >

Ca(Ti),

np n — kp' 1 < q < +oo, 1< q<

0
kp < n, kp = n,

kp

kp>n.

Theorem 1.3.3 (Compact Embedding Theorem) Let il C W1 be a bounded domain and 1 < p < +oo. i) If Q, has the property of uniform inner cone, then the embedding Whp(£l) --» Lq(Sl) with l
and the embedding W1'"^)

«-» Lq(Q)

with 1 < q < +oo, p = n are compact. ii) If dQ, is appropriately smooth, then the embedding hp a

w (n)^c {ty

Preliminary Knowledge

21

ft

with p>n,

0
is compact. P Remark 1.3.3 The same embedding relation and compact embedding relations presented in Theorem 1.3.2 and Theorem 1.3.3 respectively hold for the spaces Wo'p(n). In this case, no more conditions on the domain are needed. Remark 1.3.4 An embedding is said to be compact, if any bounded sequence in the embedded space contains a subsequence which strongly converges in the embedding space, namely, the embedding operator is compact. 1.3.6

Poincare's

inequality

Theorem 1.3.4 Let 1 < p < +oo and Q C M.n be a bounded domain. i) Ifu£Wl
(1.3.3)

I \u- un\pdx
(1.3.4)

un=

mLu{x)dx

and |f2| is the measure ofQ. Proof. We first prove (1.3.3). Since Cg°(fi) is dense in Definition 1.3.3), it suffices to prove (1.3.3) for u € Cg°(fi). Choose a cube Q - {x€Rn;ai<Xi


WQ'P{Q)

(see

,n},

to contain fi where d = diamfi and define u = 0 outside Q. Then u £ Co°(Q) and for any x £ Q, \u(x)\p = /

Diu(s,x2,--

• ,xn)ds

Jai 1-a.i+d

(£

< I /

\

\Diu(s,x2,---

,xn)\ds

P

22

Elliptic and Parabolic

<
Equations

,xn)\pds.

\D1u(s,x2,---

Integrating over Q leads to f \u(x)\pdx = [ \u{x)\pdx Jn JQ r


rai+d

/

|Diu(s ,X2, • • •

,xn)\pdsdx

JQ Jax p


\ |Diu(xi,i2.-"

,xn)\pdx

JQ p


f

\Du\pdx,

JQ

which is just (1.3.3) with C = dp. For simplicity, we merely prove (1.3.4) for p > 1; for the proof in the case p = 1, we refer to [Maz'ja (1985)]. Since (1.3.4) is unvarying with u replaced by u plus any constant, without loss of generality, we may assume that UQ = 0. Suppose (1.3.4) failed, namely, for any positive integer k > 1, there would exists Uk £ W1'p(Cl), such that / Uk(x)dx = 0, but Jn f \uk\pdx >k [ \Duk\pdx. Jn Jn Set wk{x) =

llufc||LP(n)

xeii

(fe = i,2,---)-

Then wk G W 1,p (fi) satisfies / Wk(x)dx = 0 Jn IkfclUp(n) = 1

(fc = l , 2 , - - - ) ,

(1.3.5)

(fc = l,2,---)

(1.3.6)

and

J \Dwk\pdx < i

(fc = l , 2 , - - - ) .

(1.3.7)

(1.3.6) and (1.3.7) imply the boundedness of ||i«fc||wi.j>(fi)- Thus by the weak compactness of the bounded set in W 1,p (fi) and the compact embedding

Preliminary

23

Knowledge

theorem, we may assert the existence of a subsequence of {wk}, assumed to be {wk} itself, and a function w G W 1 , p (fi), such that wk — w Dwk^Dw

{k-^oo)

in LP{Q),

(1.3.8)

(fc-+oo)

inLp(Q,Rn).

(1.3.9)

Here —*• denotes the weak convergence. (1.3.7), (1.3.9) imply w(x) = const,

a.e. x G Cl,

and (1.3.5), (1.3.8) imply / w(x)dx = 0. Thus w(x) = 0,

a.e. l e t l .

(1.3.10)

However, (1.3.6), (1.3.8) imply ||w|U"(n) = 1 which contradicts (1.3.10). • Corollary 1.3.2 Let BR be a ball of radius R in R™. i) Ifue WQ'P(BR), 1 < p < +oo, then \u\pdx < C(n,p)Rp

f JBR

ii) Ifu& Wl
\Du\pdx.

f JBR

l
+oo, then

\u-uR\pdx
\Du\pdx,

I

JBR

JBR

where UR

=

u{x)dx

\k L 'BR

Proof. By rescaling, i.e. letting y = x/R, we are led to an inequality on Bi, which can be proved easily by Theorem 1.3.4. • Remark 1.3.5 From the embedding theorem we see that if 1 < p < n, then the exponent p on the left side of the inequalities in Theorem 1.3.4 can TIT) be replaced by any q such that 1 < q < p* = , namely, n —p i)Ifu£ WQ'P{Q), \
< C{n,p, il)(f

\Du\pdx\

;

24

Elliptic and Parabolic

Equations

ii) IfdQ. is locally Lipschitz continuous andu G W1,p(£l) with 1 < p < n, then for any 1 < q < p*, ([\u-uu\qdx) Remark 1.3.6


\Du\pdx\

".

Similarly the exponent p on the left side of the inequalities 717)

in Corollary 1.3.2 can be replaced by any q such that 1 < q < p* = n — p namely, we have i)Ifue WQ'P(BR), \

\u\"dx) W1'P(BR),

\JBR

P

;

1 < p < n, then for any 1 < q < p*,

\u-uR\qdx]

(I

\Du\pdx\


f \JBR

\Du\pdx" J

To make certain of the dependence of the constant C on R on the right side of the inequalities in applying the embedding theorem, we can use the rescaling technique as we did in the proof of Corollary 1.3.2. If p > n, then the exponent q on the left side of the inequalities in Remark 1.3.5 and Remark 1.3.6 can be chosen to be any real number not less than 1. However it is to be noted that in the case p = n, the constant C on the right side of the inequalities depends on q in addition to n, fi.

1.4

t-Anisotropic Sobolev Spaces

Since the space variable x and time variable t play different roles in parabolic equations, the function spaces adopted in the study of parabolic equations are different from those in the study of elliptic equations. In this section we introduce the so-called t-anisotropic Sobolev spaces available to parabolic equations.

1.4.1

Spaces W™>k(QT), and V(QT)

W2pk'k(QT),

Denote QT = Q x (0, T) for T > 0.

Wf^iQx),

V2{QT)

25

Preliminary Knowledge

Definition 1.4.1 set

Let A; be a nonnegative integer and 1 < p < +oo. The

iu; DaDrtu £ Lp(QT),ioi

any a and r such that \a\ +2r < 2k\

endowed with the norm

E \DaD\u\^dxdt\

Mw^{QT)=([[ \JJQT

\a\+2r<2k

/

is denoted by W%k>k{QT). It can be proved easily that Wpk'k{QT) is a Banach space. From the definition of Wpk'k(Qr) we see that the order of weak derivatives with respect to t of the function in Wpk'k(Qr) does not exceed half of the highest order of weak derivatives with respect to x. We need also the following supplemental definition of the space Wm'k(QT) with m, k being 0 or 1. Definition 1.4.2
Let m, k be 0 or 1, and 1 < p < +oo. The set € LP(QT),for

any a,r such that \a\

<m,r

endowed with the norm I/P ll U Hw p m '' c (Q 7 -)

= (// \JJQT

( E \Dau\*+ Y,\Dtu\p)dxdt\ |a|<m

r
J

k

is denoted by W™> {QT). If p = 2, then in all spaces denned above, we may define the inner products so that they become Hilbert spaces. In particular, the space with p = 2, m = k = 1, i.e. the space W 2 ' {QT) is just the space H1(QT) defined in §1.3. We always denote by Du, sometimes by Vu, the weak gradient of the function u with respect to the space variables and denote by Dtu or ut the weak derivatives with respect to the time variable t. Let BIQT and dpQr be the lateral boundary 9fi x (0,T) and the parabolic boundary diQr U {(x,t);x £ Q, t = 0} of QT- Denote by C°°(QT) the set of all functions infinitely differentiable on QT, vanishing near the • lateral boundary diQr, and by C°°(QT) the set of all functions infinitely differentiable on QT, vanishing near the parabolic boundary dpQx-

26

Elliptic and Parabolic

Equations

Definition 1.4.3 Denote by W lk'k(Qr)

the closure of C °°(QT)

in

Wpfc,fe(<9r); by W™'k(QT) with m,fcbeing 0 or 1 the closure of C°°(QT) in Wp>k(QT); WP'k(QT)

by W 2fc ' fc (Qr)

t h e closure of

c°°(QT)

in W2fe>fc(QT); by

with m,fcbeing 0 or 1 the closure of C°°(QT) in W™
Definition 1.4.4 Let L°°(0,T; L2(£l)) be the set of all functions u such that for almost all t € (0,T), u(-,t) € L2(Cl) with ||u(-,t)|| L 2 (n ) bounded. Denote by V2(QT) the set L°°(0,T;L 2 (ft)) n W 2 1 , 0 (<2T) endowed with the norm j . / i

ll u llv 2 (Q T ) =

SUp \\u(-,t)\\L2{n)+

|Du|2otectt

( //

0
\JJQT

One may verify that V2(QT) is a Banach space. Definition 1.4.5

Denote e L2(QT;^n)}

V(QT) = {u &W^\QT)\Dut

,

and define the inner product as (U,V)V{QT)

= (U,V)WI,I{QT)

+

{DuuDvt)L2(QT).

It is easy to prove Proposition 1.4.1

V{QT) is dense in W2' (QT)-

Remark 1.4.1 W^'X(QT) can be regarded as the closure in W2' (QT), of the set of all infinitely differentiable functions on QT, vanishing near the bottom Q x {t = 0}. 1.4.2

Embedding

theorem

For the ^-anisotropic Sobolev spaces, we also have the embedding theorem, whose proof can be found in [Gu (1995)]. Theorem 1.4.1 (t-Anisotropic Embedding Theorem) Let Q C M.n be a bounded domain and 1 < p < +oo. i) If CI has the property of uniform inner cone, then, whenp = (n+2)/2,

Wl'\QT)

C L«(QT),

l
Preliminary Knowledge

27

WP'1(QT))

and for any u £

ML"(QT)

<

1 < q < +oo;

C(n,q,QT)\\u\\W2,i{QT),

when p < (n + 2)/2, W p 2ll (Qr) C L«(Q T ), and for any u e

IMU'CQT)

1< Q <

(n + 2)p n + 2 - 2p

W^,X{QT),

< C(".P>QT)||w||,yp2.1(QT)>

1< Q <

(n + 2)p n + 2 - 2p

is appropriately smooth, then, when p uj 7/<9fi is p>5 (n + 2)/2, W£'1(QT)cCa,a/2(Qr),

0
n +2 P

and /or any u G W p ' ^ Q r ) , n+2 Ma,a/2;Q T < C(n,p,

Remark 1.4.2

QT)\\U\\W2,I{QT),

TTie a&ove embedding theorem can be expressed as L"(QT),

l

Wl> {QT)

0 < a < 2

^(Qr),

x <,<_(!!+%, n + 2 - 2p

1<<7<+CO,

p<"

p=

+2

2

'

n+2 2

'

Using Theorem 1.4.1 for k times repeatedly leads to Corollary 1.4.1

^ ' " ( Q T ) ^ -

(n + 2)p n + 2-2kp

£"(QT),

1 <
L"(QT),

1 < q < +oo,

Ca'a/2{QT),

0
n +2 kp

n+2 ~2~' n +2 kp = ~2~' n+2 kp > kp <

The embedding theorem can be established for the space V^Qr)- For the convenience of applications, we state it for the standard cylinder Qp = Bpx(-p2,p2),

Bp = {x e R n ; \x\ < p).

28

Elliptic and Parabolic

Theorem 1.4.2

Let u € V2(QP).


(

2

sup 2

/

\-p
Equations

Then

u2dx + ff

JBP

\Du\2dxdt

JJQP

,

where 5 -,

when n = 1,2;

«=\*

2

1 H—, n 1.4.3

Poincare's

when n > 3.

inequality

Poincare's inequality can be also established for the ^-anisotropic Sobolev space Wp'l{Qx)- We state it for the standard cylinder Qp. Theorem 1.4.3 (t-Anisotropic Poincare's Inequality) Let 1 < p < +co, p>0. i) Ifu£Wl/{QP), then ff

\u\pdxdt
ii) IfueW^iQp), [f

[J

\Du\pdxdt + p2p [J

\Dtu\pdxdt).

then

\u-up\pdxdt
ff

\Du\pdxdt

+ p2p ff

\Dtu\pdxdt\

where Up = - r - r / / u(x, \Qp\ JJQp

t)dxdt.

Proof. First we use the standard Poincare's inequality (Theorem 1.3.4) to obtain the conclusion for p = 1 and then deduce the desired result by rescaling. •

Preliminary Knowledge

1.5

29

Trace of Functions in f f x ( f i )

In this section, we discuss whether we can and how to define the boundary value for functions in ff^fi) and Hl(QT) = W^iQr)1.5.1

Some propositions

on functions

fl"1(Q+)

in

Denote Q = {x G E n ; \xi\ < 1, i = 1, • • • , n), •E

=

v-^ > Xn),

X

= (Xi,

r = { x £ Q ; i „ = 0} = {x' G R

n_1

Q+ = {x G Q; xn > 0}, • • • , Xn—\

),

; \xi\ < 1, i = 1, • • • , n - 1}.

Proposition 1.5.1 For any u € i f 1 ( Q + ) , there exists a unique function w G L2(T), such that — w(x')\2dx'

esslim / \u(x',xn)

= 0.

We call w(x') the trace of u onT and denote it by *yu(x',0). Proof. Uniqueness is obvious. To prove the existence of the trace, we first note that, by Proposition 1.3.3, there exists um G C°°(Q ), such that lim ||u m -ti|| i f i(Q+) = 0 . v

m—>oo

'

Let 0 < S < 1. Choose a smooth function r](xn) G C J [0,1], such that v(xn) = 1 for 0 < xn < 6 and r)(xn) = 0 for xn less than or equal to 1 but close to 1. Clearly lim \\r}Um-r)u\\Hi{Q+)

=0.

(1.5.1)

Since for sufficiently small e G [0,6], rl

d{r)um) dxn

J£ we have \um(x',e)

-uk(x',e)\2

< /

d(r)um)

d(r)uk)

OXfi

CsXfi

Jo

/ \um(x',e) JY

-uk(x',e)\2dx'

< l JQ+

d(yum) UXJI

QjXji)

_ d(rjuk) UXJI

dx

30

Elliptic and Parabolic

Equations


(L5-2)

(1.5.1) and (1.5.2) imply that, for arbitrary fixed small e G [0,5], {um(-, s)} is a Cauchy sequence in L2(T); we denote its limit function by v(-,e). On the other hand, since {um} converges to u in L2(Q+), there exists a set E c (0,5) of measure zero, such that for any e € (0, S)\E, v(x',e) = u(x',e), Thus, from (1.5.2) we obtain, for e €

a.e. x' S T. {0,5)\E,

/ \um(x',0)-v(x',0)\2dx'<\\r)um-'nu\\Hi{Q+), -u(x',e)\2dx'

/ \um{x',e) /r

(1.5.3)

<\\rjum -r]u\\HHQ+).

(1.5.4)

In addition, clearly / |u m (a; / ,e) - u m (x',0)| 2 dx' < e 1 Jr Jo

du„

2

dx.

0xn

(1.5.5)

Combining (1.5.3), (1.5.4), (1.5.5) with / \u(x',e) — w(x')\2dx'

< / \u(x',e) —

um(x',e)\2dx'

+ / \um(x',e)

-um(x',0)\2dx'

+ f \um(x',0)-w(x')\2dx'

(1.5.6)

yields lim e€(0,S)\E B(0,S)\E

£-.0

/ \u(x',s) — w(x')\2dx'

= 0,

Jr

where w{x') = v(x',0). Remark 1.5.1

D

From (1.5.3), we have lim

/ \um(x', 0) - w{x')\2dx' = 0.

(1.5.7)

By virtue of this fact, we can define the trace of u on V as the function w(x') satisfying (1.5.7) for any sequence {um} C C°°(Q ) converging to u in H1(Q+). It is easy to verify that the trace defined in this manner is equivalent to that defined by Proposition 1.5.1. Since C°°(Q ) is dense

Preliminary Knowledge

31

in C1(Q ) , we can replace the sequence {um} in formula (1.5.7) by any sequence in C1(Q ) , converging to u in H1(Q+). R e m a r k 1.5.2 From the proof of Proposition 1.5.1 we see that the conclusion of the proposition still holds, if we replace Q+ by an arbitrary cylinder D x (0,5) (8 > 0, and D is a bounded domain in R™ -1 j, provided 3D is Lipschitz continuous, or satisfies more general condition such that C°°(Dx (0,6)) is dense in HX(D x (0,5)) (see Proposition 1.3.3). Corollary 1.5.1 onT.

If u & Hl(Q+) n C ( Q + ) , then ju(x',0)

= u(x\0)

a.e.

P r o p o s i t i o n 1.5.2 Let u G Hl(Q+) fl C(Q ) and u = 0 near the upper boundary and the lateral of Q+. If u = 0 on the bottom T of Q+, then u£Hl(Q+). Proof. Extend u to the whole Q by setting u = 0 outside Q+ and denote the new function by u. The proof will be proceeded in two steps. The first step is to prove u G H1(Q). Obviously u £ L2(Q) and the , , . . 9u .. ,v . . , du du _ , weak derivatives —— (i = 1, • • • , n — 1) exist with —— = —— on Q~*~ and axi axi axi du CJU —— = 0 on Q\Q+. Hence —— € L2(Q) for 1 < i < n — 1. It remains to axi axi prove

f

u^Ldx

JQ+

=_ f

OXn

JQ+

|%
W> e C?(Q).

(1.5.8)

OXn

To this end, for sufficiently small e > 0, choose a cut-off function rj(xn) G CQ°(—1,1), satisfying the following conditions V[Xn)

^

0 < r)(x„) < 1, Divide /

IQ+U

if|,„|>2£,

|i7'(ar„)| < - ,

- 1 < xn < 1.

d

JQ+ <- OX.

/ JQ+

u——dx = I u-—(r)(xn)

+ (1 - r)(xn))tp)dx

\ un'(xn)ipdx + / Jo+ JQ+

wq(xn)-—dx oxn

32

Elliptic and Parabolic

JQ+

Equations

OXn

=7f + 7f + 7f.

(1.5.9)

Evidently lim7f = 0.

(1.5.10)

Since for e > 0 small enough, (1 — r}(xn))

i

5 = -L^« 1 -^-))^

and hence lim 7 |

/

p-
Finally, note that u £ C(Q ) and u

(1.5.11)

= 0 . Thus from lx„=0

|7f| < / VQ+

|u77'(a;n)y>|da; n {x; |x„| < 2e}

c r <— / £ JQ+

we arrive at

<2e} |u|da;, r\{x;\xn\ lim7f=0.

(1.5.12)

Letting e -» 0 in (1.5.9) and using (1.5.10), (1.5.11),(1.5.12) yield (1.5.8). The second step is to prove u G 77o(Q + ). To this end, we consider the modified mollification of u: J~u{x) = / je(xi

- 3/1) • ••jeixn-i

- yn-i)je{xn

- Vn - 2e)u{y)dy

JQ

with e > 0 small enough, where j e ( r ) is the mollifier in one dimension. Since js(r) = 0 for |r| > e and u = 0 near the upper boundary and the lateral of Q and on Q\Q+, we have J~u £ CQ°(Q ). Since from the first step, u £ H1(Q), similar to the case of the standard mollification, we can assert lim \\J~u - u\\Hi(Q+) = 0. Therefore u e 7701(Q+).

D

Preliminary

33

Knowledge

Proposition 1.5.3 Let u £ H1(Q+) n C(Q ) and u be the extension of u to Q by setting u(x) = u(a;',0) on Q~ = Q\Q . Then u £ H1(Q). Proof. The proof is just the same as the first step of the proof of Proposition 1.5.2, and the only difference is that here we need to require n{xn) to be an even function. • 1.5.2

Trace of functions

in i f 1 ( f i )

Theorem 1.5.1 Let 0 C K™ be a bounded domain with smooth boundary. Then any u £ Hl(Sl) has trace ju on dQ, and ^u £ L2(dVt), namely, there exists a unique function ju £ L2(d£l) satisfying 2 lim / \um - ju\ da = 0 Jan

(1.5.13)

m—+oo

where {um} C C 1 (fi) is an arbitrary sequence converging to u in

Hl{£l).

Proof. Since dfl is smooth, every point on dQ has a small neighborhood U, with the following property: there exists a smooth invertible mapping * , transforming Q = {y £ Rn; \yi\ < 1, i = 1, • • • , n} into U and Q+ = {y £ Q; yn > 0} into UnQ., such that * ( r ) = UndQ,, where T = {y £ Q; yn = 0}. Let {um} C C 1 (fi) be an arbitrary sequence converging to u in H1^). 4 Denote vm = {r)um) o * with n(x) £ C™(U). Then vm £ C^Q ") and vm = 0 near the upper boundary and the lateral of Q+ and lim \\vm - (nu) o *|| H i(Q+) = 0. m—»oo

^

'

2

By Proposition 1.5.1, there exists h £ L (T), such that lim [\vm(y',0)-h(y')\2dy'

= 0.

Obviously, h = 0 near the boundary of T. Returning to the variable x, we obtain lim / \num — w\2do- = 0, - °° Junan

m >

where w = h o $

and $ = ( $ ! , • • • , $ n ) is the inverse of \I>. Note *n(x)=0

w = 0 near the boundary of U (~l dQ,. After a zero-extension of w to dfl,

34

Elliptic and Parabolic

Equations

the above formula can be written as 2 \vum - w\ da = 0.

lim /

m

^°° JdCl /an

By the finite covering theorem, there exist neighborhoods Ui (i = N

!,••• ,N) with the property stated above, such that dCl C \J U. Let T)i(x) (i = 1, • • • ,N)be the partition of unity associated to U (i = 1, • • • ,N) (see §1.1.5), and Wi be the functions corresponding to Ui, Tji obtained as above, namely, w, € L2(dfl), such that lim

/ \Vium -Wi\2da 'Jan

= 0.

(1.5.14)

m—>oo

N

Denote w = 2_Jwi-

Then w € L2(dCl) and it follows from (1.5.14) and

»=i N

^2(Vium

Um—W

-W

x£d£l

i=l

that \um — w\2da = 0.

lim 'JdCl

This proves the existence of the trace ju dCl By using the local flatting technique to the small neighborhood of any point of 9fi, one can prove the uniqueness of the trace. • Corollary 1.5.2 Let Q C R n be a bounded domain with smooth boundary. Ifu£ H1^) n C(U), then ju =u an an Proof. Use the local flatting technique and Corollary 1.5.1.

•

Corollary 1.5.3

Let fl c K " be a bounded domain with smooth boundary.

7 / t i e H&(Q.), then 7U Proof.

= 0.

there exists a sequence {um} C 0 follows from 77 (f2), which converges to u in i? (f2). Hence ju an • (1.5.13). 1

Since

an

CQ°(Q)

is dense in

HQ(CI), 1

Corollary 1.5.4 Let fl C R n be a bounded domain with smooth boundary. Ifu£ H£(Cl) n C(ty, then u =0. an

Preliminary Knowledge

Proof. 1.5.3.

35

The desired conclusion follows from Corollary 1.5.2 and Corollary •

Theorem 1.5.2 LetQ C R n be a bounded domain with smooth boundary. Ifue H\n) n C(fi) and u = 0 , then u € H&(n). Proof. Cut-off u at the small neighborhood of a given point of dfl, namely, consider rju instead of u with 77 being a cut-off function, flat U D dQ, locally (as we did in the proof of Theorem 1.5.1) and then use Proposition 1.5.2 to conclude the existence of a sequence um € CQ(U (1 £1) converging to rju in if x (Q). Choose such neighborhoods Ui (i = 1, • • • , N) and an open set f/o, such JV

that 9 f l c

N

U Ui, U0 D fi\ |J t/i. Let r)i(x) (i = 0,1, • • • , TV) be a par-

tition of unity associated to Ui (i — 0, l,--- ,iV), ulm (i = l,--- ,N) be the sequences corresponding to Ui, r]i (i = 1, • • • , N) obtained in the above manner. It is evident that there exists a sequence {u^} 6 Co°(fi) convergN

ing to

T]QU

in H1^).

Denote um — ^2Kn-

Then um G CQ(CI) and

{um}

i=0

converges to u in i? 1 (fi). Since C^(Q) is dense in

1.5.3

Trace of functions

in H1^)

=

CQ(CI),

this shows that

Wl,x{QT)

Theorem 1.5.3 Let Q, (ZW1 be a bounded domain with smooth boundary. Then any u £ H1(QT) has trace ju on dpQr and ju € L2{dpQr)Proof. By Proposition 1.5.1 and Remark 1.5.1, there exist a sequence {um} € C°°(QT) converging to u in HX(QT) and a function v(x) £ L2(Cl), such that lim / / \um(x,0)

— v(x)\2dx = 0.

m—+00

Similar to the proof of Theorem 1.5.1, by using the techniques such as local flatting OIQT, finite covering and partition of unity, we may assert the existence of a function w(x,t) e L2(diQr), such that lim / -*00JalQT

m

\um ~ w\2da = 0.

36

Elliptic and Parabolic Equations

R e m a r k 1.5.3 Any u £ ^(QT) also has trace on the upper boundary ofQr- However, such fact is not necessary in later applications. Corollary 1.5.5 Let Cl C Mn be a bounded domain with smooth boundary. IfuG H^QT) n C(QT), then 7 u dpQi

Corollary 1.5.6 Ifu£W2'

dpQj

Let Cl C K" be a bounded domain with smooth boundary.

(QT), then-yu

0; ifu&WriQr),

dpQi

Corollary 1.5.7

then ju

diQT

= 0.

Let Cl C R" be a bounded domain with smooth boundary.

1 1

ISUEW 2 {QT)^C(QT),

thenu

= 0; ifu ewl^iQr)

n C(QT),

then

dpQr

= 0. 9iQT

T h e o r e m 1.5.4 Let Cl C R" be a bounded domain with smooth boundary. ,i/ Ifue Hl(QT) n C{QT), and u 0, then u £W 2i> (QT); if u € 9PQT

1

H {QT) n C(QT),

andu

= 0 , then u <EW2 (QT)dtQT

Proof. To prove the second part, we first extend u to t < 0 and t > T as we did in the proof of Proposition 1.5.3 and then use the techniques such as local flatting, finite covering and partition of unity. Proposition 1.5.2 is applied after local flatting. To prove the first part, we extend u to t < 0 by denning u = 0 there and extend u to t > T as in the proof of Proposition 1.5.3. The new function is denoted still by u. A modified mollification of u in xn ve(x,t)

= J~u(x,t)

= / je(t — s - 2e)u(x,s)ds

(e > 0)

Ju is introduced to approximate u in i f 1 ( Q r ) - Then the techniques such as local flatting, finite covering and partition of unity are used to construct the smooth approximation of v£ in ^(QT), which vanishes near OVQT- •

Exercises 1. Prove Proposition 1.1.1. 2. Let U and V be open sets of M" with V C V C U. Construct a function £ £ C$°(U), such that £(x) = 1,

Vz € V.

Preliminary

37

Knowledge

3. Prove Proposition 1.2.1. 4. Prove Corollary 1.2.1. 5. Judge whether W 1,1 (fi) is a Banach space, where Q C W1 is an open set. 6. Prove Proposition 1.3.2. 7. Prove Propositions 1.3.8-1.3.10. 8. Let u G W 1 , p ((0,1)) with p > 1. Prove \u(x)-u(y)\

< |x-y|1_1/p( /

|i/(*)|pcft)

",

for almost all x,y G [0,1].

9. Let fi C R" be an open set, 1 < p < +oo and u G W 1 ' p (fi). i) Prove u+,u~ G W 1 - p (0), and

{

Du(x),

whenever u(x) > 0,

0,

whenever u(x) < 0,

Du(x),

whenever u(x) < 0,

0,

whenever u(x) > 0,

Du"(a;) = where u+=max{u,0},

u

=min{tt, 0};

ii) Prove Du(x) = 0,

a.e. x G {x G Q,; u(x) = 0}.

10. Prove Corollary 1.3.2 and Remark 1.3.6. 11. Prove Theorem 1.4.3. 12. Prove Proposition 1.5.3.

Chapter 2

L2 Theory of Linear Elliptic Equations This chapter is devoted to the L2 theory of linear elliptic equations. We first present the argument for a typical equation, i.e. Poisson's equation thoroughly and then turn to the general equations in divergence form.

2.1

Weak Solutions of Poisson's Equation

Let fl C i n be a bounded domain with piecewise smooth boundary dtt. Consider the equation -Au = /(i)

(2.1.1)

in fi, where x = (xi, • • • , xn), A is Laplace operator in n dimension, i.e. A - — dx\

— dx\

— dx%

and / € L2(Q,). For simplicity, we merely discuss the Dirichlet problem for equation (2.1.1) with the homogeneous boundary value condition = 0. an If a nonhomogeneous boundary value condition = g(x)

(2.1.2) '

v

(2.1.3)

oil

is assumed with g{x) appropriately smooth on Q, then we can transform the problem into the one with the homogeneous boundary value condition by considering the equation for u(x) — g(x), which is still a Poisson's equation with another function as its right member. 39

40

2.1.1

Elliptic and Parabolic

Definition

of weak

Equations

solutions

Assume that u £ C2(Cl) is a solution of (2.1.1), ip £ CQ°(Q.) is an arbitrary function. Substituting u into (2.1.1), multiplying the two sides by tp and integrating over Q yield - / Ampdx = / fipdx. (2-1.4) Jn Jn By integrating by parts, we can move the operation of derivatives acting on u to ip partially or even completely. In fact, since the support of

dz= / fipdx Jn Jn

(2.1.5)

- / uAipdx = / fipdx. Jn Jn

(2.1.6)

or

This shows that if u € C2(Q) is a solution of (2.1.1), then for any (p € Co°(fi), the integral identities (2.1.5) and (2.1.6) hold. Conversely, if for any ip e Cg°(n), u € C 2 (fi) satisfies (2.1.5) or (2.1.6), then deriving in a contrary way leads to (2.1.4), i.e. / ( - A u - f)tpdx = 0. Jn Because of the arbitrariness of ip, from this it follows that — Au — / = 0 in Q, i.e. it is a solution of (2.1.1). It is to be noted that, in order that the integral in (2.1.5) makes sense, it suffices to require u € / f 1 ( 0 ) , and in order that the integral in (2.1.6) makes sense, it even suffices to require u £ L2(tt). In view of this, it is reasonable to regard a function u £ Hl{Q) (u £ L2(f2)) satisfying the integral identity (2.1.5) ((2.1.6)) for any

L2 Theory of Linear Elliptic

Equations

41

Definition 2.1.1 A function u £ i/ 1 (fi) is said to be a weak solution of equation (2.1.1), if the integral identity (2.1.5) holds for any tp £ CQ°(Q). R e m a r k 2.1.1 Since CQ°(Q) is dense in HQ(CI), satisfying (2.1.5) for any tp £ CQ°(£1) implies the same for any

Riesz's

representation

theorem

and its

application

First we present a method which is based on the following theorem: Riesz's r e p r e s e n t a t i o n t h e o r e m Let F(v) be a bounded linear functional in the Hilbert space H. Then there exists a unique u £ H with ||u|| = H-FH, such that

F{v) = (u,v),

\/v£H,

42

Elliptic and Parabolic

Equations

where (•, •) is the inner product on H. In order to apply this theorem to the solvability of (2.1.1), (2.1.2), we introduce a new inner product (u, v) = I Vu • Vvdx Jn on HQ (fi) with a little difference from the one defined before. That (u, v) satisfies all properties of inner product can be checked evidently. For example, using Poincare's inequality (§1.3.6), we see that (u,v) = 0 in HQ(£1) implies u = 0. Denote ||u|| = (u,u)1/2, \\\u\\\ = (u,^) 1 / 2 . Then for u G HQ(Q), we have a||u||<|||u||| 0, f3 > 0 are some constants. The second part of the above inequality is trivial and the first part follows from Poincare's inequality. This means that the new inner product is equivalent to the older one. Clearly, for any / G L2(Q.), F(v) = f fvdx, Jn

v G Hb(Sl)

is a bounded linear functional in HQ(£1). If we denote the space with the inner product {u,v) by HQ(Q), then from the equivalence, F(v) is also a bounded linear functional in HQ(Q). Thus by Riesz's representation theorem, there exists a unique u G HQ(£1), such that (u,v) = F(v) = f fvdx, Jn

Vv G H%(Q.)

/ Vu • Vvdx = / fvdx, Jn Jn

Vw G.#o( n )-

i.e.

This shows the unique existence of the weak solution of the Dirichlet problem (2.1.1), (2.1.2). Theorem 2.1.1 For any f G L2(Cl), the Dirichlet problem (2.1.2) admits a unique weak solution.

(2.1.1),

L2 Theory of Linear Elliptic

2.1.3

Transformation

of the

Equations

43

problem

Now we turn to another useful method, variational method, which can be applied to not only a wide class of linear elliptic equations, but also a certain kind of quasilinear elliptic equations. First of all, let us observe the following fact: if x = (x\, • • • ,xn) is a minimizer of the quadratic form y{y) = \yAyT

-byT,

yeRn,

where A is a positive definite matrix and 6 is a given vector (existence of the minimizer is obvious), then for any y £ M.n,F(e) = * ( x + ey), as a function of £ S R, achieves its minimum at e = 0 and hence .F'(O) = 0. Since F'(e) = ^ ( i ( x + ey)A(x + eyf

- b(x + ey)T)

= yAxT + eyAyT - ybT, we have F'(0) = y(AxT-bT\

=0,

VyeR"

and hence AxT = bT because of the arbitrariness of y € R™. This shows that, to solve a system of linear algebraic equations, it suffices to find a minimizer of its corresponding quadratic form. The basic idea revealed above is available to differential equations. According to this idea, to solve a given problem for some differential equation, one tries to find its corresponding functional and then to minimize it in a suitable function space. Of course, doing in this way is not always successful for any problem of differential equations. However a wide class of differential equations do have their corresponding functionals. It will be seen soon that the functional corresponding to Poisson's equation (2.1.1) is J

¥\ = o / \^v\2dx - / fvdx2 Ja Jo,

If u e HQ(fi) is an extremal of J[v] in HQ(Q),

then, for any ip e HQ(£1),

44

Elliptic and Parabolic

Equations

as a function of e, F(s) = J[u + e
HQ(£1).

Thus we arrive at

Proposition 2.1.1 Ifu £ HQ(Q,) is an extremal of the functional J[v] in #o(fi), then u is a weak solution of the Dirichlet problem (2.1.1), (2.1.2). The solvability of the Dirichlet problem (2.1.1), (2.1.2) is then transformed to the existence of extremals of its corresponding variational problem. 2.1.4

Existence tional

Lemma 2.1.1 below in

of minimizers

of the corresponding

func-

For any f £ L2(Q), the functional J[v] is bounded from

HQ(Q,).

Proof. By Poincare's inequality (§1.3.6) and Cauchy's inequality with e (§1.1.1), we have, for any v € HQ(£1),

-5(Hi>-s//* where fx > 0 is the constant in Poincare's inequality, e > 0 is a constant to be chosen such that e < —. Then from the above inequality, we obtain

JM>-^£Jnfdx and the boundedness from below of J[v] in HQ(Q) ^s proved. Lemma 2.1.2

•

For any v € #o(fi) and f € L2(Q.), f \Vv\2dx <4|U / f2dx Jn Jn

+ 4J[v],

(2.1.7)

L2 Theory of Linear Elliptic

Equations

45

/ v2dx <4/x2 f fdx + AfiJ[v], Jn Jn where n> 0 is the constant in Poincare's inequality. Proof. have

(2.1.8)

Using Cauchy's inequality with e and Poincare's inequality, we

/ \Vv\2dx = 2 1 fvdx + 2J[v]

Jn

Jn

2

<e : [ v dx + £- f fdx

Jn

Jn

+ 2J[v]

2

< e\x f \Vv\ dx + £- f fdx

+ 2J[v].

/ \Vv\2dx <\ I \Vv\2dx + 2/x / fdx Jn 2 Jn Jn

+ 2J\v]

Jn

Jn

Choose e = — . Then 2/i

and (2.1.7) follows. Using Poincare's inequality to the left side of (2.1.7) we further obtain (2.1.8). • By Lemma 2.1.1, J\v] is bounded from below in HQ(Q) and hence inf J[v] is a finite number. The definition of infimum then implies that tfoo

J\v\.

ffi(fj)

{uk} is called a minimizing sequence of J[v] in HQ(Q,). Existence of the li limit lim J[uk] implies the boundedness of J[ufe], i.e. for some constant M,

k~*oo

\J[uk}\<M,

k=

l,2,---.

From this and Lemma 2.1.2, we see that {uk} is bounded in HQ(Q), i.e. {uk} and {Vtifc} are bounded in L2(£l), which implies the existence of a subsequence {u^} of {uk} and a function u £ HQ(CI), such that uki —*• u, Vu^ —*• Vu(i —> oo) in L2(Q). In particular, we have lim / fukdx i-"30 Jn

= / fudx. Jn

46

Elliptic and Parabolic

Equations

Moreover, from / |V(W/fci-u)|2^>0 Jn i.e.

/ \Vuki\2dx>2 Jn

/ \S7u\2dx, Jn

\ Vuki-VudxJn

it follows lim / \Vuki\2dx *->oo Jn

> 2 lim / Vuki-Vudx*->°° Jn

/ |Vu| 2 dx Jn

= 2 / \Vu\2dx - f \X7u\2dx Jn Jn

f |Vu|: dx.

Jn So

lim J[uki] — - lim / \Vuki\2dx

- lim /

fukidx

> - / |Vu| 2 cte - / / u d z = J[«] and hence inf J[v] < J[u] < lim J[uki] = lim JfufeJ = HZ(Sl)

Thus J[w] =

i-^oo

i-*00

inf J[v}. H*(Sl)

inf J[v], i.e. u is a minimizer of J[v] in i?o(Q).

Proposition 2.1.2 For any f £ L2(Q), minimizer in HQ(Q).

the functional J[v] admits a

Combining Proposition 2.1.1 with Proposition 2.1.2, we obtain again the existence of weak solutions of (2.1.1), (2.1.2). The uniqueness of weak solutions can also be proved in the following way. Let ui,U2 £ HQ(Q) be weak solutions of (2.1.1), (2.1.2). Then by the definition of weak solutions, we have f Vui • Vipdx = I f(pdx, Jn Jn

(i = 1,2),

L2 Theory of Linear Elliptic

47

Equations

and hence / Vui • V
ip e H^(Q)

(i = 1,2).

Denote u = u\ — u-2- Then / Vu • Vipdx = 0, Jn

In particular, choosing ip = u gives 2 / | V 7u\ t dx = 0.

Thus Vu = 0 a.e. in Cl and using the homogeneous boundary value condition yields u = 0 a.e. in fi, which can also be derived from Poincare's inequality / u2dx < C(n,n) Ja 2.2

I |Vu| 2 ob = 0. Jn

Regularity of Weak Solutions of Poisson's Equation

The weak solution obtained in §2.1 is a function in HQ(Q). In this section we investigate the regularity of weak solutions in HQ(Q). The finite difference method is one of the important methods in studying the regularity of solutions. The basic idea of this method is to obtain the differentiability of the solution by investigating its difference quotient. Although the method can be used to the general elliptic equations, we confine ourselves to Poisson's equation in order to make the exposition simple and concise. 2.2.1

Difference

Definition 2.2.1

operators For a function u(x) in Rn, denote Alu(x)

=

u(x + hei) — u(x) h

and call Alh the difference operator in xit where e* is the unit vector in the direction xi. Proposition 2.2.1

Difference operators possess the following properties:

48

Elliptic and Parabolic

Equations

i) The conjugate operator of Alh, denoted by Alh is just the operator —A _h, i.e. for any f(x), g(x) € L 2 (R") with compact support, there holds l

f(x)Aihg{x)dx

[

= - [

g(x)Alhf(x)dx;

ii) Alh is commutative with any differential operator, i. e. for any weakly differentiable function u, there hold DjAiu

= AiDjU

(j = l , 2 , . - . , n ) ;

Hi) The difference of the product can be expressed as AUf(x)g(x))

= Ay(x)n9(x)

+

f(x)Aig(x),

where T£ is the translation operator in the direction Xi, defined by Tlu{x) = u(x + hei). We leave the proof to the reader. The following important properties on the difference of functions in Sobolev spaces are needed for our argument. P r o p o s i t i o n 2.2.2 Let fi C R™ be a domain and i = 1, • • • , n. i) If u £ /f1(f2) and Q.' CC 0 , then for sufficiently small \h\ > 0,

A ' ^ u e i 2 ^ ) and \\&huh*(n')

<

\\Diu\\L2{n).

ii) IfuG L 2 (Q) and for fi' CC fi and sufficiently small \h\ > 0, ||AU||L2(n0 < K with constant K independent of h, then DiU ۥ L 2 (Q') and II Au||i*(n') < K. Proof,

i) Suppose for the moment u G Cl(Sl) n H1^).

a;«(x)

.r

u(x + he^ — u{x)

fh

1

-

Then

/

hh Jo

Diu(xi,---

,Xi-i,Xi

+ 0,Xi+i,---

,xn)d6.

L2 Theory of Linear Elliptic

49

Equations

Using Schwartz's inequality gives rh

|A>(*)r< \h\

[ IA u(xi, Jo

• • • ,Xi-i,Xi

+6,xi+i,

• • • ,xn)\ dO

Integrating over fi' leads to Whu{x)\2dx / Jo

JQ'

/

I

I

\Diu(xi,- •• ,Xi-i,Xi

+ 9,xi+i,--

•i'iW^Ii, • • • , 3^—1, Xi, X j + i , • • •

•

,xn)\2dxd9

,Xn)\

2

dxd6

Jo Jn>h]

\Diu(x)\2dx,

< / Jn

where fi{h| = { i e R n ; dist(x, fi') < |/i|} c ft for small \h\. Thus the desired conclusion is proved for u G C 1 (fi) D /f 1 (Q). By approximation it can be carried over to u £ iJ 1 (fi). ii) By the weak compactness of any bounded subset in L 2 (Q'), there exist a sequence {hk} and a function v G L 2 (0') with ||w||L2(n') < K, s u ° h that for any

/ ipA}lkudx —> / ipvdx. Jo,1 Jw However / <^A^fcuda; = — I 1 uAl_hkipdx —> — /1 Jci' Ja Jo.

uD^dx.

Thus / d:r = — I uD{(pdx, Jw Jw i.e. u = Z?jU.

•

Similarly we can prove Proposition 2.2.3 1,2--- , n - 1.

Lei -8^(0) = {a; G Bi(0);x n > 0},0 < p < l,i =

50

Elliptic and Parabolic

i) If u G Hl(Bf(0)), H^B+iO)) and

then for sufficiently small \h\ > 0, A{u G

HAfcullL»(B+(0» ii) IfuE

L2(Bf(0))

Equations

WDiu\\mB+(0)y

and for sufficiently small \h\ > 0, II^ U IIL2(B+(O)) ^

K

with constant K independent of h, then DiU G L2(B+(Q)) and HAu|lz,2(B+(0)) ^ 2.2.2

Interior

K

-

regularity

Now we proceed to discuss the regularity of weak solutions of Poisson's equation. First we discuss the interior regularity. Theorem 2.2.1 Let f G L2(Q), and u G iJ : (ft) be a weak solution of equation (2.1.1). Then for any subdomain fi' CC fl, u € H2{Q.') and \\U\\H'(Q')

< C (||u||jfi(n) + H/Hz^n)),

where C is a constant depending only on n and dist{ft',9ft}. Proof.

For fixed ft' CC ft, denote d = -dist(ft',dft). Choose a cut-off

function on ft relative to ft', i.e. a function r](x) G Co°(ft), such that 0 < r}(x) < 1,

rj(x) = 1 in ft', dist{suppr?, 9ft} > 2d.

To prove the conclusion of Theorem 2.2.1, by Proposition 2.2.2, it suffices to derive the estimate 2

\A{Vu\2dx

< C(\\u\\2H1{n) + ||/||£ a ( n ) )

(2.2.1) Jn for some constant C independent of h. To establish any estimate on weak solutions, the original starting point is the definition of weak solutions, i.e. the integral identity

/

V

/ Vu • Vydx = f fipdx,

V

(2.2.2)

L2 Theory of Linear Elliptic Equations

51

The crucial step is to choose a suitable test function
L

2 v

\AhVu\2dx

= f AhVu • V{ri2Ahu)dx Jn = f Vw • VAi*(r)2Ahu)dx Jn

-2 -2

[ A\Vu Jn

• r/A^Vrycfo

[ TjA{uVr] • AhVudx, Jn

(2.2.3)

it is natural to choose cp = Azh*(rj2Alhu) (clearly it belongs to HQ(Q,)) in (2.2.2). Thus we obtain / Vu • VAJ, V A ^ ) c f e = / fA\* Jn Jn

(r,2Ahu)dx,

which combined with (2.2.3) gives / r)2\AhVu\2dx Jn

= f fAh*(r,2Ahu)dx Jn

- 2 / T / A ^ V T ? • A^Vudx. Jn

Now we use Cauchy's inequality with e to the integrals on the right side of the above formula to obtain

/ r,'\AhVu\'dx

n Jn [ f2dx + 2e [\Ak*(r,2Aiu)\2dx <± Z£ Jn Jn ~2e + - f \Vri\2\A\u\2dx + e / r ^ l A ^ V u l 2 ^ . £ Jn Jn Using Proposition 2.2.2 i), we have / \Ai*(V2Aiu)\2dx

= f

(2.2.4)

\Ath(v2Aiu)\2dx

< / lA^A^)!2^ Jn < f Jn

\V(V2Ahu)\2dx

= [ I^VA^u + Jn

2rjAiuVv\2dx

<2 f \r]2VAiu\2dx Jn

+ 2 / \2rjAhuVr]\2dx Jn

52

Elliptic and Parabolic

Equations

<2 / r)2\VA{u\2dx Jo

+ 8 [ |VT ? | 2 |A^l 2 da? Jo

and f |V»/|2|A£u|2da; < C f JO

|A^r*|2da: < C f \DiU\2dx
^supp7j

JQ.

\Vu\2dx.

JO

Combining these with (2.2.4), we finally obtain (1 - 5e) / jj 2 |A^V«| a di < C(-v e + lfe) / \Vu\2dx + 2±f £ Jo ' Jo Jo

fdx

and the desired conclusion (2.2.1) follows by choosing e suitably small.

•

Corollary 2.2.1 Let u be a weak solution of equation (2.1.1). If f G Hk(Q) for some nonnegative integer k, then, for any subdomain Q' CC Cl, u G Hk+2(fl') and IMU*+2(fi') < C (||u|| H i(n) + ||/||if=(n)) , where C is a constant depending only on k, n and dist{fi',9fi}. Proof.

First consider the case k = 1. By the definition of weak solutions,

/ Vu • VDupdx = / fDt(pdx, ty> G Cg°(n) Jo JO

(i = 1, • • • , n).

Since, by Theorem 2.2.1, for any subdomain fi' CC Cl, u G H2(n') and / G if 1 (£2) is assumed, we can integrate by parts in the above formula to derive / VDiU • \>
Jo

Jo,

V

(i = 1, • • • , n).

This shows that DiU is a weak solution of the equation -Av

= Dif,

xeQ.

(i =

l,---,n)

and hence we can use Theorem 2.2.1 to assert Dtu G H2(Q') for any subdomain fi' CC O and obtain the estimate l|w|k 3 (n') < C (|M|tfi(n) + ||/||ifi(n)) • By induction, we can prove the conclusion of Corollary 2.2.1 for any positive integer k. •

L? Theory of Linear Elliptic

If f £ Hk(fl)

Corollary 2.2.2

Equations

53

with k > —, then the weak solution u

of equation (2.1.1) satisfies the equation —Au = f(x) in fl in the classical sense. Proof. By Corollary 2.2.1, for any subdomain Q.' CC Q, u G Hk+2(Q,'). Since k > - , by the embedding theorem, Hk+2{Cl') ^ C2'a(n') with

2.2.3

Regularity

near the

boundary

P r o p o s i t i o n 2.2.4 Let Cl C R n be a bounded domain with dfl € C2 and y = ty(x) be a local flatting mapping in a neighborhood of the given point x° G dfl (see §1.1.6). Then for any weak solution of Poisson's equation (2.1.1), u(y) —u{^~1(y)) is a weak solution of the equation

namely, for any ip G C^(B^),

there holds

^ l r • j£rdy = i + KvMv)dy, JB+ °Vi °Vj JB+ where a,ij(y) is the (i,j) element of the matrix [

+

(2-2.5)

(fiii(y))„xn = | J ( j / ) | * ' ( * - 1 ( y ) ) * ' ( * - 1 ( y ) ) T ,

f(y) = \J(y)\W-Hy)), ,_1

and x = ^ (y) is the inverse mapping of y = ^(x), J(y) the Jacobi determinant of the mapping x = * _ 1 ( y ) , W(x) the derivative matrix of the mapping y — $(x) and ^'(x)T the transposed matrix of^'{x). In this book, repeated indices denote summation from 1 to n if there is no other indication. The proof of the above proposition is left to the reader. R e m a r k 2.2.1 In the formula (2.2.5) and the formula before it, repeated indices imply a summation from 1 to n. Such summation convention will be adopted frequently in the sequel. T h e o r e m 2.2.2 Let f G L2(Q) and u G HQ(Q,) be a weak solution of the Dirichlet problem (2.1.1), (2.1.2). IfdCl G C2, then for any x° G dfi, there

54

Elliptic and Parabolic

Equations

exists a neighborhood U of x°, such that u G H2(U n 0) and IM|jj2(t/nn) < C (\\u\\m{n) +

\\fh*(n)),

where C is a constant depending only on n and SlnU. Proof. By Proposition 2.2.4, there exists a neighborhood U\ of x° and a C2 invertible mapping \P : U\ —> Bi(0), such that

*((7i nfl) = B+ = B+(o),

*(t/i n an) = 8B+ n {y e Rn; y„ = 0}

and -t*(y) = u(^!^1(y)) satisfies (2.2.5) for any

Tj 2 |A£v«| 2 dy,

where A£(fc = 1,2, • • • , n — 1) is the tangential difference operator. Similar to the derivation of (2.2.1), we choose

/ ^ 7 P • IT fA£VA^)1 dy = / f(y)tf(r,*Akhu)dy. Using Proposition 2.2.1 i), ii) further gives

Lt AJ (a« w) w, (,2A!:") * = L t /C'^VAS*)*. Since, using Proposition 2.2.1 iii), ii), we have Ah aij

\ dy-)-

h ij

~dy~+

ht3

dy0'

we are led to

o„ fc . 0 A U aA*<2 /. /

9Aju 5u 7 7 2 A^a i j —A- • — d y - 2 /

77—^-A^A^u—
L 2 Theory of Linear Elliptic Equations

-2f

JB{

AtaijAkhu^dy+ °Vj

°Vi

55

/ /(y)AJtVAJt«)d».

JB{

From this we can proceed similar to the proof of the interior estimate in Theorem 2.2.1 to derive

/

\kkhVu\2dy

\Wu\2dy + C f


JB+2

JB+

f2dy.

(2.2.6)

JB+

To do this, it is to be noted that, since dfl G C2, we have &ij G C1 and hence |A*ciij| < M for some constant M. Another more important fact to be noted is that there exist constants A > 0, ho > 0, such that ThaiMo > A KI 2 . provided 0 < \h\ < h0. Using Proposition 2.2.3 ii), from (2.2.6) we see that for any k = 1,2, •• • ,n — 1 and j = 1,2, • d2u

•lst/2

dy
dykdyj

*** dykdyj

(4

GL2(5+2)and

\\7u\2dy + J

+

f2dy

(2.2.7)

Now we rewrite (2.2.5) as

Lt &nnwn • S > = L t IiyMy)dy - £2n Lt &ij iji • 1 ^ or, after integrating by parts in the second term of the right side,

Li ^nWn • | > = Li {Iiy) + i+^2n W, ( % ^ ) J *{V)dyProm this and (2.2.7) it follows that ——\a n n -r—) G L2(Bt/0). Since it is l2 dyn\ dynJ '' 2 du easy to verify that ann ^ 0 in By2, we further have jr-j2 G L 2 (Sjy 2 ) and dy

L

d2u dVn

dy
\Vu\2dy + C / jBi JBi

•L

f'dy.

This combined with (2.2.7) implies u(y) G H2(B~f,2). Changing the variable y to the original one shows that u G H2(U fl fi) with U = }i~1(B^,2) and u satisfies the estimate in Theorem 2.2.2. •

56

Elliptic and Parabolic

Equations

Similar to the interior regularity, we also have Corollary 2.2.3 Let u G HQ (Cl) be a weak solution of the Dirichlet problem (2.1.1), (2.1.2). IfdCl G Ck+2 and f G Hk(Cl) for some nonnegative integer k, then for any x° G dCl, there exists a neighborhood U ofx°, such that u G Hk+2(U n Cl) and IM|jf*+2(t/nn) < C(H|tfi ( fj) + ||/||jj*(n)), where C is a constant depending only on k, n and CinU. Corollary 2.2.4 If dCl G Ck+2, f G Hk(Cl) and k > | , then for any x° G dCl, there exists a neighborhood U of x°, such that any weak solution u of the Dirichlet problem (2.1.1), (2.1.2) belongs to C2'a{U C\Cl) with 0 < Ik 2.2.4

Global

regularity

To prove the global regularity of weak solutions, we choose a finite open covering of Cl and decompose the solutions by means of the partition of unity (§1.1.5). Theorem 2.2.3 Let f G L2(Cl) and u G HQ(CI) be a weak solution of the Dirichlet problem (2.1.1), (2.1.2). If dCl G C2, then u G H2{Cl) and \HHHO)

< C (||«||ffi(n) + ||/||L*(n)) ,

(2-2.8)

where C is a constant depending only on n and Cl. Proof. By Theorem 2.2.2, for every x° G dCl, there exists a neighborhood U(x°) such that u G H2(U(x°) n 0 ) and \H\H2(U(x°)nu) < C (\H\HHQ)

+ ll/lk 2 (n)) •

Using the finite covering theorem we can choose such neighborhoods of N

finite number f/i, • • • , UN to cover dCl. Denote K = Cl \ (J [/*. Then K i=\

is a closed subset of Cl and there exists a subdomain UQ CC Cl, such that U0 D K. Theorem 2.2.1 shows that u G H2(U0), and NI/r*(c/0) < C (||u||ffi(n) + ||/l|z.3(«)) •

L 2 Theory of Linear Elliptic

Equations

57

Using the theorem on the partition of unity, we can choose functions ^o, ?7i> • • • i T)N> s u ch that 0<»/i(x)
VxeK

(i = 0,1, - - - ,N),

N »=i

Thus N

u

2

ll llfl" (n)

N

<£>•

^ViU j? 2 (n)

i=0

li?2(n)

i=0

< c ( H f f i ( n ) + ||/|| L a ( n ) ). R e m a r k 2.2.2

D

Under the assumptions of Theorem 2.2.3, we have hUnn)

< C||/||La(n),

(2.2.9)

where C is a constant depending only on n and fi. Proof.

We first set

Jn

V € H^{Q)

Jn

and use Cauchy's inequality with e and Poincare's inequality to obtain / \Vu\2dx = /

Jn

Jn

fudx

<1£- [ u2dx+±i£ Jn

Jn

[fdx

<£J± [\Vu\2dx + ± [ fdx, 2 Jn

2e Jn

where fi > 0 is the constant in Poincare's inequality. Choosing e = — then M gives / \Wu\2dx < (j. I Jn Jn

fdx.

and further by Poincare's inequality, / u2dx
Jn

l

Jn

fdx.

58

Elliptic and Parabolic Equations

Thus the desired inequality (2.2.9) follows by combining the above two estimates and substituting into (2.2.8). • In the proof of Theorem 2.2.2, the normal derivative of second order is estimated via the equation and the estimates for the tangential derivatives. Repeating this procedure we can estimate higher order derivatives in normal direction. Theorem 2.2.4 Let u G H&(Q.) be a weak solution of the Dirichlet problem (2.1.1), (2.1.2). Ifdn G Ck+2 and f G Hk{Q) for some nonnegative integer k, then u G Hk+2{Q) and llulltf*+2(fi) < C (||u||ffi(n) + ||/||ff*(n)), where C is a constant depending only on k, n and fi. As an immediate corollary of this theorem, we have Theorem 2.2.5 Let u G HQ(Q) be a weak solution of the Dirichlet problem (2.1.1), (2.1.2). IfdCl G C°° and f G C°°(Tl), then u G C°°(ty. Remark 2.2.3 Theorem 2.24 shows that 30, G Ck+2, f G Hk(Cl) imply u £ Hk+2(Q.) and Theorem 2.2.5 shows that <9fi G C°°, f G C°°(Ti) imply u G C°°(f2). This means that the conclusions on the regularity of weak solutions are complete both in Hk(Q) and C°°(fi). In Chapter 8 it will be proved that f G Ca(Q) (a G (0,1)) implies u G C 2,a (f2), which means that the conclusion on the regularity of solutions is also complete in Holder spaces. However it is impossible to assert u G C 2 (0) from f G C(Q). 2.2.5

Study of regularity

by means of smoothing

operators

Smoothing operators u£ = JEu=

/ je(x - y)u(y)dy, Jo.

(2.2.10)

instead of difference operators can also be applied to the study of regularity of weak solutions, where js(x) is an arbitrary mollifier. In (2.2.10), u is regarded as zero outside of CI. It is easy to check the following facts which are an analog of Proposition 2.2.1 i), ii). Proposition 2.2.5

Let Cl c Mn be a domain.

L 2 Theory of Linear Elliptic Equations

59

i) For any u, v £ L J (fi) vanishing outside ofQ, / uevdx = /

Jn

Jn

uv~dx,

where v~ = J~v=

/ j~(x - y)u{y)dy,

j~(x) =

j£(-x).

ii) For any Q' CC fi and sufficiently small e > 0, DiUe = {DiU)e

inQ'

(i = 1,2, • • • ,n).

However we do not have the analog of Proposition 2.2.1 iii) for smoothing operators. This will restrict the application of the present method in the study of regularity. We also have the following proposition which corresponds to Proposition 2.2.2 and can be proved similarly. Proposition 2.2.6 Let Q, CM" be a domain and i — 1,2, • • • , n. i)Ifu£ i? 1 (n) and Q' CC fi, then for sufficiently small e > 0, \\DiUe\\L2(ni)

< ||Diu|| L 3(n).

ii) Ifu e if 1 (fi), fi' CC fi and for sufficiently small e > 0, ||Aw£||L2(fi') < -^ wii/i constant K independent of e, then DiU £ L 2 (0') and ||Aw||L2(fl') < # •

The proof is left to the reader. We do not state the analog of Proposition 2.2.3, although it does hold. Now we proceed to use smoothing operators to establish the interior regularity, i.e. to prove Theorem 2.2.1. Choose a cut-off function r)(x) as in the proof of Theorem 2.2.1. By Proposition 2.2.6 ii), it suffices to establish the estimate 2

2

/ V \DiVue\ dx Jo.

< C (|M| 2 „ 1 ( n ) + | | / | | £ a ( n ) )

for some constant C independent of e. Using Proposition 2.2.5 and integrating by parts, we have

/ rf\DiS7ueYdx n Jn

(2.2.11)

60

Elliptic and Parabolic

Equations

= / A V u e • V(r}2DiUe)dx - 2 / •qDiueVn • A Vu e dx Jn Jn = - / Vu £ • V(A(r? 2 A« e ))da; - 2 / •qDiuEViq • A V u £ d x Jn Jn = - / Vu- V ( A ( l 2 A M £ ) ) £ " d i - 2 / T]DiU£Wr) • DiVu£dx. Jn Jn Choosing ip = (Di(r]2DiUe))~ in (2.2.2) and combining the resulting equality with the above formula lead to / r)2\DiVue\2dx Jn

= - I fiDiirfDiU^-dx Jn

- 2 / rjDiUeVri • DiVuedx. Jn

From this we may deduce (2.2.11) similar to the proof of (2.2.1). 2.3 2.3.1

L2 Theory of General Elliptic Equations Weak

solutions

Now we turn to the following general elliptic equations in divergence form Lu = -Dj(cnjDiu)

+ biDiU + cu = f + A / * ,

(2.3.1)

where ay, 6», c G L°°(fi), / G L2(il), /* G L2(f2), and ay = a^j satisfy the uniform ellipticity condition, i.e. for some constants 0 < A < A, A|£|2 < a y ( * ) ^ < A|^| 2 ,

V£ 6 i n , x € fi.

In this case, we call (2.3.1) uniformly elliptic equations. Here, repeated indices imply a summation from 1 up to n. As in the preceding sections, only the Dirichlet problem with the homogeneous boundary value condition u

= 0

(2.3.2)

an is discussed. Remark 2.3.1

If a nonhomogeneous boundary value condition u

an

= g

is prescribed with g G H1^), then, setting w = u—g, we can change (2.3.1) to an equation for the new unknown function w,

Lw = f + DJi,

L2 Theory of Linear Elliptic

Equations

61

where f = f - hDig - eg,

f =

f+aijDjg.

The boundary value condition which w satisfies is then a homogeneous one. If u £ C 2 (fi) is a solution of equation (2.3.1), then multiplying (2.3.1) with any ip £ CQ?(£1) and integrating over fi lead to, after integrating by parts, / (aijDiuDjip + biDiU(p + cwp) dx = (ftp — f%Ditp)dx. Jn Jn Conversely, if u £ C2{fl) and for any (p £ satisfies (2.3.1) in the classical sense.

CQ°(Q),

(2.3.3)

(2.3.3) holds, then u

Definition 2.3.1 A function u € Hl(Vi) is said to be a weak solution of (2.3.1), if for any ip £ C^(Q), (2.3.3) holds. If, in addition, u £ H^{Cl), then u is said to be a weak solution of (2.3.1), (2.3.2). 2.3.2

Riesz's

representation

theorem

and its

application

Riesz's representation theorem applied to Poisson's equation can be carried over to equation (2.3.1) with 6j = 0 (i = 1, • • • , n), i.e. the equation -DjiaijDiu)

+cu = f + Dif*.

To this purpose, we define a new inner product in

(2.3.4) HQ(CI)

as follows:

(u, v) = / (aijDiuDjV + cuv) dx,

Ja

whose corresponding norm is denoted by ||| • |||. It is easy to verify that if c > Co for a certain constant Co, then (•,•) possesses all properties of inner product. For example, using the ellipticity condition and Poincare's inequality, we have, for u £ HQ{Q),

Mil2 = (u, u) = / {aijDiuDjU + cu2) dx Jn

>A / |Vu| 2 dx + co /

Jn

>a]\u\\2,

Jn

u2dx

62

Elliptic and Parabolic

provided

Equations

\- c0 > 0, where ||u|| is the norm in #o(Q), M > 0

constant in Poincare's inequality and a = min { - ,

is

tne

\- CQ \. From this it

I 2 2fi

)

follows that (u, u) = 0 implies u = 0. Clearly, for a certain constant /3 > 0,

IIMII2
(2.3.5)

which implies, in particular, that F[v] = / (fv - fDiv) Jn

dx

is a bounded linear functional in HQ(Q), the same space as H Q ( O ) endowed with the inner product (•, •). Hence, by Riesz's representation theorem (see §2.1.2), there exists a unique u G HQ{£1) such that (u,v) = / (dijDiuDjV + cuv)dx Jn = * > ] = f {fvJn

fDiv)

dx,

\fv e

H&n).

From (2.3.5) we have u £ HQ(Q) and the above formula implies / {dijDiuDjtp + cu
My e

C^(Q),

which means that u is a unique weak solution of (2.3.4), (2.3.2). Theorem 2.3.1 There exists a constant CQ such that for any f £ L2(Cl), p £ L2(Cl)(i = l,--- ,n), the Dirichlet problem (2.34), (2.3.2) admits a unique weak solution provided c > CQ .

2.3.3

Variational

method

Theorem 2.3.1 can also be proved by means of variational method. The functional corresponding to (2.3.4) is J v

\ \ = o / (aijDivDjV + cv2) dx2 Jn

I (fv - fD^) Jn

dx.

L2 Theory of Linear Elliptic

63

Equations

In fact, arguing as in §2.1.3, we may prove that if u G H^ft) is an extremal of the functional J[v] in HQ(CI), then u is a weak solution of the Dirichlet problem (2.3.4), (2.3.2). To prove the existence of a minimizer of J[v] in HQ(£1), we first establish the boundedness from below of J[v] in HQ(CI). Using the ellipticity condition and Cauchy's inequality with e, we have 2 J[v] >7? / v2dx - | / v2dx 2 / \Vv\ dx + ^ Ja 2 Jn 2 JQ

-—

f fdx

- -

f \Vv\2dx - -J- / ffdx.

(2.3.6)

This and Poincare's inequality further give

M

> i (A_I + c o _£) j ^ i x _ ^ ^ _ ijf

/(/Ml , (aAT)

where /x > 0 is the constant in Poincare's inequality. If Co satisfies — + c o > 0, then we may choose e > 0 so small that - (

f- Co — e) > 0. The

2 V

/Li

/

boundedness from bellow of J\v] in # o ( ^ ) i s thus proved. Combining (2.3.6) with (2.3.7), we obtain / v2dx + / \Vv\2dx
C2J[v],

Vv G H^(il),

(2.3.8)

where C\, Ci are constants independent of v G HQ(Q). Let {ufc} be a minimizing sequence of J[v] in #o(fi). From (2.3.8) it follows that both {uk} and {Vufc} are bounded in L2(Q) and hence there exist a subsequence {MA:I} of {uk} and a function u G i / ^ f i ) such that Ufc, —»• u,

Vwfc, —*• Vu

in L2(f2) as / —> oo.

In particular, we have ;

lim / fuk,dx = / fudx, ^ ° ° JQ JO,

lim / fiDiukldx=

f fDiudx

(2.3.9) (i = 1, • •• ,n).

Moreover, from / [a,ijDi(uk, - u)Dj(uk, -u) + c(v,k, - u)2] dx > 0

(2.3.10)

64

Elliptic and Parabolic

Equations

i.e.

/ (cLijDiUktDjUkt Jn

+cul)dx — / (aijDiuDjU + cu2)dx, Ja

>2 / (aijDiU^DjU + cuk^dx Jn it follows that lim (aijDiiiktDjUkt+cull)dx i—>oo Jn

(aijDiuDjU +cu2)dx. Jn

>

(2.3.11)

Combining (2.3.9), (2.3.10) and (2.3.11), lim J[uk] = lim J[ufc,] > J[u). k->oo

j^oo

Thus u is a minimizer of J[v] in #o (fi) of (2.3.4), (2.3.2) is proved. 2.3.4

Lax-Milgram's

theorem

an(

^ * n e existence of weak solutions

and its

application

It is to be noted that not any elliptic equation of the form (2.3.1) has its corresponding functional so that the variational method can be applied to the Dirichlet problem. If bi (i = 1, • • • ,n) are not all equal to zero, then Riesz's representation theorem also can not be applied. In this case, we need to slightly extend the representation theorem. Lax-Milgram's theorem is one of the very useful results obtained in this direction. Definition 2.3.2 Let a(u, v) be a bilinear form in the Hilbert space H, i.e. a(u, v) is linear in u and in v respectively. i) a(u, v) is said to be bounded, if for some constant M > 0, \a(u,v)\ < M\\u\\\\v\\,

Vu,v £ H;

ii) a(u, v) is said to be coercive, if for some constant 8 > 0, a(u,u)>S\\u\\2, VueH. Lax-Milgram's Theorem If a(u,v) is a bounded and coercive bilinear form in the Hilbert space H, then for any bounded linear functional F(v) in H, there exists a unique u £ H, such that F(v)=a(u,v),

Vv£H

(2.3.12)

L2 Theory of Linear Elliptic Equations

65

and

IMI <

]\\n

Proof. Since a(u, v) is bilinear and bounded, for any fixed u G H, a(u, •) is a bounded linear functional in H. By Riesz's representation theorem, there exists a unique Au G H, such that a(u,v) = (Au,v),

VveH.

(2.3.13)

It is easy to verify from the bilinearity of a(u, v) that the operator A is linear. The boundedness of a(u, v) implies the same property of A: \\Au\\ < M\\u\\,

VuG if.

In addition, since a(u, v) is coercive, we have S\\u\\2 < a(u,u) = (Au,u) < ||Au||||u||,

Vu € H.

Hence j||u|| < ||A«||,

Vu G H,

which shows the existence of A~l. Now we prove that the range of A, denoted by R(A), is the whole space H. First of all, R(A) is a closed subset. In fact, if {Auk} C R{A) is a convergent sequence: lim Auk = v, k~*oo

then, from S\\UJ

- Ufc|| <

\\AUJ

- Auk\\

we see that {uk} is a Cauchy sequence and hence {uk} is also a convergent sequence: lim Uk = u. k—too

Hence, by the continuity of the operator A, lim Auk = Au. fc—»oo

Therefore Au = v, i.e. v G R(A).

66

Elliptic and Parabolic

Equations

Suppose R(A) ^ H. Then there exists a nonzero element w e H, such that (Au, w) = 0 ,

Vu € H.

In particular, if we choose u = w, then (Aw,w) = a(w,w) = 0, which and the coercivity of a(u, v) imply w — 0, a contradiction. Thus R(A) = H. For any bounded linear functional F(v) in H, by Riesz's representation theorem, there exists a unique w € H, such that \\w\\ = \\F\\ and F(u) = (w,v),

v e H.

Choose u = A~1w. Then

Hl^ll^lllhll^illFH and F{v) = {Au,v),

veH

which combined with (2.3.13) leads to (2.3.12).

•

As an application of Lax-Milgram's theorem, we have Theorem 2.3.2 There exists a constant CQ, such that for any f € L 2 (fi) and p € L2(Q.) (i = 1, • • • , n), the Dirichlet problem (2.3.1), (2.3.2) admits a unique weak solution provided c> CQ. Proof.

Denote

a(u,V) = f ( ^ ^ H A ^ + H ^ , Jn

V.,,

G

^(O).

Obviously, a(u,v) is bilinear and the boundedness of a,j, bi, c implies the same property of a(u, v): \a(u,v)\
+ IMU2(n)IMlL=(n))
L 2 Theory of Linear Elliptic

67

Equations

Moreover, using the ellipticity condition and Cauchy's inequality with e, we derive, for u € HQ(Q), a(u,u) >A||Vu||| 2 ( n ) -C J |Vu||«|da; + co||u||^ ( n ) >A||Vu||| 2 ( n ) - | | | V n | | | 2 ( n ) - 2^||«||i a ( n) +co||«|ll3 ( n)

c2 Choosing e such that 0 < e < 2A and then taking CQ > ——, it follows that 2s for some constant S > 0, a{u,u) > 5\\u\\2Hi{n), Vu € H*(Q), i.e. a(u, v) is coercive. Now we can apply Lax-Milgram's theorem to the bounded linear functional F(v) = f (fvJa

fDiv)

dx,

to conclude that there exists a unique u €

IMIW <

v e Hi (Q)

HQ(CI),

such that

-5\\F\\

and a(u,v) = F(v),

Vu€Hl(£l),

which means that u £ HQ (fl) is the unique weak solution of the Dirichlet problem (2.3.1), (2.3.2). D 2.3.5

Fredholm's

alternative

theorem

and its

application

Theorem 2.3.2 merely affirms the weak solvability of the Dirichlet problem (2.3.1), (2.3.2) for the case c > CQ (some constant). To investigate the general case we need the following result (see [Zhong, Fan and Chen (1998)]). Fredholm's Alternative Theorem Let V be a linear space endowed with a norm, A : V —• V a compact linear operator and I the identity operator. Then there is exact one of the following alternatives:

Elliptic and Parabolic

Equations

i) Either the equation x - Ax = 0

(2.3.14)

has a nontrivial solution x G V; ii) Or the equation x-Ax

=y

(2.3.15)

admits a unique solution x G V for any y € V. In other words, if the homogeneous equation (2.3.14) merely has a trivial solution, then the nonhomogeneous equation (2.3.15) admits a unique solution for any y G V, or if for some y G V, the solution of the nonhomogeneous equation (2.3.15) is unique, then for any y G V, the nonhomogeneous equation (2.3.15) has a unique solution. As an immediate application of this theorem, we have Theorem 2.3.3 There is exact one of the following alternatives: i) Either the boundary value problem Lu = 0,

u

an

= 0

has a nontrivial weak solution; ii) Or the boundary value problem Lu = f + DJ\

u

an

= 0

has a unique weak solution for any f G L2(il) !,••• ,n)-

and p

G L2{Q) (i =

Proof. According to Theorem 2.3.2, there exists a constant vQ, such that the equation Lu + vu = f + Dif has a unique weak solution u G HQ(CI) for any / G L 2 (fi) and /* G L2(f2) (i = 1, • • • ,n) provided v > v0, i.e. the operator L + vl has its inverse (L + vI)~l. Thus Lu = h = f + Dif is equivalent to u = (L + u l ^ h

+ v{L + J / / ) _ 1 U

L 2 Theory of Linear Elliptic Equations

69

or u-v{L

+ vl)~lu

={L +

vl)~lh

i.e.

u - Au = w, where A = v(L + i/J)" 1 , w = (L + vl)~lh G #£(fi). To apply Fredholm's alternative theorem, it suffices to prove the compactness of the operator A : HQ(Q) —» HQ(Q). In fact, A can be regarded as a linear operator from l? (fi) to H\ (fi). If we use E to denote the embedding operator from H&(Cl) to L 2 (fi), then we have A = AE : H%(Sl) -> H&(ft). Since the embedding operator from HQ(SI) to L2(Q) is compact and A is a bounded linear operator as shown in the proof of Theorem 2.3.2, we can assert that the operator A — AE : HQ (fi) —+ HQ (0) is also compact. Thus the conclusion of the theorem follows from Fredholm's alternative theorem.

D

Exercises 1. Introduce the definition of weak solutions of the boundary value problem ' A2u = / , du dv

x € 0, 0,

x G 80,

and prove the existence and uniqueness, where CI C K n is a bounded domain, / G L2(Cl) and v is the unit normal vector outward to dfl. 2. Define weak solutions of the Neumann problem for Poisson's equation —Au = / , du . du

0,

ie(], x£

dfl,

where Cl C K™ is a bounded domain, / G L 2 (fl), v is the unit normal vector outward to dfl. And prove that the problem has a weak solution if and only if

/ f{x)dx = 0. Jn

70

Elliptic and Parabolic Equations

3. Assume A > 0. Define weak solutions of the equation - A u + Xu = f,

ieR"

and prove the existence and uniqueness, where / G L 2 (R ra ). 4. Prove Proposition 2.2.1. 5. Prove Proposition 2.2.4. 6. Let B be the unit ball in Rn and u G HX(B) be a weak solution of Laplace's equation - A u = 0,

x £ B.

i) Prove u G C°°(B); ii) Prove that if there exists a function v € C°°(M.n) such that u — v G H^(B), then u G C°°(B). 7. Let u G CQ(IR") be a weak solution of the semi-linear equation

- A u + up = /,

xeW1

where / G L 2 (R"), p > 0. Prove u G iJ 2 (R"). 8. Establish the theory of regularity for weak solutions of general elliptic equations.

Chapter 3

L2 Theory of Linear Parabolic Equations This chapter is a description of the L2 theory of linear parabolic equations parallel to the previous chapter. As in treating elliptic equations, we first discuss a typical equation, i.e. the heat equation in greater detail and then discuss the general linear parabolic equations in divergence form in a brief fashion. 3.1

Energy Method

In this section we introduce the energy method, one of the basic methods available to parabolic equations. Let fl C i " be a bounded domain with smooth boundary dQ, and T > 0 be a constant. Consider the heat equation — - Au = f{x, t),

(x, t)£QT

= nx

(0, T).

(3.1.1)

Different from elliptic equations, we are not permitted to prescribe the condition on the whole boundary of QT- One of the typical conditions to determine the solution is OPQT

where dpQr is the parabolic boundary of QT, i.e. dpQT=dQT\(Clx

{t = T}).

The problem of finding solutions of equation (3.1.1) satisfying this condition is called the first initial-boundary value problem. For simplicity, we merely = 0, i.e. the condition consider the case g{x, t) d,QT

u(x,t)=0,

(x,t) edQx 71

(0,T),

(3.1.2)

72

Elliptic and Parabolic

u(x,0)=uo(x),

Equations

xetl.

Sometimes we even assume g(x,t) boundary value condition

(3.1.3)

= 0, i.e.

u

consider the zero initial-

=0.

(3.1.4)

opQr

If g(x,t) is appropriately smooth in QT, then we may introduce a new unknown function w = u — g to transform the original initial-boundary value condition into the latter.

3.1.1

Definition

of weak

solutions ° 11

Definition 3.1.1 A function u £W2 (QT) is said to be a weak solution of the first initial-boundary value problem (3.1.1), (3.1.2), (3.1.3), if for any

there holds //

(ut(p + Vu-Wip)dxdt=

JJQT

fipdxdt

(3.1.5)

JJQT

and ju(x, 0) = uo{x) a.e. on Cl. o

° in

Remark 3.1.1 Since C°°(QT) *S dense in W2

(QT),

the test function

Sometimes, we merely discuss the equation itself and no initial-boundary value condition is concerned. In this case the following definition is needed. Definition 3.1.2 A function u £ W2' (QT) is said to be a weak solution of equation (3.1.1), if for any tp € CQ°(QT), the integral identity (3.1.5) holds. Remark 3.1.2

It is not difficult to prove that ifu S W2' (QT) is a weak o

solution of equation (3.1.1), then for any (p O .

&C°°(QT)

an

d hence for any

n

tp £W2 (QT), the integral identity (3.1.5) holds. The following propositions provide some equivalent descriptions of Definition 3.1.1, which are frequently used in the sequel. °II Proposition 3.1.1 A function u €W 2 ' (QT) satisfies (3.1.5) for any o


£C°°(QT)

^

an

d

// JJQT

on

ly tfu satisfies

(uttpt + Vw • Vipt)dxdt = II JJQT

ftptdxdt

(3.1.6)

L2 Theory of Linear Parabolic Equations

73

foranyipeC°°(QT)Proof.

Suppose u eW^iQr)

satisfies (3.1.5) for any ip

Then, for any

then, since tp

A

(3.1.6) holds.

satisfies (3.1.6) for any ip £C °°(QT)>

1 (QT)

_

o

/"*

&C°°(QT)

eC^iQr)-

implies / ip(x,s)ds

_

we

&C°°(QT),

may choose

Jo

ip(x,s)ds as a test function in (3.1.6) to derive (3.1.5). Jo

I 1 A function u GWJ (QT) satisfies (3.1.5) for any

Proposition 3.1.2 o


rj

0

if and only tfu satisfies

&C°°(QT)

(uttpt + Vu-V
if

[[

JJQT

fipte~9tdxdt

(3.1.7)

JJQT o

for any

where 6 is an arbitrary constant. Proof.

Suppose u et

Then, since y>te~ //

&WI'1(QT)

&C°°(QT)I

(ut(pte'et

satisfies (3.1.5) for any

eC^iQr)-

have

+ Vu • S/
JJQT

f
JJQT

namely, (3.1.7) holds. o . ,

o

Inversely, suppose u £W 2 ' (QT) satisfies (3.1.7) for any (p eC°°(Qr)Then, since ip GC°°(QT) implies ip(x,t)eet

ft

-6

ip(x,s)eesds

GC°°(QT), Jo we can choose the latter as a test function in (3.1.7) to derive (3.1.6) and also (3.1.5) by Proposition 3.1.1. • Remark 3.1.3 Since C°°(QT) C V{QT) CW\'1(QT) and C°°(QT) is °II dense in W2 (QT), we may choose any

€ V(QT) as the test function in (3.1.6) and (3.1.7). 3.1.2

A modified Lax-Milgram's

theorem

To prove the existence of weak solutions of the problem considered, we will apply a modified Lax-Milgram's theorem. First we prove Lemma 3.1.1 Let H be a Hilbert space, V C H a dense subspace of H and T : V —> H a bounded linear operator. If T _ 1 exists and is bounded,

74

Elliptic and Parabolic

Equations

then the range of the conjugate operator T* of T is the whole space H, i. e. R(T*) = H. Proof. We want to prove that for any h € H, there exists u € H, such that T*u = h. To this purpose, we consider the linear functional F(z) = (h,T~1z), defined in R(T) = D{T~l)

Vz£R(T)

(domain of T~l).

Since

||F|| = sup \F(z)\ < \\h\\\\T-% IMI=i F(z) is bounded. Now we extend F(z) to be a bounded linear functional in R(T) which is a Hilbert space and apply Riesz's representation theorem (§2.1.2) to assert the existence of u S R(T) satisfying (u,z) = F(z) = (h,T-1z),

VzER(T),

i.e. (u,Ty) = (h,y),

VyeV

(T*u,y) = (h,y),

VyeV.

or

This and the density of V in H lead to (T*u,y) = (h,y),

Vy£H.

Thus T*u = h.

U

Modified Lax-Milgram's Theorem Let H be a Hilbert space, V C H a dense subspace and a(u, v) a bilinear form in HxV satisfying the following conditions: i) For some constant M > 0, |o(u,w)| < M||u|| ff ||i;||v,

Vu £H,\/v£

V;

ii) For some constant S > 0, a(v,v)>6\\vfH,

V«GV.

Then for any bounded linear functional F(v) in H, there exists u G H, such that F(v)=a(u,v),

WeF.

(3.1.8)

L2 Theory of Linear Parabolic

Equations

75

Proof. Since for any fixed v £ V, a(-,v) is a bounded linear functional in H, whose boundedness follows from the condition i), Riesz's representation theorem can be applied to assert the unique existence of Av G H, such that a(u,v) = (u,Av)H,

Mu&H.

(3.1.9)

Prom the bilinearity of a(u,v) and the condition i), it follows immediately that the operator A : V —• H thus denned is bounded and linear. Condition ii) and (3.1.9) imply (v,Av)H>S\\v\\2H,

VveV

\\Av\\H>S\\v\\H,

VueV.

and

Thus A~l exists and is bounded. Therefore we can apply Lemma 3.1.1 to assert that the range of A*, the conjugate of A, is the whole space H : R{A*) = H. Now Riesz's representation theorem is applied, from which it follows that there exists a unique h £ H, such that F(v) = (h,v)H,

VveH.

(3.1.10)

Since R(A*) = H, there exists u G H, such that A*u — h, and hence («, Av)H = (A*u, v)H = (h, v)H,

VU G V,

which combined with (3.1.9), (3.1.10) leads to (3.1.8). 3.1.3

Existence

Lemma 3.1.2

and uniqueness Let u ew\'1 {QT).

of the weak

• solution

Then for almost all t G (0,T),

h(t) - I (lu(x,Q)))2dx = 2 / / Ja Jo Jo.

u-^dxds, dt

where h(t) = / u2(x,t)dx, Ja

t<= (0,T).

76

Proof.

Elliptic and Parabolic

Equations

11

According to the definition of W2' (QT), there exists a sequence

{um} CC°°(QT),

such that mlimJ|um-u||

^1,1(^=0.

Prom this and Fubini's theorem, it follows that for almost all t € (0,T), lim hm(t) = h(t), m—MX)

where hm(t) = / u2n(x,t)dx.

Letting m —> oo in

Jn

ft

ft

hm(t) - hm(0) = / h'm(s)ds = 2 /

/»

Q

/

um—^dxds

and using lim

/

/ Um—^p-dxds =

™^°°Jo Jn

°t

u—dxds

J0 Jn dt

and (see Remark 1.5.1) lim hm(0) = lim / uL(x,0)dx m^oo

m->oo Jn

= /

{~iu(x,0))2dx,

Jn

we are led to the conclusion of the lemma.

•

Theorem 3.1.1 For any f € L2(QT), the first initial-boundary value problem (3.1.1), (3.1.2), (3.1.3) admits at most one weak solution. Proof. Let u\, un. be weak solutions of problem (3.1.1), (3.1.2), (3.1.3). Then by the definition of weak solutions (Definition 3.1.1) and Remark 0

i i

3.1.1, u = u\ — ui €W 2 ' (QT), JU(X, 0) = 0 and u satisfies //

(utip + Vu • Vip)dxdt = 0,

V

&W12°{QT)-

JJQT

Choosing

2 (uut + \Vu\ )dxdt = 0,

iQs JJQ,

where X[o,s](t) is the characteristic function of the segment [0, s] (0 < s < T). Hence //

uutdxdt = -

\Wu\2dxdt < 0.

L2

Theory of Linear Parabolic

Equations

77

From this, using Lemma 3.1.2 and noticing ju(x, 0) = 0, we deduce / u2(x, s)dx < 0,

a.e. s € (0, T).

Jn

Therefore u = 0 a.e. in QT, i.e. ui = u
•

Now we are ready to prove the existence of weak solutions. In this section, we consider the problem with zero initial-boundary value condition (3.1.4) and apply the modified Lax-Milgram's theorem stated above to the existence for this problem. Other methods will be introduced in §3.2 and §3.3 to the existence of weak solutions for problem (3.1.1), (3.1.2), (3.1.3) with general initial values. For any f £ L2(QT),

Theorem 3.1.2

the first initial-boundary value * i i

problem (3.1.1), (3.1.4) admits a weak solution u £W2 Proof.

(QT)-

Denote

a(u, v) = / / JJQT

[utvt + Vu • Vvt)e-etdxdt,

u £WI'X(QT),

V£

V(QT),

where 0 > 0 is a constant. Obviously Hu,v)\

< \\U\\WI,I{QT)\\V\\V{QT),

On the other hand, for v G //

Vv •

U ew^iQT),

V(QT),

v e V(QT).

(3.1.11)

we have

Vvte-etdxdt

=\IL«-et>v?dxdt ^t(\Vv\2e-et)dxdt+9-JJ

=\ j l IQ -6T

f IVd 2

Jn

t=T

dx--

f

2 Jn

\W\h-°*dxdt

7|Vd

2

t=o

dx + - [f 2

JJQT

\Vv\2e~etdxdt,

denotes the trace of | Vu| 2 when t = 0. Prom this, noticing

where7|Vv| t=o

that v € V(QT) implies -yS/v

0 and hence t=o

Jn

dx = 0, it=o

78

Elliptic and Parabolic

Equations

we obtain //

-8T

Vv • S7vte-etdxdt

JJQT

2

• Since C°°(QT) is dense in

V(QT),

(3.1.12)

JJQT

Poincare's inequality of the form

v2dxdt < fi / /

//

\Vv\2dxdt.

> ——- / /

JJQT IQT

\Vv\2dxdt

JJQT JJQT

still holds. From (3.1.12) we are led to Vi> • Vvte~etdxdt

// JjQT

-6T Qp-vT

rr rr

Qa-8T

flp-^

rr

Therefore a(v,v)>S\\v\\2wi,1{QT),

VveV(QT),

(3.1.13)

where 5 = min < 6

9e~eT ee~eT

eT

'

4

'

4/i

Choose # =wl'\QT), V = V(QT)- Then, by Proposition 1.4.1 of Chapter 1, V C H is a dense subspace of # and (3.1.11), (3.1.13) show that the conditions i), ii) in the modified Lax-Milgram's theorem are satisfied. Obviously, //

fvte

et

dxdt is a bounded linear functional of v in

JJQT

* 11

H. Therefore there exists a u G H =Wi a(u,v)=

[f

(QT), such that

fvte-9tdxdt,

^v£V{QT),

JJQT IQT

namely, ff JJQT

(utvt + Vu-Vvt)Q-6tdxdt=

ff

fvte-etdxdt,

Vv G V(Qr).

JJQT

This means, by Proposition 3.1.2, u is a weak solution of problem (3.1.1), (3.1.4). •

L2

3.2

Theory of Linear Parabolic

Equations

79

Rothe's Method

In this section we present another important method, called Rothe's method or semi-difference method, which is available to the study of existence for parabolic equations. The basic idea is to difference the equation with respect to the time variable, solve the obtained elliptic equations to construct approximating solutions and use the estimates for approximating solutions to complete the limiting process to arrive at the desired solution. Let Q C M.n be a bounded domain with piecewise smooth boundary. Consider the first initial-boundary value problem (3.1.1), (3.1.2), (3.1.3). Theorem 3.2.1

Let f G L2(QT)

anduQ G # o ( n ) - Then problem (3.1.1),

(3.1.2), (3.1.3) admits a weak solution u GWy (QT)Proof. Suppose for the moment, / G C(QT). We proceed to prove the existence of weak solutions in several steps. Step 1 Difference the equation with respect to the time variable t to construct the approximating solutions. For any positive integer m and function w(x,t), denote wm'j(x)=w{x,jh) where h = T/m.

(j = 0,l,--- ,m),

Consider the approximating equation of (3.1.1) Aum,3=fm,:

{j = lj2,...,m).

(3.2.1)

According to the condition of the theorem, um'° = UQ G HQ(Q). Suppose that u m '-J -1 G HQ(Q) is known. We want to prove that equation (3.2.1) admits a weak solution u m j G HQ(Q). Denote v = u m j . Then (3.2.1) can be written as 1

vm,j-l

-Av + TV = fm<3 + — T —

(3.2.2)

which is an elliptic equation. It follows from Theorem 2.3.1 of Chapter 2, (3.2.2) admits a unique weak solution v = u m j G HQ(Q,). Thus, by induction, we obtain um'\um'2,--in

HQ(Q),

,um'm

which is the weak solution of (3.2.1) for j = 1,2, • • • ,m, succes-

80

Elliptic and Parabolic

Equations

sively, namely, for j = 1,2, • • • , m and for any ip £

/ {^^

HQ(£1),

there holds

~ " m '^ 1 )^ + Wum,i " V < ^) dx = / / m 'Vz-

(3.2.3)

So far we merely obtain an approximation of the required solution on the line t = jh = jT/m (j = 1,2, • • • , m). In order to obtain an approximating solution in the whole domain QT, we define m

wm{x,t)

=Y,Xm'j(t)um'j(x)

(3.2.4)

and

« m ( i , t ) = 5 ] f J ' ( t ) P ( t ) i ' , " J W + (1 - AmJ(t))uroj'-1(i)]

= 5>mj'(*K,J'-1(*) m

+ 53x m , j i (*)A" , J (t)(« T , , , , '(x) - u r o J - 1 ( x ) ) , where x m ' J ' is the characteristic function of the segment [(j — l)h,jh) AmJ(4)=n-o--D, (^ 0,

(3-2-5) and

*€[(,--i)M/o, otherwise.

For fixed x e Cl, (3.2.4) is a step function of t, which equals um'*{x) on [{j — l)h,jh), and (3.2.5) is a broken line function of t, which equals umJ-l{x){um>i{x)) at t = {j- l)h(t = jh). Denote

m

771

f (x,t) =

j2xm'jwm,jw-

Then from (3.2.3) we see that for ip € H&(Q,), t € (0,T), j (^-

+ Vw m • V j dr = /" /"Vdar.

Estimate the approximating solutions.

(3.2.6)

I? Theory of Linear Parabolic Equations

81

We need to prove the following estimates dum dt

2

\\^m\\h(QT) m

m

(3.2.7)

<Mm,

LHQT)

(3.2.8)

<4TMm, 2

\\™ -u \\lHQT)
(3.2.9)

where Mm = ||Vuo||£ a( n) + ll/ m ll! 2 (Q T ). To this purpose, we choose ip — u m j — u m , J _ 1 in (3.2.3) to obtain ))dx

= / fm'j{um>i

-um'j-l)dx.

Prom this we can deduce i . | | „ m J _ •>,mJ-1|l2 u

u

h\\

\\\7n,m<3\\'i 2 L (Q)

4-

llL2(n) + l l V u

\\L

lli,2(n) •

_ll.,in,j

.,m,j

2h"

—1||2

"L'W

I +

h"

II

2"* 21

fm,}\\2 L2

"

(")•

Hence ^ll u

u

llL2(n) + l l V u


llL2(fi) (j = l , 2 , . . . ,m).

(3.2.10)

In particular,

iiv«mj'iiia(n) < i i v t ^ - 1 ! ^ + h\\rm*{ay

(3.2.11)

Iterating (3.2.11) j times yields l|V« m J ||£ a ( n ) < ||V«o||i a ( n ) + / i ^ | | / m ' i | | 2 ( n ) < M m and summing (3.2.10) on j from 1 up to m yields 1 1

m V II | inm , j _ u m , j - l | | 2 2 L (Q.) J= l

(3.2.12)

82

Elliptic and Parabolic

Equations


+ Am,J'(Vum,J' - Vu m j ' - 1 )).

Thus, using (3.2.13) leads to dun dt

•.

Z

Til

n

LHQT)

j =

l

and using (3.2.12) leads to HVu m ||| 2(QT) pT

m

= J2 Xm,j / 1(1 - A n , J ')V« m j ' - 1 + •=1 Jo Jn <2E / j=l

\m'jVum'j\2dxdt

*m'j (llV« m - , '- 1 |li a( n) + HVu r o 'ii 2 ( n ) ) dt

0

m

^JXIIVI^-1!!^)

+ ||VumJ||ia(n))

<4TM m . (3.2.7) and (3.2.8) are then proved. By the definition of wm and u m , we have ^ X m , i ( l - Am'J')(um'J' - um>j~l) which and (3.2.13) imply

and prove (3.2.9). Step 3 Complete the limiting process.

(3.2.13)

L 2 Theory of Linear Parabolic

Since / £ C(QT), fm converges to / in

83

Equations

L2(QT)-

Hence

Jirn^M™ = ||V«o||£ a{n) + | | / | | £ 2 W T ) , which implies, in particular, that {Mm}m=i i s bounded. Therefore, it follows from (3.2.7), (3.2.8) and Poincare's inequality m

•u

ll

2


that {um}^=1 is bounded in W2' (QT), which implies the existence of a subsequence of { u m } ~ = 1 , supposed to be {um}^=1 itself, and a function u £ W2' (QT), such that um converges to u, and —-— and V u m converge dii

weakly to — and Vu respectively, in

L2(QT)-

(JTI

Now we proceed to prove that u is a weak solution of problem (3.1.1), (3.1.2), (3.1.3). First prove u

£W\'1(QT)

and -yu(x,0) = u0(x) a.e. in £2. ° 1 1

To this end, it suffices to check um £ W y (Qr)> ryurn(x)0) = UQ{X) a.e. in fl. For every positive integer m, choose {u^}(^L1 limJuZ-um\\wui(QT)=0, lim / \uf(x,0)

-uo(x)\dx

o

CC°°(QT),

such that (3.2.14)

= 0.

(3.2.15)

For example, we can construct u™ as follows: first choose {u™'3}'%L1 C C§°(Cl), such that lim \\u™'j - umJ\\^m

=0

(j = 1,2, • • • ,m),

K—>00

and then replace u m J by u™'-1 in the expression (3.2.5) of um, followed by a °II mollification with respect to t. um SWV (QT) then follows from (3.2.14), m and 'yu (x, 0) = UQ(X) a.e. in Cl follows from (3.2.15), Remark 1.5.1 and Remark 1.5.2 of Chapter 1. In order to verify that u satisfies the integral identity in the definition o

of weak solutions, we integrate (3.2.6), which holds for any

('^
jf

fmipdxdt.

GC°°(QT),

(3.2.16)

Since from (3.2.9) we see that the fact that um converges to u in L2(QT) implies the convergence of wm to u in L2(QT), we can let m —> oo in

Elliptic and Parabolic

84

Equations

(3.2.16) to deduce ( "PT^ ~ U^(P ) dxdt = II

//

ftpdxdt,

which is equivalent to ' du tp + Vu • Vip I dxdt dt

JJQ.

ftpdxdt,

JJQ-

° 11

due to u £W2 (QT)- Summing up, we have proved that u is a weak solution of problem (3.1.1), (3.1.2), (3.1.3). Moreover, letting m —> oo in (3.2.7), (3.2.8), we obtain du L2(QT)

(3.2.17)


HV«||£aWr) <4T (||V«o||i a(n ) + ll/|li a( Q T) ) Now we turn to the general case / S L2(QT)such that lim || fk - f\\L*(QT)

Choose {fk}^!

(3.2.18) C C(QT)

= 0.

fc—>oo 0

1 1

Let uk GW2 (QT) ( dukbe the weak solution of the problem Aufc = fk, (x,t)eQT, dt uk(x,t) = 0, (x,t)e9Slx (0,T), [uk(x,0)

= u0(x),

xeQ,

as constructed above. Prom (3.2.17), (3.2.18), duk dt


l|V«fc||ia(Qr) <4T (||Vu 0 ||| 2(n) + \\fk\\lHQT)) 0

11

These show that {wfc}^i is bounded in W2' (QT)- Hence we can choose a subsequence of {ufc}£Li, supposed to be {uk}^ X

u GWl' (Qr),

itself, and a function

such that uk converges to u, and -^— and Vuk converge

L2 Theory of Linear Parabolic

weakly to — and Vu respectively, in L2(QT)-

//

l-zrlP

+ 'Vuk-'V(p)dxdt=

Equations

85

Letting k —> oo in

fkipdxdt,

we see that u satisfies the integral identity in the definition of weak solutions. Since 7Ufc(:r,0) = uo(x), from / \u(x,t) — uo(x)\2dx Jfi < / \u(x,i) - uk(x,t)\2dx

Jn

it follows that ju(x, 0) =

3.3

+ / \uk(x,t) -juk(x,

Jn

0)\2dx,

O

UQ(X).

Galerkin's Method

In this section another important method available to parabolic equations, called Galerkin's method, is introduced. This method is efficient in both theory and practical computation. The basic idea of the method is to choose a suitable basic space X and a standard orthogonal basis {u>i(x)} and then oo

to find a solution of the form Yjcj(i)a;i(x). i=l

As a typical example, we still consider problem (3.1.1), (3.1.2), (3.1.3). In order to apply Galerkin's method to prove the existence of weak solutions, we need the following Hilbert-Schmidt's Theoremfsee [Jiang and Sun (1994)]) Let H be a separable Hilbert space, A be a bounded and self-adjoint compact operator and {Aj} be all eigenvalues of A. Then there exists an orthonormal basis {WJ}, such that Auii = AjWj. The existence of weak solutions is proved in four steps: Step 1 Construct basis. Define operator A = ( - A ) " 1 : L2(n) - L2(Q),

f -> Af,

86

Elliptic and Parabolic

Equations

where Af is the unique solution of the problem —Au — / , x £ ( l , an

= 0.

From the L 2 theory of elliptic equations (see Theorem 2.1.1 and Remark 2.2.2 of Chapter 2) we see that Af e H2(Q.) D #o(fi) and \\Af\\HHQ) < C\\f\\LHn), i.e. A is a bounded operator. Integrating by parts leads to

J

/ g(Af)dx

=- [

JQ JQ

A(Ag)(Af)dx

JQ

= - [ A(Af)(Ag)dx

= f f(Ag)dx,

JQ

Vf,g £ L 2 (ft),

JQ

which means that the operator A is self-adjoint. Since HQ(£1) can be compactly embedded into L2(£l), the operator A is compact. Therefore, by Hilbert-Schmidt's theorem, there exists a standard orthogonal basis {ui}iZi, such that AuJi = AjWj. Since

Au = o, x € n, = 0 dQ

admits only a trivial solution, it is certainly \%^Q and hence - A u > j = -— w». Aj

Using Theorem 2.2.4 of Chapter 2 and the embedding theorem, we conclude Wj € C 2 (fi) provided dd is appropriately smooth. S t e p 2 Construct approximating solutions. Set t*o = / ^ QWi and let i=l

m

satisfy 'dUjn

, dt

u>k ) = (Aum,LJk) + {f,uk),

k = 1,2, ••• ,m,

(3.3.1)

L2 Theory of Linear Parabolic Equations

87

where (•, •) is the inner product in L2(Q). Since

x

'

i=\ m

1

(Au m ,w fe ) = ^c™(t)(Awi,u f e ) = ——cjp(i), (3.3.1) implies ±cT(t) = -j-cT(t)+fk(t),

(3.3.2)

where fk(t) = (/.wjt)- Hence # ( * ) = e-*/A* f cfc + y e^x"fk(r)dA

.

Step 3 Estimate approximating solutions. Multiplying (3.3.1) by c™(£) and then summing on k from 1 up to m yield

namely, 2^ll u m(-,i)ll|2(n) = -||V« m (-,t)lli,a(n) + (/(-»*).«m(-.*))Integrating over (0,£), we further obtain

2ll«i"(-.*)llia(n) - 2ll u '"( - ' 0 )lli 2 (n) = — II JJQt

\Vum\2dxdt+

//

fumdxdt.

JJQt

Using Poincaxe's inequality and Cauchy's inequality with e leads to sup | | w m ( - , i ) | | | 2 ( n ) + / / te[0,T]

\Vum\2dxdt

JJQT

0 is the constant in Poincaxe's inequality.

(3.3.3)

88

Elliptic and Parabolic

Equations

Next we multiply both sides of (3.3.1) by —c™(£) and sum on k to obtain dum

dum\

( = Aum

-dr'-dr)

dum\

( + f

{ >-dr)

dun

{ >-d-t

Integrating over (0, T), integrating by parts with respect to x and using Cauchy's inequality we are led to \dum jf Jf^\ dxdt+\\Vum(;T)\\lHn) dt
fdxdt.

(3.3.4)

IQ JJQT

Combining (3.3.4) with (3.3.3) yields

I

QT

du, m |Um| + |Vu m | + dt \ 2

2

2

dxdt < C,

(3.3.5)

where C is a constant independent of m. S t e p 4 Complete the limiting process. The estimate (3.3.5) implies the existence of a subsequence of {um}, supposed to be {um} itself, and a function u S W2' {QT), such that um , dum ,_ ,, du , _ converges to u, and —-— and \um converge weakly to -— and vu respecat at L2(QT)-

tively, in

The function u is expected to be a weak solution of problem (3.1.1), (3.1.2), (3.1.3). 0

11

First we have u £W<2 {QT)- In fact, by Theorem 1.5.4 of Chapter 1, O i

i

O i

i

um GW2' (QT) and u is the weak limit of um in Wi (QT)Let h S C 2 (Q) and ip e C 2 [0, T] be arbitrarily given functions such that h

= 0 , ip(0) = tp(T) = 0. Choose a sequence 3 h x

j( )

'^2ajkUk(x),

= fe=l

1

converging to h in H ^). Multiply (3.3.1) by ip(i), integrate over (0,T) and integrate by parts with respect to x. Then let m —-> oo to obtain //

—Ukipdxdt = -

Vu • Vu)ki>dxdt + / /

fuikiidxdt.

L2 Theory of Linear Parabolic

89

Equations

Prom this it follows by multiplying by ajk and summing on k from 1 up to j , that du

hjtpdxdt

JJQ-

-II

II

Vu • Vhjipdxdt + / /

JJQT

fhjipdxdt

JJQT

Letting j —> co then leads to

JJQi

du hipdxdt dt

Vu-Vhipdxdt+ JJQ-

//

f hipdxdt.

JJQT

Because of the arbitrariness of h and ip, we may assert that for any ip £ C O ° ( O T ) (for instance, use Lemma 3.5.1 of §3.5.3) // JJQT

—
Vu • Wipdxdt + / /

JJQT

fipdxdt.

JJQT

This formula can be further proved without difficulty to hold for any o


namely, u is a weak solution of (3.1.1). It remains to verify 7u(:r,0) = UQ(X). We have €C°°(<9T)I

/ \u(x,t) — uo(x)\2dx Ja ; / \u(x,t) - um(x,t)\2dx Ja.

+

J

Jn

+ I Ja

£(c?(t)-*)<*(*)

dx

i=l

^2 CiU)i(x) dx l=7Tl + l

=h + h + h Evidently, I\ and I3 can be made arbitrarily small by choosing m large enough. Once m is fixed, Ii can be made arbitrarily small if t > 0 is small enough. Thus we have lim / \u(x,t) — uo(x)\2dx = 0.

3.4

Regularity of Weak Solutions

We first discuss the interior regularity.

90

Elliptic and Parabolic Equations

Theorem 3.4.1 Let f € L2(QT) and u of problem (3.1.1), (3.14). Denote

€W\X{QT)

Q5T = Slsx

fls = {xe Q; dist(x, 9fi) > 6}, Thenu£Wl'l{QsT)

be a weak solution (0,T).

and

\M\WI\QI.)

<
(3.4.1)

with constant C depending only on n and 5. Proof.

By the definition of weak solutions,

//

(ut

JJQT

fipdxdt,

V

(3.4.2)

JJQT

Choose a cut-off function r)(x) £ 0^(0.),

such that rj = 1 on fig, 0 < rj{x) <

1 and |V77(ar)| < —. Since for small h, tp = A{*(r]2Aiu)x[o,s} we can substitute it into (3.4.2) to obtain ff JJQs

= ff

L A ^ V A > ) + Vu • V ( A j / (v2Aiu)} L

€WI'°(QT),

dxdt J

fAi*(r,2A{u)dxdt,

(3.4.3)

JJQs

where i = 1,2, • • • , n, X[o,s](t) is the characteristic function of the segment [0, s] (0 < s < T). Using the properties of difference operators and Lemma 3.1.2, yields JJ

utAih\n2Aihu)dxdt=JJ

^^r,2Aiudxdt

-\j]Q}t^^hu)2)dxdt r,2(Aiu(x,t))2dxt=S t=o

=1 f * Jn =\ f

2 V

(Aiu(x,s))2dx.

J it

Thus, from (3.4.3), we obtain \ f n2{Aihu{x,s))2dx+ z

Jn

< ff

ff

Vu.V(Ai*(r,2Aiu)dxdt

JJQ3 2

fA\*{r] Aiu)dxdt,

0 < s < T,

(i = 1,2, • • • , n)

L2 Theory of Linear Parabolic

Equations

91

which implies i

f rj2{Aihu{x,s))2dx

sup

2o<s
< ff

Vu-V(Ai*(r)2Aiu)dxdt

+ ff JJQT

fA^^A^dxdt,

(i = l , 2 , - . - , n ) .

(3.4.4)

JJQT

Starting from this, we can proceed as we did in Chapter 2 for Poisson's equation to derive / rj2(Aihu{x,s))2dx

sup

\A]yu\2dxdt

+ ff

0<s
JJQ%.


(t = l , 2 , - . . , n )

(3.4.5)

which implies, by virtue of Proposition 2.2.2 of Chapter 2, that r?|Vu| S L°°((0,T);L 2 (f2)), D2u € L2(Q5T) and sup / r,2\Vu(x, s)\2dx < C K(||V«||i a ( Q T ) + | | / | | i 2 ( Q T ) ) , o<s
(3.4.6)

\D2u\2dxdt < C (||V«||i a ( Q T ) +

(3.4.7)

ff

||/|||2(QT))

•

JJQT

The difference is that here there is an additional nonnegative term on the left side of the inequality and the integrals are with respect to both the space variables and the time variable. In addition, as the starting point of our derivation, (3.4.4) is an inequality rather than an equality as we got for Poisson's equation. However this does not prevent us from deriving the desired estimate. To derive the estimate on Ut, we use the difference operator in t, which is denoted by A° for simplicity. Extend u to Q x (-co, +oo) by setting u = 0 outside jf

QT-

Take tp = r]2A°hu

(^rj1Alu

€WI'°(QT)

+ Vu-V{r}2A°hu))dxdt

to obtain = ff

fV2A°hudxdt

ff

A°h{r)2\Vu\2)dxdt

or // JJQT

rj2^A°hudxdt &t

= ff

r)2fA°hudxdt-

JJQT

JJQT

- 2 // JJQT

r)A°huVu • Vrjdxdt.

92

Elliptic and Parabolic

Equations

Using Holder inequality, Cauchy's inequality with e and (3.4.6) gives

I

r]2—A0hudxdt dt

QT

<-

rj2(A°hu)2dxdt+

(I

[f

4 JJQT

+ \ fl II

* JJQT

+
A°h(r)2\Vu\2)dxdt

+ l [[ ' JJQT

r)2(A°hu)2dxdt + 4 / /

4 JJQT

<\

rffdxdt

JJQT

|Vr/| 2 |Vu| 2 dxrft

JJQT

r]2(A°hu)2dxdt+

f[

fdxdt

+ 4 sup

JJQT

f

r}2\Vu(x,s)\2dx

O<S
(T)71|V*|2<M •r,HK")2dxdt + C (ll V«||l, ( „ ri + VHIHOT))

•

>QT

By Proposition 2.2.2, we get

// a /(t)«4// 0 /(§^ + C(||VU||2L2(QT) + | | / | | | 2 ( Q T ) ) ,

which implies

JJ

s

(^fdxdt

< C (||VU\\2LHQT) + \\f\\lHQT)) .

(3.4.8)

Combining (3.4.8) and (3.4.7), we obtain the desired estimate.

•

Since we can treat the integrals containing ut in deriving the estimate near the lateral boundary similar to the interior estimate, we can obtain the estimate near the boundary for equation (3.1.1), and hence combine it with the interior estimate to obtain the following result on the global regularity. Theorem 3.4.2 Let f £ L2(QT) and u €W\'X{QT) be a weak solution of problem (3.1.1), (3.14). If dQ e C2, then u £ Wl'l{QT) and HIV^

W T )

< C{\\U\\W1,O{QT)

+ ||/||L'WT)),

(3A9)

with constant C depending only on n and fi. Remark 3.4.1

Under the assumptions of Theorem 3.4-2, there holds \\u\\w^(QT)
(3.4.10)

L2 Theory of Linear Parabolic

93

Equations

with constant C depending only on n and Q.. Proof.

By the definition of weak solutions, ff

(uttp + Vu-Vtp)dxdt=

JJQT

//

ftpdxdt,

V
ewl'°(QT)•

JJQT

Choose (p = u and use Cauchy's inequality with e and Poincare's inequality on fi to obtain - / u2(x,t)dx 2jn

= //

\Vu\2dxdt

+ //

«=o

JJQT

fudxdt

JJQT

<— ff

u2dxdt + £ ff

<\ ff

\Vu\2dxdt+^ ff

2/u JJQT 2 JJQT IQT

fdxdt

2 JJQT JJQT *2 JJQi

fdxdt,

where \x > 0 is the constant in Poincare's inequality. Since u satisfies the zero initial value condition, this leads to

ff

\Vu\2dxdt < fi ff

JJQT

fdxdt,

(3.4.11)

JJQT

from which we obtain by using Poincare's inequality on D. ff

u2dxdt < \x2 ff

JJQT

fdxdt.

(3.4.12)

JJQT

Combining (3.4.11) with (3.4.12) gives

Finally we substitute it into (3.4.9) to obtain (3.4.10).

•

Furthermore, we have *I I

T h e o r e m 3.4.3 Let u GW2 (QT) be a weak solution of problem (3.1.1), (3.14). If dQ, e C2k+2 and f € W22fe,fe(Qr) for some nonnegative integer k, then u e W2k+2'k+1 (QT) and \\u\\wik+2,k+nQT)

< C ( | | t i | | W a i . o W T ) + \\f\\w^k(QT))

where C is a constant depending only on k, n and Q,.

>

94

Elliptic and Parabolic

Equations

Corollary 3.4.1 Let u &W\'1{QT) be a weak solution of problem (3.1.1), (3.1.4). IfdSl G C°° and f G C°°(QT), then u G C°°(QT). L2 Theory of General Parabolic Equations

3.5

Now we turn to the general parabolic equations Lu— — - Dj(aijDiu) where ay, bt, c G Lco(QT), parabolicity condition A|£|2 < dijix^Uj

+ biDiU + cu = f,

f G L2{QT)

< A|^| 2 ,

(3.5.1)

and oy = aji, satisfy the uniform

V£ € R n , (x,t) G QT,

where A, A are constants with 0 < A < A. Here, as before, repeated indices imply a summation from 1 up to n. As in the preceding sections, we consider the problem for (3.5.1) with the initial-boundary value conditions u(x,t) = 0,

( x , t ) 6 3 f i x (0,T),

(3.5.2)

u(x,0) = u0(x),

l£fl.

(3.5.3)

Existence of weak solutions of the problem will be treated by means of the methods which we have applied to the heat equation in the preceding sections. The weak solution u GW2' (QT) of problem (3.5.1), (3.5.2), (3.5.3) is defined by

I

{ut

QT

ftpdxdt,

V GC°°(QT).

(3.5.4)

QT

All of the methods will be described in a brief fashion. 3.5.1

Energy

method

As shown in §3.1, the application of the method to the existence of weak solutions is based on a modified Lax-Milgram's theorem. This theorem can also be used to equations of the form (3.5.1) whose coefficients ay depend only on the space variable x. To demonstrate this fact, as we did in §3.1,

L 2 Theory of Linear Parabolic

95

Equations

we need the following identity which is equivalent to (3.5.4): (utft + aijDiuDjifit + biDiU(pt + cu
//

II

fipte-etdxdt,

V^eC°°(Qr),

where 8 > 0 is a constant which can be chosen arbitrarily. As in §3.1, we consider only the case UQ = 0. Denote the bilinear form a(u, v) as (utvt + UijDiuDjVt + biDiUvt + cuvt)e~~etdxdt,

a(u, v) = / / JJQT

UQW\'1{QT),V£V{QT),

whose boundedness is obvious. To prove the coercivity of a(u, v), i.e. for some constant S > 0, a(v,v) > % | | ^ I . I W T ) ,

VveV(QT),

(3.5.5)

we need to estimate all terms in the expression of a(v, v). Since a^ are independent of t, we may use the parabohcity condition to derive, similar to the proof of Theorem 3.1.2, for v € V(QT), a,ijDivDjVte~~0tdxdt

11 JJQT

^-(aijDivDjv)e~etdxdt

= 2 //

TT (aaDivDiVe"61)

=x / / 2 JJIQT QT -8T

2

dt

K

>

I auDivDjV

Jn

Ae- e T

f \Vv

t=r

Jo.

2

2

dx + - / /

dx + t=T

aaDivDiVe~etdxdt

dxdt + -

2JJQT

°4 II 2

JJQT

aaDivDiVe~etdxdt

\Vv\2e~etdxdt

JJQT

0t

e~ dxdt.

In addition, using Cauchy's inequality with e, we get // JJQT

biDiVvte~6tdxdt

(3.5.6)

96

Elliptic and Parabolic

v2e~etdxdt

<e ff

+-

Equations

ff

\Wv\2e~8tdxdt,

(3.5.7)

v2e~etdxdt,

(3.5.8)

and cvvte~8tdxdt\

// JJQT

<e / /

I 0t

v?e- dxdt

JJQT

+£

ff JJQT

where the constant C depends only on the bound of \bi\ and \c\. Combining (3.5.6), (3.5.7), (3.5.8) and using Poincare's inequality, we are led to a(v,v) >(1 - 2e) / /

v2e~etdxdt

JJQT

+ (e-±-C) ff \Vv\2e-0tdxdt 4

+I

e ,

JJQT

V

S-?)1" "^

where /x > 0 is the constant in Poincare's inequality. From this, (3.5.5) follows immediately by choosing e > 0 small enough and 6 > 0 large enough. Remark 3.5.1 Recalling Theorem 2.3.1 of Chapter 2, we observe that to prove the existence of weak solutions for elliptic equations, the coefficient c is required to be less than some constant CQ. However, as stated above, for parabolic equations, no other conditions in addition to the boundedness of c are required. This is an essential difference between parabolic equations and elliptic equations. 3.5.2

Rothe's

method

In applying Rothe's method to the heat equation in §3.2, we transformed the problem into the one of solving elliptic equations and establishing some necessary estimates; the resulting elliptic equations are treated by means of variational method. All of these are available to more general parabolic equations in divergence form. However, since the variational method can not be applied to elliptic equations involving terms of first order derivatives, here we merely discuss equation (3.5.1) with bt = 0(i = 1,- • • ,n). We stress that, different from the case of elliptic equations, in treating par-

L2 Theory of Linear Parabolic

97

Equations

abolic equations, no other conditions in addition to the boundedness of the coefficient c, are required. In the present case, the elliptic equation obtained by discreticizing (3.5.1) with respect to t is ,,m,k-l

j . + c)v = fm'k + ——, whose corresponding functional is J{v) = - / (aijDivDjV

+[r+

.

,.m,fc-lN

cjv2 \

-2(/ m ' ,s + ^ — y)dx,

Wei^O).

Since in the expression of J(v), the coefficient of the term v2 is — + c h which can be made nonnegative if h > 0 is small enough, because of the boundedness of c. Thus the boundedness of J(v) from below is obvious. 3.5.3

Galerkin's

method

In applying Galerkin's method, the key step is to choose a suitable basic space and a standard orthogonal basis in it. For general parabolic equations (3.5.1) in divergence form, we choose L2(Q) as the basic space. The existence of the needed basis is proved in the following Lemma 3.5.1 Assume 80, 6 C2. Then there exists an orthonormal basis ( w i}iSi in L2(Q) satisfying the following conditions: i) ua e C2(f2), Ui = 0, (ui,Wj)Li(n) = <5y; oil

it) For any ip £ HQ (Q.) and e > 0, there exists a function of the form N


cteR,

i=l

such that \\V~
<£;

Hi) For any v € C2(QT) vanishing near the lateral boundary

DIQT

and

98

Elliptic and Parabolic Equations

e > 0, there exists a function of the form N

vN(x,t)

a(t) G C 2 ([0,T]),

= Y,Ci{t)^i{x), i=l

such that //

(\v-vN\2+

\Vv-VvN\2)dxdt

<e.

JJQT IQT

Proof. Since dCl € C 2 , by means of local flatting of the boundary, finite covering and partition of unity, we may assert the existence of a function C(x) G C2(f2), such that C = 0 and C(x) > 0 in fi. Let Q, C {x G R n ; 0 < ^ < Z, i = 1,2, • • • , n} and denote n/2

n

nSin(

Wfc(a;)

where A; = (fci, fc2,..., fcn) and fcj (j = 1, • • • , fcn) are positive integers. Given ip G Cg°(fi). By the definition of C, j G C$(fi). Hence for h > 0 small enough, ( ^ ) G Cg°(ft) and

<

#!(")

2'

where /^ denotes the mollification of / with radius h. Now we expand I — I in a Fourier series with respect to {u)fc}. Since this series and the series obtained by differentiating each term formally converge uniformly in Q, for any e > 0, there exists a function of the form V J Ck<*>k{x), such l
that

v s /

'»

^

l
i.e. f >»

£

l
£

c

(7) - E

CfcWfe

L 2 (fi)

<2' if!(fi)

L2

Theory of Linear Parabolic

+E

dX

i\<Jh

Equations

<

!
L2(Cl)

Thus
E

<£,

CkUJk 2

l
L (f2)

/V E a9^vcy

cfcDfc

^ ***

<e. 2

L (fi)

Setting wj(x) = ((x)wfc(:E) leads to

M7~ E l
CkGlk


L2(Q)

L (fi)

and

£

dw

^

v-^

9^t

i
^ L2(n)

i=l n

sE

-^ 7 - y " cfcwfe M ^ 1<7?
L2(n)

i=\

+E c

d ftp dxt \ C

5Z c* dxi

duk

Kk i
»=i

L2(n)


V? -

5 Z l
CkU}


*k m(n)

where the constant C depends only on C and is independent of
100

Elliptic and Parabolic

Equations

It remains to prove that {uJk} satisfies iii). To this end, we first expand /

\ .

T=T

. i

i .

2rrm

| , „ — < ) m = _ and ( c o s _ , | ^ v(x, t) in QT with respect to ^ ssin t ,

,.

v x

v-^

/ N . 2m7r

t) = Z-, am{X) m=l

(,

y-^ . , .

Sin —^-t

+ 2 ^ Pm(x) m=0

:

2m-K COS - ^ - * ,

where am,/3m € C 2 (fi) and a„ = /? m = 0. Since this series and the an Ian series obtained by differentiatii series obtained by differentiating each term formally converge uniformly in QT, for any e > 0, there exists a integer Ni, such that //

(\v - vNl | 2 + |Vu - VvNl | 2 ) ctecft < e,

where /

\

V"»

/ \ •

2m7T

^r—>. . .

2m7T

vNl (x, t) = 2 ^ am(aO sin -—-* + 2 ^ ftn(i) cos —jT*m=l

m—0

Prom ii), it follows that there exists a positive integer N, such that

am-

Yl

c'k,mUk

i
Hi(n) 2 c

<—,

fc,mwfc

l
m = 0,l,--- ,iVi.

tfi(n)

Hence //

{\v-vN\2

\Vv-VvN\2)dxdt
+

JJQT

where NI

VN

2TO7T

(x, t) = 2^ sin - — t m=l

2_,

V^l

1

)

l
cos—-t m=0 nN

•:^2ci(t)Wi(x). i=l

2^ \
Ck.mWkW

L2 Theory of Linear Parabolic

Equations

101

The proof is complete.

•

Now we use Galerkin's method to prove the following Theorem 3.5.1

Assume that dCl G C2, o y , bt, c, -^-

L 2 (0), a,ij = aji satisfy the parabolicity condition and

G L°°(fi), / G

G HQ(Q). Then °II problem (3.5.1), (3.5.2), (3.5.3) admits a weak solution in WY (QT)UQ

Proof. We merely prove the conclusion of the theorem for the case atj G Cl{QT), c,f£ C(QT). The conclusion under the assumptions of the theorem can be carried over by approximation. We proceed first to construct the approximating solutions. Since UQ G m

HQ(£1),

by Lemma 3.5.1 ii), there exists u™ — ^ J c ™ ^ converging to

UQ

in

i=i

Ho(fi). Approximating solutions to be found are of the form m

um{x, t) = Y2 9T(t)ui(x)

(m = 1,2, • • •),

i=l

satisfying /

(dum

[~ariJl<: +

dum

ai

duik , , dum

i~d~ ' ~Q~.

+

bi

~Q~UJk

, +

^rn^k

^,

~ J^kjdx

fc = 1 , 2 , •• • , m ,

n

= 0,

(m = l , 2 , •••)

or g™(t) (i = 1,2, • • • , m) satisfying equations of the form jt9r(t)=fi(t,9T(t),---,9Z(t))

(t = l > 2 , - . - , m ) ,

where fa are some linear functions of g™,g™, • • • ,g^initial value conditions 9T(0)=c?

(» = l , 2 > - . - > m )

(3.5.9) I*1 addition, the (3.5.10)

should be satisfied. By the theory of ordinary differential equations, problem (3.5.9), (3.5.10) admit solutions $"(*) G C^O.T]. For approximating solutions thus constructed, we can prove \\um\\w^{QT)
(m = l,2,---)

without difficulty and then take limit of a subsequence of {um} to obtain the desired weak solution. D

102

Elliptic and Parabolic

Equations

Exercises 1. Prove Theorem 3.4.2. 2. Establish the theory of regularity of weak solutions for general parabolic equations. 3. Define weak solutions of the Cauchy problem du — -Au

+ Xu = 0,

(x,t) e l " x (0,T),

Oil

u(x,0) = u0(x),

x £

and prove the existence and uniqueness, where A g R and UQ £ H 1 (R"). 4. Consider the first initial-boundary value problem du

- A u = 0,

(i,f)6Qr =

u{x,t) = 0,

(x,t)edQx

u(x,0) = u0(x),

fix(0,r), (0,T),

xeQ.,

where O c R n is a bounded domain and u0 £ L2(Q,). i) Define weak solutions of the above problem and prove the existence and uniqueness; ii) Prove that if u is a weak solution of the problem, then u £ C°°(QT) and if, in addition, dQ £ C°°, then u £ C°°(Ti x (0, T)). 5. Let u £ CQ(QT) be a weak solution of the equation du

du

Hi - Au + IVul + at

+ up = f,

fat)

G QT = SI x

(0,T),

where fi c R n is a bounded domain, / £ L2(QT), p > 0. Prove u £ 2 H (QT). 6. Define weak solutions of the second initial-boundary value problem r du dt du

-Au = f,

•u(x,0) = u0(x),

(i,t)GQr = nx(0,T), (x,t) e f f l x (0,T), x &Q,

and prove the uniqueness, where 0 C R™ is a bounded domain, / € g e L2{dCl x (0,T)) and u 0 £ L 2 (^).

L2(QT),

L2 Theory of Linear Parabolic Equations

103

7. Define weak solutions of the initial-boundary value problem ' du — + A2u = f, ( i , t ) e O r = n x ( 0 , r ) , du (x,t)£dQx (0,T), u = — =0, ov u(x,0) = 0, and prove the existence and uniqueness, where fl c Rn is a bounded domain, / G L2(QT) and v is the unit normal vector outward to 80..

Chapter 4

De Giorgi Iteration and Moser Iteration

This chapter is devoted to a discussion of properties of weak solutions. Two powerful techniques, the De Giorgi iteration and the Moser iteration, are introduced, which can be applied not only to linear elliptic and parabolic equations in divergence form, but also to quasilinear equations, not only to the estimate of maximum norm, but also to the study of other properties, such as regularity of weak solutions. In order to expose the basic idea and main points of these techniques in a limited space, we confine ourselves basically to Poisson's equation and the heat equation, and apply the techniques merely to the estimate of maximum norm of weak solutions.

4.1

Global Boundedness Estimates of Weak Solutions of Poisson's Equation

In this section we illustrate the De Giorgi iteration by applying it to the estimate of maximum norm of weak solutions for Poisson's equation. 4.1.1

Weak maximum equation

principle

for solutions

of

Laplace's

Definition 4.1.1 Let u G Hl{1H). The least upper bound and the greatest lower bound of u on 0, and dQ, are defined as supu = inf{/; (u — /)+ = 0, a.e. in Q,}, supu = inf {7; (u — l)+ S

HQ(Q)},

dU

inf u = — sup(—u), inf u = — sup(—u), n an n an 105

106

Elliptic and Parabolic

Equations

where s+ = max{s,0}. In case u is continuous on Q, the definition of supu, inf u and supu, n n an inf u coincides with the usual one. For sup u and inf u, this is obvious and an (f n for sup u and inf u, this follows from the discussion of the trace of functions an

9Q.

in Hl(Sl) (see §1.5). Let Cl c M.n be a bounded domain. Consider Laplace's equation - A u = 0,

xeCl.

(4.1.1)

Let u e iJ x (fi) be a weak solution of Laplace's equa-

Proposition 4.1.1 tion (4.1.1). Then

supu < supu. n an Proof.

By the definition of weak solutions, u satisfies

/ Vu-V
(4.1.2)

JQ

for any tp £

CQ°(Q)

and hence for any ip €

any k > I, (u — k)+ £

HQ(CI).

Set I = supu. Then for an From Proposition 1.3.10 of Chapter 1,

!

du dx~' 0,

HQ(Q).

., l

, >

' if tx < fc.

Choosing (p = (u — k)+ in (4.1.2) gives 2

/ |V(u-fc)+| da; = 0. /n Jo.

Thus from Poincare's inequality (Theorem 1.3.4 of Chapter 1), we obtain / \(u - k)+\2dx < n f |V(u - k)+\2dx = 0,

Jo.

Jn

where y. > 0 is the constant in Poincare's inequality, which implies (u — k)+ = 0, or u < k a.e. in Q.. Thus the conclusion of the proposition follows from the arbitrariness of k > I. • Corollary 4.1.1 (4.1.1). Then

Let u G if 1 (£2) be a weak solution of Laplace's equation inf u > inf u. n an

De Giorgi Iteration and Moser

Iteration

107

Choosing functions of the form (u — k) + as test functions to derive the estimate of maximum norm is an important technique in establishing a priori estimates. However, the argument as simple as above cannot be used to the same estimate for general equations, even Poisson's equation. For such equations, instead, one has to proceed by means of some iteration techniques, among them is the De Giorgi iteration introduced in the following. 4.1.2

Weak maximum equation

principle

for solutions

of

Poisson's

Lemma 4.1.1 Let ip(t) be a nonnegative and nonincreasing function on [fco,+oo), satisfying

ip(h) < ( ^ — J

[¥>(*)]", Vh>h>k0

(4.1.3)

for some constants M > 0, a > 0, (3 > 1. Then there exists d > 0 such that (fi(h) = 0 , Proof.

V/i > fc0 + d.

Set ks = k0 + d- —,

s = 0,1,2, •••

with constant d > 0 to be determined. Then from (4.1.3) we obtain the recursive formula V(ks+i)<

j

a

[
(s = 0 , 1 , 2 , . . . ) .

(4.1.4)

From this we can prove, by induction, ¥>(*.) <

^

(s = 0 , 1 , 2 , . . . )

(4.1.5)

with constant r > 1 to be chosen. Once this is proved, letting s —> oo then derives ip(ko + d) = 0 and the conclusion of the lemma by the nonincreasingness of Q r ^ 0 V(k3+1) < [
108

Elliptic and Parabolic

Now we choose r = 2a/^~1\

Equations

Then

¥>(fc.+i) < ^

^

Hh)f

[f{ko)f-1

< 1,

'-

Prom this, we see that if d > 0 satisfies Ma2a/9/(/J-l)

Ta

i.e.

then (4.1.5) is also valid for s replaced by s + 1.

•

Now we turn to Poisson's equation -Au = f(x),

xen.

(4.1.6)

Theorem 4.1.1 Let f € L°°(fi) and u £ i7 1 (fi) be a weak solution of Poisson's equation (4-1-6). Then s u p u < supu + C||/|| L oo(m, n an w/iere C is a constant depending only on n and CI. Proof.

By the definition of weak solutions, u satisfies / Vu • Vipdx = / fipdx Jn Jn

for any ip £ CQ^(Q) and hence for any

I in the an above identity. Then we obtain / \SJ
/ \tp\Pdx Jn /


Jn

\f
(4.1.7)

De Giorgi Iteration and Moser Iteration

109

where the constant C depends only on n and si and

{

+00,

n = l,2,

In other words 2/P

f

\
>A(k) jA(k)

' ~ f
/I

' IX, \f
where A(k) = {x e fi;u(x) > fc}. Prom this, using Holder's inequality

/

\
\f
./Ac*:)

\v,4(it)

y

If

|/|«dx)

\-/>i(fc)

,

y

where 9 is the conjugate exponent of p, i.e.

i + i-i. P

Q

we obtain M ' d x \)

(/"

V-^w

y

i/p

< C (/ /

l/l'efa]\

v^(fc)

1/9

.

(4.1.8)

y

Since h > k implies A(h) C A(k), and (p> h — k on A(h), we have /

Mpdi> /

|^|p^>(/i-fc)p|^(/i)|,

where, as before, \E\ denotes the measure of E. This combined with (4.1.8) gives (h-k)\A(h)\1'p, i.e.

\A{h)\<(CU^~W)YlA{k)lv/<,.

110

Elliptic and Parabolic

Equations

Since p > 2 implies p > q, from Lemma 4.1.1 we obtain \A(l +

d)\=0,

where

^=C||/|| L ~ ( n)|^(0l (p_< ' )/(p9) 2 p/(p - 9)
« < i + c|n|^-«)/^2"/<"-«)||/|| L =o (n) .

n Corollary 4.1.2 (4.1.6). Then

Lei / € L°°(0) and u £ /f 1 (fi) be a weafc solution of

infu>infu-C||/||Loo(n), where C is a constant depending only on n and 0 . The De Giorgi iteration technique can also be applied to more general elliptic equations in divergence form. For instance, for the slightly general equation - A u + c(x)u = f(x) + divf(x),

ie(l,

(4.1.9)

we have Theorem 4.1.2 Assume that p > n > 3, 0 < c(x) < M, f € L p *(fi), / £ L p (fi;R") andu £ iJ1(f2) is a weak solution of equation (4-1.9). Then supu < s u p u + + C (||/||LP.(n) + ||/1lLP(n)) | f i | 1 / n " 1 / p , inf u >mf u_ - C (||/||LP. (n ) +

||/||L^))

|0|1/n"1/p,

where p* = np/(n + p), s_ = min{s,0} and C is a constant depending only on n, p, M and Q, but is independent of the lower bound of |fi|. For the proof we leave to the reader.

111

De Giorgi Iteration and Moser Iteration 4.2

G l o b a l B o u n d e d n e s s E s t i m a t e s for W e a k S o l u t i o n s of the Heat Equation

In this section we apply t h e De Giorgi iteration technique t o t h e estimates of maximum norm for weak solutions of t h e heat equation.

4.2.1

Weak maximum principle geneous heat equation

for

solutions

of the

homo-

Definition 4.2.1 L e t u e W2hl(QT), where QT = ftx(0,T) with ft C W1 being a bounded domain. Define t h e least upper b o u n d and t h e greatest lower b o u n d of u on QT and dpQr as s u p u = inf{Z; (u — l)+ = 0, a.e. in

QT},

QT

sup u = inf{/; (u - l)+

eW2'

(QT)},

dpQr inf u = — sup(—u), QT QT

inf u — — sup (—u). dpQT dpQT

First consider t h e homogeneous heat equation flit

^ - A u = 0,

(x,t)eQT-

(4.2.1)

P r o p o s i t i o n 4.2.1 Let u £ W2' (QT) be a weak solution neous heat equation (4-2.1). Then

of the

homoge-

s u p u < sup u. QT

Proof.

BVQT

By the definition of weak solutions, u satisfies //

(ut

) dxdt = 0

(4.2.2)

JJQT

o for any ip &C°°(QT)

°1 1 and hence for any

(QT)-

Set I = sup u and 9VQT

choose (p = (u — k)+ with k > I. T h e n

CWl'^Qr).

112

Elliptic and Parabolic Equations

Substituting

(u - k)t(u - k)+dxdt +

JJQT

W(u-k)-V(u-k)+dxdt

= 0,

JJQT

i.e.

- if

—(u-k)%dxdt+

IQT

\V(u-k)+\2dxdt

[J

Ul

= Q.

JJQT

Thus, we obtain from Lemma 3.1.2 of Chapter 3, \

I (u(x, T) - k)\dx - \ \ (7((u(ar, 0) «/ 12

k)+))2dx


+ ff

2

\\7(u-k)+\ dxdt = 0.

JJQT 'QT

Since by Corollary 1.5.6 of Chapter 1, / ( 7 ( K a ; , 0 ) - f c ) + ) ) 2 d a ; = 0, we have \V(u-k)+\2dxdt<0.

// JJQT

Combining this with Poincare's inequality, we further obtain //

(u - k)\dxdt

|V(u - k)+\2dxdt < 0,

< M//

JJQT

JJQT

where /x > 0 is the constant in Poincare's inequality. Hence u(x,t) < k a.e. in QT and the conclusion of the proposition follows from the arbitrariness of k > I.

D

Corollary 4.2.1

Let u G W^iQr)

be a weak solution of (4-2.1). Then

inf u > inf u. QT

4.2.2

9PQT

Weak maximum principle for solutions mogeneous heat equation

of the

nonho-

Now we turn to the nonhomogeneous heat equation ^ - A u = f(x,t),

(x,t)€QT.

(4.2.3)

De Giorgi Iteration and Moser

Iteration

Theorem 4.2.1 Let f £ L°°(QT) and u £ W2' (QT) of the nonhomogeneous heat equation (4-2.3). Then

113

be a weak solution

s u p u < sup u + C||/|| L < »(Q r ) , QT

9PQT

where C is a constant depending only on n and il. Proof.

Denote sup u = 1. For k > I and 0 < t\ < t2 < T, we have

(u — k)+X[t1,t2] GWV (QT), where X[ti,t2]W 1S ^e characteristic function of the interval [ t i , ^ ] . Thus we may choose tp as a test function in the definition of weak solutions (see Remark 3.1.2 of Chapter 3) to obtain //

(u-k)t(u-k)+X[t1,t2]dxdt+

//

JJQT QT

JJc 'QT

X[ tl ,t 2 ]|V(u -

k)+\2dxdt

JJQT JJQT

f(u-k)+X[tut2\dxdt.

Hence 2o

/ H (u-k)2+dxdt+ Jti dt Jn

/ Jti

/ Jn

\X7(u-k)+\2dxdt

< 1^ I \f\(u-k)+dxdt, Jti

i.e.

Jn

\(ik(t2) - Mil)) + r i iv(u - k)+\2dxdt 1

Jti

Jn

< [* I \f\(u - k)+dxdt, Jti

Jn

where Ik(t)=

/(u-k)\dx. Jn

Assume that the absolutely continuous function Ik(t) attains its maximum at a e [0,T]. Since Jfe(0) = 0, h(t) > 0, we may suppose a > 0. Taking ti = a — e, t2 = o with e > 0 small enough so that a — e > 0 and noticing that

h(°) - h(°-~ s) > 0,

114

Elliptic and Parabolic Equations

we obtain f |V(« - k)+\2dxdt < f

f

J<7—£ JQ

f \f\{u - k)+dxdt.

J a—E JQ

Thus it follows from - / e

/ l v ( u - k)+\2dxdt <- f £

Jcr-e Jfl

[ \f\(u - k)+dxdt

J as

JQ,

by letting e —> 0 + that / \V{u(x,a)-k)+\2dx

< / \f(x,a)\(u(x,a)

JO.

- k)+dx.

JO.

This is an analog of (4.1.7) with (p = (u — k)+ obtained for Poisson's equation. Having this in hand, we may process as in the proof of Theorem 4.1.1 to establish the desired estimate. To this end, denote Ak(t) = {x;u(x,t)>

k},

\ik = sup \Ak(t)\. 0
Then, similar to the derivation of (4.1.8), we may deduce (u-k)p+dx)

(/ \JAk(cT)



[

\f\"dx)

\JAk(cr)

< C||/|| L ~ (QT)/ i fc 1/9 ,

)

where +oo, 2
2n

U-2

n = 1,2, n>3,

Q

P-1'

Applying Holder's inequality to Ik(a) and combining the result with the above estimate, we are led to h{°) <( [ (« - kf+dx J \JAk(a) J

\Ak(a)\^-^p

<(cn/ik~(Q T) ) 2 /4 3p - 4)/p . Hence, for any t € [0, T], /*(*) < hi*) < (C\\f\\L~(QT))2tfp-i)/p.

(4.2.4)

De Giorgi Iteration and Moser Iteration

115

Since for any h > k and t £ [0, T],

(u - k)2+dx >(h- k)2\Ah(t)\,

h(t) > f JAh(t) from (4.2.4) we obtain

(h-k)W<(C\\f\\L^QT))2^4)/p, i.e.

(C\\f\\ L^iQrA

(3p-4)/p

Using Lemma 4.1.1 and noticing that p > 2 implies P

P

we finally arrive at /xj+d = sup \Ai+d(t)\ = 0 , 0
^cifil 1 - 2 /^^- 4 )/^- 4 )!!/!!^^). This means, by the definition of A(k),

uKl + ClQf-V^-W^Wfh^Q^, Corollary 4.2.2 of (4.2.3). Then

Let f £ L°°(QT)

}?*"-/>"# QT

a.e. i n Q r .

Q

and u £ W^' ( Q T ) &e a weofc solution

U-C

1I/IU~(QT).

OPQT

where C is a constant depending only on n and 0 . The De Giorgi iteration technique can also be applied to more general parabolic equations in divergence form to establish the weak maximum principle. For instance, for the equation du -* — -Au + c(x,t)u = f(x,t)+divf(x,t), we have

(x,t)eQT,

(4.2.5)

116

Elliptic and Parabolic

Equations

Theorem 4.2.2 Assume p > n > 3, 0 < c(x,t) < M, f e L°°(0,T;LP'(D.)), fe Loo(0,T;IA'(Q,Rn)), and u € W\<X{QT) is a weak solution of equation (4-2.5). Then supu< supu+ + c f QT

dpQT

mfu> QT

inf u . - c ( OPQT

sup | | / | | i , . ( n ) + sup ||/|U P (n)) M 1 / n _ 1 / p , \0
0
/

sup | | / | | L , . ( n ) + sup ll/IU^n) V | 1 / n - 1 / p , \0
0
J

where p* = np/(n+p) and C is a constant depending only on n, p, M and Cl, but is independent of the lower bound of |fi|. The proof is left to the reader. Remark 4.2.1 Among the assumptions of Theorem 4-2.2, c(x,t) > 0 is not necessary. If we replace this condition by \c(x,t)\ < M for some constant M, then the same estimates hold, but the constant C depends on T in addition to n, p, M and Q. In fact, under such condition, we may introduce a new unknown function w = e _ A t u with A > 0 to be determined and change equation (4-2.5) into ^ - Aw + (A + c)w = e - A t ( / + div/). at If we choose A = ||c||i,°o(Qr), then A + c(x,t) > 0 and thus the conclusion of Theorem 4-2-2 can be applied to the new equation to obtain the desired estimate.

4.3

Local Boundedness Estimates for Weak Solutions of Poisson's Equation

Another important technique in estimating the maximum norm of solutions is the Moser iteration. In this section, the main points of this technique will be illustrated by applying it to Poisson's equation in establishing the local boundedness estimate of weak solutions. 4.3.1

Weak subsolutions

(supersolutions)

In order to further discuss the local boundedness of weak solutions of Poisson's equation, we introduce the concept of weak subsolutions (supersolutions) of equation (4.1.9).

De Giorgi Iteration

and Moser

Iteration

117

Definition 4.3.1 A function u € H1^) is said to be a weak subsolution (supersolution), if for any nonnegative function

) / (fipdx - / • V(p) dx. Sometimes the weak subsolution (supersolution) is said to be a function in if 1 (fi) satisfying -Au + c(x)u < (>)/(x) + div/(x) in the weak sense. Proposition 4.3.1 Assume that f = 0, / = 0, c(x) > 0 andu e if 1 (f2)n L°°(Q) is a weak subsolution of equation (4-1.9). If g"(s) > 0, g'(s) > 0, 3(0) = 0, then w = g(u) is also a subsolution of equation (4-1.9). Proof. By the definition of weak subsolutions, for any nonnegative function tp G Cg°(fi), / (Vu • Vy> + cwp)dx < 0. n Since g'(s) > 0 and u <E tf^fi) n L°°(D,), we have 0 < g'{u)

+ g"(u)\Vu\2

Jn

g"(u)\Vu\2
< / c{g{u) Jn

ug'(u))ipdx.

Here we have used the condition g"(s) > 0. To prove that w = g(u) is a subsolution of (4.1.9), besides c > 0, cp > 0, it suffices to note that 5(0) = 0 and g"{s) > 0 imply g(s) - sg'(s) < 0,

Vs e R. D

118

Elliptic and Parabolic

Equations

Remark 4.3.1 Conditions g"(s) > 0 and g'(s) > 0 in Proposition 4-3-1 can be replaced by that g(s) is a nondecreasing convex Lipschitz function; a typical example is g(s) = sp+,

seR

(p>l).

We leave the proof to the reader. 4.3.2

Local boundedness estimate Laplace's equation

for

weak

solutions

of

Theorem 4.3.1 Let x° & Q, BR = BR(x°) Cfl andut H1 (SI) n L°°(0.) be a weak subsolution of Laplace's equation (4-1.1). Then 1/2

— uu2+,tdx sup u < C I — —/ R n BR,2 \ JBR

where C is a constant depending only on n. Proof. Prom Proposition 4.3.1, we see that u+ is also a weak subsolution of Laplace's equation (4.1.1). So we may assume u > 0. The proof will be proceeded in three steps. Step 1 Prove the inverse Poincare's inequality, namely, for any p > 2, r)2\Vup'2\2dx

f

up\Vn\2dx,


JBR

(4.3.1)

JBR

where rj(x) is the zero extension of a cut-off function on Bp>, relative to Bp (0 < p < pf < R), namely, rj € C$>(Bp,), 0 < n(x) < 1, n(x) = 1 on Bp, r](x) = 0 on Cl\Bp> and \S7n(x)\ < — 2 p_1

Choose 7y u Then

.

as a test function in the definition of weak subsolutions.

/ Jn

Vu-V(n2up-l)dx<0,

or (p-l)

f

n2up-2\Vu\2dx

riup-lVu

+2 J

J BR

J

• Vrjdx < 0.

BR

Hence ^ ^ P

/ JBR

ri2\Vup/2\2dx

+ f JBR

r)up'2Vup/2

• Vrjdx < 0.

De Giorgi Iteration and Moser Iteration

119

Since using Cauchy's inequality with e gives /

r,up'2^up'2

JBR

r)2\Vup/2\2dx

-S/r]dx<^ 2 [

+ 2e l-

JBR

up\Wr]\2dx,

[ JBR

(4.3.1) can be obtained by choosing e > 0 small enough. Step 2 Prove the inverse Holder's inequality, namely, for any p > 2,

i-zn

[

\R JBp

upqdx)


)

* n 2

r= f

,

updx),

2

~ \R - (p -p) JBl>,

J

(4.3.2) y

'

where +oo,

n = 1,2,

1
n . n-2'

n > 3.

Prom Remark 1.3.6 of Chapter 1, we have / , , \1/(2<j) / , _L/ rpundx] U
\i/(2g) W'2)*>dx\ \V{riup/2)\2dx\

,

or

where C is a constant depending only on n. On the other hand, using the inverse Poincare's inequality gives / \V(r]up/2)\2dx J BR

= f \r)Vup'2 + J BR <2 [

r]2\Vup/2\2dx

JBR


Therefore (4.3.2) holds. Step 3 Iterate.

up/2VV\2dx +2 [ JBR

p

2

u |Vry|

up\Vr)\2dx

120

Elliptic and Parabolic

Equations

Denote

and choose p = 2qk, p = pk+i, p' = pk in (4.3.2). Then \

„

i/(2gfc+1)

\u\2"k+1dx

.

RnJB.

/

N V<2«*>

Iterating repeatedly leads to /

i

\1/{2qk+1)

/•

S i r

\ V2

where OO

-

OO

fc

2o '

^

^

fc + 2 2o f c '

Since 9 > 1 implies the convergence of these series, a, (3 are both finite numbers. Thus for some constant C depending only on n, v l/(29fc+1)

/

1/2

Prom this the desired conclusion follows by letting k —• oo. 4.3.3

Local boundedness equation

estimate

for solutions

of

• Poisson's

Now we turn to equation (4.1.9) with / = 0, namely, -Au + c(x)u = f(x),

xGfi.

(4.3.3)

Theorem 4.3.2 Let 0 < c(x) <M, f G L°°(ft) and u G if 1 (fi)nL°°(n) 6e a weafc subsolution of equation (4-3.3). Then there exists a constant Ro > 0 depending only on M, such that for any x° G Cl, there holds supu
V-"

JBR

u2dx)

+C||/||Loo(n), J

De Giorgi Iteration and Moser Iteration

provided 0 < R < R0 and BR = BR(X°) depending only on n, RQ and M. Proof.

121

C Q, where C is a constant

For any x° e £1, denote u(x) = u(x) + \x- z°| 2 ||/|| L =c(n),

x € ft.

Then, in the weak sense — Au + cu 2n||/|| L oo ( n ) +cu + c\x - x°| 2 ||/||L°°(fi)

= -Au-

0 such that RQ < ——-.

in SI.

Then, in the weak sense,

-Au + cu<0,

mQr\BRo(x°),

namely, u is a weak subsolution of equation —Av + cv = 0 in Q D By Proposition 4.3.1, u+ also satisfies - A u + + cu+ < 0,

BR0(X°).

in Q, n Bfl0 (x°)

and hence mQ,nBRo(x0)

-Au+<0,

in the weak sense, namely, u+ is a weak subsolution of Laplace's equation in fi n jBfl0(a;0). Thus, from Theorem 4.3.1, we obtain \l/2

sup i p u+ u++ <
Ban ~ BR

WJBJ

z2 \u+\ dx ] + do

'

J

,

and hence the conclusion of the theorem follows.

0 < R < Ro •

R e m a r k 4.3.2 What we have adopted to establish the local boundedness estimates in Theorem 4-3.1 and Theorem 4-3.2 is the so-called Moser iteration technique, a technique of extreme importance. The method is based on the fact IMU°o = lim

\\U\\LP-

122

Elliptic and Parabolic

Equations

The basic idea in establishing the boundedness estimates is to choose suitably Pk and pk such that po = R, lim pk = R/2 and lim pk = +00, and then fe—»oo fe—»oo

try to prove that Ak =

\\u\\L'k(BPk)

satisfies the recursive formula < Ca"Ak

Ak+1 00

with otk > 0 such that the series V J ctk is convergent. fc=o

4.3.4

Estimate Poisson's

near the boundary equation

for

weak solutions

of

All estimates presented above are established in a neighborhood of the interior points of Q. In addition to these interior estimates, we need to establish estimates near the boundary points. As an example, we will do this for a domain of the form Q+ = {x € M.n; |XJ| < 1 (1 < i < n),xn > 0}. For general domains, we may transform the neighborhood of the boundary point to a domain of this special form by means of local flatting of the boundary. Of course, after a local flatting transformation, the shape of the equation will be changed. Theorem 4.3.3 Assume that 0 < c(x) < M, f £ L°°(Q+) and u € H1(Q+) n L°°(Q+) is a weak subsolution of equation (4-3.3) with trace vanishing on the bottom of Q+, i.e. ju(x\,--,a;„_i,0) = 0. Then there exists a constant Ro £ (0,1] depending only on M, such that for any point x° on the bottom of Q+,

sup u
R/2

u2dx\

I \

R

+C||/||L~(Q+), /

provided 0 < R < RQ and B^ = B+(x°) C Q+, where B^(x°) = BR(x°) n {x s Rn;xn > 0} and C is a constant depending only on n, Ro and M. The proof is similar as the one of Theorem 4.3.2. We leave it to the reader.

De Giorgi Iteration and Moser

4.4

Iteration

123

Local Boundedness Estimates for Weak Solutions of the Heat Equation

In this section, we use the Moser iteration technique to the local boundedness estimates for weak solutions of the nonhomogeneous heat equation. 4.4.1

Weak subsolutions

(supersolutions)

We first introduce weak subsolutions (supersolutions) of equation (4.2.5). Definition 4.4.1 A function u G W^iQr) is said to be a weak subsolution (supersolution) of (4.2.5), if for any nonnegative function

) / / JJQT

(ftp - f-

JJQT^

Vip)dxdt. '

Sometimes, a weak subsolution (supersolution) u of (4.2.5) is said to be a function satisfying OVL

~*

— - Au + c(x, t)u < ( > ) / ( ! , t) + div/(x, t) in the weak sense. Proposition 4.4.1 Assume that f = 0, / = 0, c(x,t) > 0 and u G W 2 1 ' 1 (gr)nL 0 0 (Qr) is a weak subsolution of (4.2.5). Ifg"(s) > 0, g'(s) > 0 and g(0) = 0, then g(u) is also a weak subsolution of (4-2.5). The proof is similar to the elliptic case (see Proposition 4.3.1). R e m a r k 4.4.1 Conditions g"{s) > 0 and g'(s) > 0 of Proposition 4-4-1 can be replaced by that g(s) is a nondecreasing convex Lipschitz function; one of the typical cases is g(s) = sp+, 4.4.2

seR

(p>l).

Local boundedness estimate for weak solutions homogeneous heat equation

of the

T h e o r e m 4.4.1 Let (x°,t0) G QT, QR = QR(x°,t0) = BR(x°) x {t0 R2,t0 + R2) C QT and u G Wl'1(QT) n L°°(QT) be a weak subsolution of

124

(4-2.1).

Elliptic and Parabolic

Equations

Then

ST~C(n^l/dxdt)"2 with C depending only on n. Proof. Similar to the discussion for Poisson's equation, we proceed in three steps. Step 1 Derive an estimate similar to the inverse Poincare's inequality. For any p, p' such that R/2 < p < p' < R, choose a cut-off function rj(x) on Bpi, relative to Bp, namely, n G CQ°(BP>), 0 < n(x) < 1, r](x) = 1 on Bp, and |V^(x)| < — 2

and extend 77 to be zero for x G Q\Bpi. For

2

any s G (to — P ,h + R ), choose £ G C°°(—00, s], such that £(t) = 1 on [t0 - p2,s], £(t) = 0 on (-00, t 0 - p'2] and 0 < C(t) < —

^ for t < s,

(P - P)

and extend it to be zero for t > s. We may assume that u > 0; otherwise we use u+ instead of u. Choose ip = £2n2u as a test function in the definition of weak subsolutions to obtain {ut£"n2u + Vu • V ( £ V u ) ) dxdt < 0,

// JJQT IQ

namely,

Wt{ev2u2)dxdt~U s ti'^dxdt

\jj. p'

p'

2

+ if

tW\Vu\ dxdt

+ 2 if

*
u^nVu

• Vrjdxdt < 0,

pi

where Qp = Bp x (to - p2,t).

Since f (t) = 0 at t = t 0 - p' , we have

[f ±L(Z2r,2u2)dxdt = f JJQ* or JB

ZWu2

t=s

dx.

Using Cauchy's inequality with e gives u£2rjVu • Vrjdxdt

2 // p'

<--If ~2

Z2r,2\Vu\2dxdt

+ 2 ff

Z2u2\Vr)\2dxdt.

125

De Giorgi Iteration and Moser Iteration

Hence \

[

£ W

<- ff tW\Vu\2dxdt 2 JJQp <\ 2

er?\Vu\2dxdt

dx+ [[

yjQ',

, (.P

JJQS^

C _

tt'r}2u2dxdt

ff

JJQ^

£2ri2\Vu\2dxdt+

ff

£2u2\Vr)\2dxdt+

+ 2 //

u 2 dxdi.

// P) .A/Q',

Therefore /•

sup

to-p2
C_ <, . ^ xo / / '{P'-PYJJQ JJQj

/

r)2u2(x,t)dx+

rto+P

r

/

/

Jto-p2

T72|Vu|2dxdt

JBp,

u2da:eft.

S t e p 2 Derive an estimate similar to the inverse Holder's inequality. Let x ( 0 be the characteristic function of the segment [to — p2,to + 2 p }. Then x{t)rlu G V^Q/j) and by the t-anisotropic embedding theorem (Theorem 1.4.2 of Chapter 1),

wt) )2w

(sw/ 0 „ '" 'r
sup

+ IJ =C{n)R7n(

JBR

\X(t)V(Vu)\2dxdt).

sup

rto+P

r)2u2(x,t)dx

/

^t0-p2
+ /

(x(t)7?u(a:,t))2dx

/

^t0-R2
JB-i r

/

.

\r]Vu +

where 5/3,

n = l,2,

1 + 2/ra,

n > 3.

uVr)\2dxdt),

126

Elliptic and Parabolic

Equations

Using the inequality obtained in Step 1, we further deduce 1/9

'Qt

j

Dn+2

JJ {X{t)rjufdxd^
sup V *o-p2
+ /

/

Jto-p2 n


r?u2{x,t)dx

/ JBp,

.

uVri\2dxdt)

\r]Vu +

JBp,

'

sup

rj2u2(x,t)dx

/

^t0-p2
JBp, 2

fto+p2

2

+ 2/ / n \Wu\ dxdt + 2 / Jto-p2 JB„,2 Jt0-p2

< „ _n , ^

— //

R {p'-P)2 JJQ P

U dl^.

/•

/ JB„,

.

u2\Vn\2dxdt) '

Proposition 4.4.1 shows that u 9 is also a weak subsolution of (4.2.1). So with uq in place of u, we obtain from the above inequality, x l/2qk+1

/

/

v

l/2qk

Step 3 Iterate. Similar to the case of Poisson's equation.

4.4.3

•

Local boundedness estimate for weak solutions nonhomogeneous heat equation

of the

Now we turn to equation (4.2.5) with / = 0, namely, Qu

— -Au

+ c(x,t)u = f(x,t),

(x,t)GQT.

(4.4.1)

Theorem 4.4.2 Let \c(x,t)\ < M, f £ L°°(QT) and u £ W 2 M (Qr) f~l L°°(QT) be a weak subsolution of (4-4-1)- Then for any (x°,to) € QT and

De Giorgi Iteration and Moser Iteration

127

R > 0 such that QR = QR{X°, t0) C QT, 1/2

sup u
U u22dxdt^j dxdt }

IJ/I

+C||/||LOOWT)

QR/2

with C depending only on n, M and T. Proof.

Let w(x,t) = e~Mtu(x,t),

(x,t)eQT-

Then, in the weak sense, w satisfies ^ - Aw + (M + c)w = e-Mt at

(^-Au \at

+ cu]< )

e~Mtf,

in QT.

So, without loss of generality, we may assume that c(x, t) in (4.4.1) satisfies 0
in QT-

Then, in the weak sense, u satisfies &&

A—

— at =

—

Au + cu

dit

~di ~Au + cu~ H/IU~(QT) _ ct\\f\\L^(QT) = / - II/IU»(QT) - CtWfh^iQr) <0,

in QT,

namely, u is a weak subsolution of (4.4.1) with / = 0. So s-i

—^- — Au+ + cu+ < 0,

in QT

(so

and hence — - Au+ < 0, dt

in QT,

namely, u+ is a weak subsolution of (4.2.1) in QT- Thus, from Theorem 4.4.1, we have

ss^-c(^LMdx)

128

Elliptic and Parabolic

Equations

Hence 1/2

sup u < C ( - L j f V- 0,

QR/2

u2dx)

JQR

+ C||/||L-(QT).

/

• Similar to the case of Poisson's equation, we can further establish the estimate near the boundary for the heat equation.

Exercises 1. Prove Theorem 4.1.2. 2. Let A > 0, n C R" be a bounded domain, / G L°°(fi) and u G HQ(Q) n L°°(fi) be a weak solution of - d i v ( ( u 2 + A)Vu) +u = f,

iefi.

i) Use the De Giorgi iteration technique to establish the maximum norm estimate for u; ii) Whether the maximum norm estimate holds in case A = 0? 3. Prove Theorem 4.2.2. 4. Let 0 C t n be a bounded domain, p > 2 and / G L°°(QT)Consider the first initial-boundary value problem for p-Laplace's equation — - divfl V u r 2 Vu) = / ,

(x, i ) G Q r = O x (0, T),

= 0. dPQx

i) Define weak solutions of this problem and prove the existence and uniqueness; ii) Use the De Giorgi iteration technique to establish the maximum norm estimate for weak solutions of the problem. 5. Prove Remark 4.3.1. 6. Prove Theorem 4.3.3. 7. Let Q C K n be a bounded domain and u G L°°(Q). Show that IMU~(n) = limJ|u|| L P (n).

De Giorgi Iteration and Moser

8. Let u\ and U2 € HQ(Q) ^>e a of Poisson's equation

wea

—Au = / ,

Iteration

129

k solution and a weak subsolution i£fi,

where Q C R" is a bounded domain and / € L2(Q,). Show that ui(x) > U2{x),

a.e. x € £1.

9. Prove that u £ W2' (QT) is a weak solution of the equation — -Au

+ c(x,t)u = f,

(x,t)eQT

=

flx(0,T)

if and only if u is both the weak supersolution and the weak subsolution of the equation, where fi C W1 is a bounded domain, c S L°°(QT) and 2 / G L (QT). 10. Prove Proposition 4.4.1 and Remark 4.4.1. 11. Let u G W2' (QT) n L°°(QT) be a weak solution of the equation

W " div ( ( ^ r l ) V u )

+

<X^U

= *> ( x '*) e gr = fi x (°'T)

where Q. C R" is a bounded domain, c £ L°°(QT) and / € L2(QT). Use the Moser iteration technique to derive the local boundedness estimate for u. 12. Use the Moser iteration technique to derive the local boundedness estimate near the boundary for weak solutions of the heat equation.

Chapter 5

Harnack's Inequalities

In this chapter, we continue our study of properties of weak solutions, we will concentrate our attention on Harnack's inequalities which reveal deeply the properties of solutions of elliptic and parabolic equations. Such kind of inequalities hold not only for general linear elliptic and parabolic equations in divergence form, but also for quasilinear equations (see Chapter 10). However, we merely illustrate the argument for the simplest equations such as Laplace's equation and the homogeneous heat equation, although the basic idea is available to general linear and quasilinear equations.

5.1

Harnack's Inequalities for Solutions of Laplace's Equation

In this section, we are concerned with Laplace's equation x£Rn.

- A u = 0, 5.1.1

Mean value

(5.1.1)

formula

Theorem 5.1.1 Let u € C2(Rn) ball BR = BR{y) C R n , u

(y) =~

be a solution of (5.1.1) Then for any

u x

^T=T / n

l

nunR

( )ds,

(5.1.2)

J9BR

(5.1.3) u(y) =—5^

/

u(x)dx,

where un is the measure of the unit ball in M.n. 131

132

Proof.

Elliptic and Parabolic Equations

Integrating (5.1.1) over the ball Bp = Bp(y) with p € (0, R) gives /

IB0 JB„

Audx = I/ Tr^ds — 0, JdB Jdi B du

where v denotes the unit normal vector outward to dBp. Introduce the polar coordinate p=\x — y\,z = x-y Then from the above formula, we have, with u = u(x) = u(y + pz), 0

dv

Jdi IdB,

-L

d_u(y + pz)ds aBp(o) dp d_u(y + u)ds (0) dp

7

JdBx d

„ n - i'— =p-

dp

/

u(y + u)ds

JdB^o)

p1

dp

n

u(y + pz)ds JdBp(0)

Hence pl~n

( u(y + pz)ds =R1~n I u{y + Rz)ds JdBp(o) JdBR(.o) =i?1-" / JdBR

u(x)ds.

Sending p —• 0 + and noting lim pl~n P-+0+

/

u(y + pz)ds =

nunu(y),

JdBp(0)

we then derive (5.1.2). Since (5.1.2) holds for any R > 0, we have ncjnpn~1u(y)

= / u(x)ds, JdBp

Integrating over (0,-R) with respect to p then gives (5.1.3).

•

Harnack's Inequalities

5.1.2

Classical

Harnack's

133

inequality

Theorem 5.1.2 Let u € C 2 (R n ) be a nonnegative solution of (5.1.1). Then for any ball BR = BR(y) C M.n, sup u < C inf u, B

R

BR

where the constant C depends only on n. (In fact, we may take C = 3n). Proof.

For any x1, x2 G BR(y), BR{xl)

c B2R(y) C

B3R(x2).

Using the mean value formula, we have ufx1) = — — - /

u(x)dx

<—— / u(x)dx unRn 7s 2R ( y ) <'—^-

/

u(x)dx

=3nu(x2). The desired conclusion then follows from the arbitrariness of x 1 and x2. O We have proved Harnack's inequality for classical solutions of Laplace's equation. In fact, such kind of inequality also holds for weak solutions. To prove, we proceed in several steps. 5.1.3

Estimate

of sup u Ben

Lemma 5.1.1 Let 0 < To < T\ and
for any t, s such that TQ < t < s < T\, where 9 < 1, A, B and a are nonnegative constants. Then

^-

C

((fl-p)«

+ g

)'

r0
where C is a constant depending only on a and 9.

134

Proof.

Elliptic and Parabolic

LetT0
Equations

Denote

ti+1=U

+ 0--T)Ti(R-P)

(t = 0 , l , " - )

with r G (0,1) to be specified. By assumptions of the lemma, we have

^)<Wti+i)+{{1_T)Ti{R_p))a+B,

i = 0,l,....

For any integer k > 1, iterating gives

rtto) < *
|>-.)«.

The desired conclusion follows by choosing r such that Qr~a < 1 in the above inequality and sending k —> oo. • Theorem 5.1.3 Let u G Hioc(M.n) be a bounded weak subsolution of (5.1.1). Then for any p > 0 and 0 < 6 < 1, 1/p

s u p u ^ c f - z j - r / (u+) p dx) Ben Vl-Dfll VB H / where C is a constant depending only on n, p and {1 — 0)- 1 Proof. From Proposition 4.3.1 of Chapter 4, u+ is also a weak subsolution of Laplace's equation (4.1.1). Hence, we may assume that u > 0. Using Theorem 4.3.1 of Chapter 4 (There we have treated the special case 6 = 1/2; the general case 0 < 9 < 1 can be treated similarly) we can derive the conclusion for p = 2. We can prove the conclusion for p > 2 in a similar way or by using Holder's inequality directly on the conclusion for p = 2. Now we consider the case 0 < p < 2. We first use the result for p = 2 to obtain supu
( f

Bert

\JBR

u2dx\ J

O

r BR

\ 1//2 vPdx) J

and then use Young's inequality with e to derive supw < \ supu + C((l BBR

l

BR

9)R)-n/"\\u\\LP{BR).

,

135

Harnack's Inequalities

Denote (f(s) = sup u and set s — 6R, t = R in the above inequality. Then B,

1 C V(») < gVW + ( t _ 8 )n/pll U H^(gi»)'

0 < S < i < i?.

Thus from Lemma 5.1.1, we deduce the desired conclusion

Checking this proof, we may get that Theorem 5.1.3 still holds if u G Hioc(Rn)

Remark 5.1.1

5.1.4

Estimate

is replaced by

of inf it Ben

Lemma 5.1.2 Let 3>(s) be a smooth function on R with $"(s) > 0 and u G Hloc(Rn) be a bounded weak solution of (5.1.1). Then v = $(u) G Hyoc(Rn) is a weak subsolution of (5.1.1), namely,

J

Proof.

Vu • V < 0,

VO < y> G

C^(Rn).

Ju In fact, for any nonnegative function ip G Co°(R n ), we have /

Vv • Vipdx

JRn

= /

$'(u)Vu • V(fdx

JR*

= [

Vu-V(&{u)
JRn

<; /

f

&'(v)\Vu\2
JRn

Vu • V{$'(u)
JR"

=0.

a

Remark 5.1.2 The smoothness condition for $(s) can be weakened to local Lipschitz continuity. Lemma 5.1.3

Assume that w G L2{B2) and satisfies

( f (v2\w\2h)"dx) \JB2

< C(2h)2h + Ch2 [ J

JB2

(|VT7|

+ r])2\w\2hdx

136

Elliptic

and Parabolic

Equations

for any h > 1 and any cut-off function r] on Bi, where q > 1 and the constant C is independent of h and r\. Then there exists a constant C > 0, such that for any integer m>2, \w\mdx)

< Cm.

Proof. Set hi = qi~1,

S0 = 2,

S i ^ S ^ - y ,

i = 1,2, ••• .

Choose T) to be a cut-off function on Bsi_1, relative to Bst, namely, 77 G C ^ C ^ i - i ) . 0 < r){x) < 1, »j(x) = 1 in BSi and |V??(x)| < 2*C. Then from the assumption of the lemma, we see that 1/9

(L

^dx

< Cq^-W-1

J

\

With It= [ I

+ C{2q)W-V

f

{w^dx.

l/(2
Zq

\w\ 'dx

, we further have

7.
1

)(29)(i-i)/9i-1/._1)

i =

i,

2 )

... .

Iterating then gives Ij < C J ] g*"1 + C Q ' (29)ft Jo,

j = 1,2, • • • ,

i=l J

J 1 ' i— 1 * = where Oj = 5 3 o »_i > &' 5 3 ; - i • Since 5 ^ ^

i=l

9

i=l

9

_ 1

- ^q^, the above

i=l

inequality implies Ij^Cqi+CIo,

j = 1,2, • • - .

From this, noting that for any fixed integer m > 2, there exists an integer j , such that 2qi~1 <m< 2qj, and using Holder's inequality, we have l/m

< CIj
Harnack's

Inequalities

137

Thus, with another constant C independent of m, we finally obtain \w\mdx B1 Lemma 5.1.4

< Cm. J

D n

Assume that w € H^c(R ),

/

w(x)dx = 0 and

JBi

Aw + \Vw\2 < 0,

x e W

in the sense of distributions, i. e. -f

Vw-Vipdx+

\Vw\2
J

V0<
Then there exists a constant p > 0 depending only on n, such that

r (P\w\y JBi

<2~m,

m = 2,3,---.

(5.1.4)

m\

Proof. We proceed in two steps: first prove the conclusion for m = 2, and then use the standard Moser iteration to reach the conclusion for m > 2. Choose ri G C$°(B3) such that 0 < r) < 1, 77 = 1 in B2 and |Vr7| < C and set