Strongly Elliptic Systems and Boundary Integral Equations

O#vEL,,(1) IIVIIL,,(fa) (3.2)

so L . ( 7 ) is isometrically imbedded in the dual of L p (0). In fact, Lp.(S2) = [L p(c2)]*

for 1 < p < oo (but not p = oo);

(3.3)

see Yosida [106, p. 115]. If the (measurable) functions u and v are defined on the whole of R", then we define their convolution u * v by

(u * v)(x) =

r

J

u(x - y)v(y) dy

whenever the integrand belongs to L I (W). Convolution turns out to be a very effective tool for approximating non-smooth functions by smooth ones, a tech-

nique that we shall use repeatedly. The substitution y = x - z shows that (u * v)(x) exists if and only if (v * u)(x) exists, in which case they are the same. Thus, convolution is commutative:

v*u=u*V.

Convolution

59

The following theorem gives simple criteria for the existence of the convolution.

Theorem 3.1 Let 1 < p < oo, 1 < q < oo and 1 < r < oo, and suppose that

-+-=1+-. p q r 1

1

1

(3.4)

If u E LP (lR") and v E Lq (R"), then u * v exists almost everywhere in ]R" and belongs to Lr(]R" ), with

RR" IIu * VIIL,.(R") < II1IIL,(R")

(3.5)

Proof. First note that if p = q = r = 1, then J

J

lu(x-Y)v(y)Idydx= f v(Y)I(fR Iu(x-y)Idx)dY

=f

Iv(Y)IIIuIIL,(R")dy = IIuIIL,(R'1)IIVIIL,(R"),

"

so u * v exists almost everywhere and belongs to L i (]R"), and (3.5) holds. Now let u E La (R"), v E Lq (1R") and 0 E L,.. (W), for p, q and r satisfying (3.4), with r > 1. Assume first that u, v and 0 have compact supports, and so belong to L 1 (R). Since 1 l p + l /q + 1/r ; = 2, if we put ilr (x) (-x), then by Exercises 3.2 and 3.3, I(u * v,4)I = I(u * v * c)(O)I <- IIuIILp(R")IIUIILq(R")II1kIIL,*(R") = IIuIILp(R")I IVIILg(R")IIOIIL,*(R")

Now drop the assumption that u, v and 0 have compact support, define

if Ix I < j, 0 if Ix I > j, 1

Xr (x)

and put uj = X1 u, vj = Xjv and ¢j = Xj 4,. Since (I1J I * It; 1, I4) I) -< IIuj IIL,,(R") III; IILq(R")II4); IIL,.(R")

< IIuIILp(R")IIVIILq(R")II4IIL,.(R")

for all j, the monotone convergence theorem implies that I(u * v, 4))I _< (lul * Ivl, I4I) <_ IIuIIL,,(R")IIvIILq(R")II4IILrs(R"), giving the desired bound for 11U * V II L,. (R")

D

Sobolev Spaces

60

Taking r = oo in (3.4), we see that u * v is bounded if u E L p (IR") and v r= L. (IR"). To prove a stronger result, we introduce the p-mean modulus of continuity, 1/p

p

cvp(t,u)=sup(J lu(x+h)-u(x)Ipdxl Ihl
fort>0 and

/

Ilk"

1 < p < oo. It can be shown that, for 1 < p < 00, if u E L p (IR" ), then cop (t , u) as t J, 0.

3.6)

0

Theorem 3.2 Let I < p < 00. If U E L p (IR") and V E L p. (IR"), then u * v is uniformly continuous on IR". If, in addition, p 1, then (u * v)(x) -* 0 as I x l -+ oo.

Proof By Holder's inequality,

[u(x - z) - u(y - z)lv(z) dz

I(u*v)(x)-(u*v)(Y)I = IRIS

< wp(Ix - YI, u)IIvIILP.(R'), so u * v is uniformly continuous on W. Assume now that p Since p and p* are both finite, there exists R > 0 such that

f

u(Y)Pdy < Ep

and

1, and let c > 0.

v(Y)I'dy < E',

J yl>R

yl>R

and by Holder's inequality,

u(x - y)v(y) dy

I(u * v)(x)I

u(x - Y)v(Y)dy

flyl>R

<

1/P

(

Iu(x - y)IpdY)

IIVIIL,,.(tt.-)

Iyl
1/p'

+ IIUIIL,(R") (LI>R v(y)P' d) 1/p

< (fly-xl
IIUIILN(R")E.

Iflxl>2Randly-xl 2R-R= R. Thus, KU * v)(x)I < EIIvllLp.(R") + IIUIILn(R")E

andso(u*v)(x)-*OaslxI

oo.

for Ixl > 2R,

Differentiation

61

Differentiation Let S2 be a non-empty open subset of R". If a function u : Q -* C is sufficiently smooth for them to exist, then we denote the partial derivatives of u by 'a

aau(x)

(ax,

I

an

...

(ax")u(x),

..., a,,) is a multi-index, i.e., an n-tuple of non-negative integers. The order of the partial derivative aau is the number where a = (al,

lad = al + ... + a", and we put u(k)(x;

Y) lal=k

. a,,! and ya = y;'

where a! = a1 ! be written as

(3.7)

a 8,U(X)Y"

yin. In this way, Taylor's formula may

k

1 u1i)(x;

u(x + y) =

I!

y) + 1 k! J0 (1 - t)kulk+i)(x + ty; Y) dt; 1

(3.8)

see Exercise 3.5. For any integer r > 0 we let

Cr(S2) = (u : 8'u exists and is continuous on S2 for jaI < r), and put

C°°(Q) = n cr(ci). r>0

The support of u, denoted by supp u, is the closure in S2 of the set (x E 0 u (x) 0 0}. If K C= SZ, i.e., if K is a compact subset of 0, then we put

CK (0) _ {u E Cr (0) : Supp U C K}

and CK (Q) =

I

CK (S2). I

r>O

Next, we define

Ccomp(S2) _ {u : u E Cr (S2) for some K C 0} and

C mp(0) _ {u : u E CK (0) for some K C= c }. Exercise 3.6 gives some examples of compactly supported C°O functions.

62

Sobolev Spaces

We now show that differentiation commutes with convolution; see also Exercise 3.10.

Theorem 3.3 Let r > 0 and 1 < p < oo. If U E Ccomp (R") and V E Lp (R), then u * v E Cr (R") and

aa(u*v)=(a1u)*v for lot I < r.

Proof The case r = 0 follows from Theorem 3.2. Suppose r = 1, and consider the difference quotient with respect to the Ith variable,

A, hu(x) =

u(x + he,) - u(x)

for l < 1 < n and h

'h

where e,, ... , e" are the standard basis vectors for R". It is easy to see that 01,h (u * v) = (A1,,, u) * v, so for every x E

IR

11

I[o1,h(u * VA(x) - [(81u) * ul(x)I = 1[(A1,hu - a1u) * vl(x)I III/Au - a,uIIL,,.(R")II

IIL,,(R,').

Since u is C1 and has compact support, we have Dj,i,u -> aju in Lp.(R"), and thus 81 (u * v) = (a1u) * v. A simple inductive argument proves the result for the general case r > 1.

The connection between convolution and approximation by smooth functions, mentioned earlier, comes about via the following construction. Let * E Cop (R") satisfy

*>0onIlk",

*(x)=0forIx1> 1,

Jf *(x)dx=1;

(3.9)

such a function exists by Exercise 3.6. We define

kE(x)_e' r(E-lx)

forxER" and E>0,

(3.10)

so that, as one sees via the substitution x = Ez, `YE> 0 on R",

*E(x)=0 for Ixl>E,

r

J

*,(x) dx = 1.

These properties of 'VE mean that (`YE * u)(x) is a kind of local average of u around x, and for this reason 'YE * u ti u when c is small.

Differentiation

63

Theorem 3.4 Let 1 < p < oo. If `/. E is as above, and if u E L p (R" ), then

and II'/'E * U - uII L,(R") < co,,(, Eu),

11 *c * uII Lp(1R") < IIUIIL,,(R")

u in Lp(R") as e 4. 0.

so VE * u

Proof. Since 11 *E

IIL,(R") =

1, we see from Theorem 3.1 that

IIi *UIILn(R") < II1IreIIL,(R")IIUIILp(R") = IIUIIL,,(R")

Also,

'- * u(x) - u(x) = u * 'VE(x) - u(x)

0,., 0,., (Y) dY R"

and so, for any 0 E L p. (W'), Holder's inequality implies that

I(*E*u-u,0)I

=I fYISe

R*E(Y)

f [u(x - y) - u(x)]O(x) dx dy

I

J

'Y E(Y)Wp(E,

u)IIOIILr,+(R^) dy = Wp(E,

Y1 <E

and the desired estimate for ikE * u - u follows.

Corollary 3.5 If I < p < oo, then C,,,,,p(S2) is dense in Lp(SZ).

Proof. We choose any K j C S2 such that KI S; K2 e ... and 0 = U1 K); for example,

Kj = {x E S2 : dist(x, R" \ SZ) > 1/j and Ixj < j).

Let U E L(), define U j E L(R) by u (x) =

u(x) if x E Kj,

ifx E1R' \Kj,

0

and consider the function uj,E =

YkE * u j.

Theorem 3.3 shows that U j., E

C a ,p(R"), Exercise 3.4 shows that supp u j,E C Q

if E < dist(K1, R" \ 0),

and by Theorem 3.4 Iluj.E - UIILE,(c2) S IIUE.j - uj IIL,(R1') + IIuJ - uII L,,(s )

< Wp(e, U j) + IIuIIL,,(Q\KJ)

64

Sobolev Spaces

Since II U II L,,(s,\K) --). 0 as j -+ oo, and since cop (E, uj) -* 0 as c -* 0 for each fixed j, the result follows. We can also use convolution to smooth out the characteristic function of a set.

Theorem 3.6 Let F be a closed subset of R". For each E > 0, there exists XE E C°°(R') satisfying

0 < X, ,(x) < 1 and I aaXE (x) I < CE-IaI

if x E F, if 0 < dist(x, F) < E,

XE (x) = 0

if dist(x, F) > E.

XE (x) = 1

Proof Define vE E L°O(]R") by J1

VE(x)

0

if dist(x, F) < E, if dist(x, F) > E,

so that vE = I on a neighbourhood of F, and choose 1/r E C mp(R) satisfying (3.9). With the help of Exercise 3.4, one sees that the function XE _ *E/a * VE/2 has the required properties.

Schwartz Distributions

A (measurable) function u : 0 -* C is said to be locally integrable if u is absolutely integrable on every compact subset of Q. We denote the set of all such functions by L1,1oc(52). The following observation is the starting point for the theory of distributions.

Theorem 3.7 If u, v E L1,10 (0) satisfy

1 u(x)q(x) dx = J v(x)o(x) dx for all O E C mp(S2), then u = v almost everywhere on Q. Proof. Let K C= 52, and choose an open set 521 such that K C= S21 c S21 Cc Q.

We define f E L1(R") by

f(x)=

J

u(x) - v(x) if x E 521, 0

ifxER"\521,

'YE be as in Theorem 3.4. There is an co > 0 such that if x E K and 0 < E < co then (x - -) E C mp (521) and therefore (Vi, * f) (x) = (f, *E(x - .))tt,, = (u - v, 'YE(x - .))a = 0. Since '/FE * f -* f in L1(R"),

and let

Yk E

Schwartz Distributions

65

it follows that f = 0 almost everywhere on K, i.e., u = v almost everywhere on K. 0 Theorem 3.7 shows that a locally integrable function u is uniquely determined by its associated linear functional 4) H (u, 0) a. We wish to introduce a larger

class of linear functionals on C,'O.P (0). Following the notation introduced by Schwartz [92], put

E(Q) =

C°O(S2),

DK(S2) = CK (S2),

V(S2) = C mP(S2),

for any K C= Q. Since we want our functionals to be continuous in an appropriate sense, we now define convergence of sequences in each of these function spaces. No deeper properties of the underlying locally convex topologies will be used; cf. [106]. Let (4j) J _ , be a sequence in E (S2). We write

cj -+ 0 in S(Q) if, for each compact set K and for each multi-index a,

8'Oj -* 0 uniformly on K. When, for a fixed K, this condition holds for all a, and in addition supp c! c K for all j, we write

cj - 0 in DK (S2). 0 in D(7) means that 4j -+ 0 in DK(S2) for some K C= 0. Convergence to a non-zero function is then defined in the obvious way. For instance, cj --* ¢ in DK (0) means ¢ E DK (0), 4j E DK (0) for all j, and ¢j - 4) -3 0

Finally, 4j

in DK (S2).

Consider an abstract linear functional f : D(52) - C. For the moment, we write e(0) to denote the value off at ¢ E D(S2). If f is sequentially continuous, i.e., if for every sequence ¢j in D(S2), c1 -* 0 in D(S2)

implies t(4 f) -+ 0,

then t is called a (Schwartz) distribution on Q. In this context, the elements of D(Q) are referred to as test functions on 0. The set of all distributions on S2 is denoted by D*(0). Associated with each u E L 1,1 (0) is the linear functional to defined by (Lu)(4)) = (u, 4))c

for 0 E D(S2).

(3.11)

66

Sobolev Spaces

It is clear that to : D(7) -f C is sequentially continuous, and hence a distribution on 92. Furthermore, Theorem 3.7 shows that the linear map i : L 1,1"C (0) --+

D*(S2) is one-one. Hence, we may identify u with tu, and thereby make L1,1oc(92) into a subspace of D*(92). Those distributions that are not locally integrable can then be viewed as generalised functions.

As an example, fix x E R", and let E E D*(92) be the associated point evaluation functional defined by

f(0) = 0(x) for 0 E D(R"). It is not possible to represent this e by a locally integrable function. To see why,

suppose for a contradiction that £ = to for some u E L1.1oc(R"). It follows from Theorem 3.7 that u = 0 almost everywhere on R" \ (x}, and since the set (x) has measure zero, this means that u = 0 almost everywhere on R". Hence, ¢(x) = (u, 4)) = 0 for all 0 E D(R"), a contradiction. Following the convention introduced by Dirac, we denote the point evaluation functional for x by S., or in the case x = 0, just by S. In keeping with the philosophy that distributions are generalised functions, we henceforth write (u, 0) n for the value of u E 'D* (0) at 0 E D(92), whether or not u is locally integrable on 0. If 92 = R", then we usually omit the subscript, and just write (u, 0); for instance,

(S. ,0) =0(x) for0 E D(R"). Suppose that 921 is an open subset of 0, and for any ¢ E D(921) let E D(92) denote the extension of ¢ by zero. For any distribution u E D*(92) the restriction u I n, E D* (921) is defined by

(uIn,, 0)si, = (u, )st for 0 E D(9Z1). We say that u = 0 on S21 if u I a, = 0, and define supp u to be the largest relatively closed subset of Q such that u = 0 on n \ supp U. If U E L1,1,, (92), then the distributional support of u is the same as its essential support as a function, i.e., supp u is the largest closed set such that u = 0 almost everywhere on S2 \ supp u. We define E*(92) in the obvious way, i.e., a linear functional u : E(Q) -+ C

belongs to E* (Q) if it is sequentially continuous: (u, 4 )n -+ 0 whenever ¢J -} 0 in E(92). Exercise 3.8 shows that the inclusion D(92) g E(S2) is continuous and dense, so E*(92) S; D*(92). In fact, we can characterise E*(92) as follows.

Schwartz Distributions

67

Theorem 3.8 The space E* (S2) coincides with the space of distributions having compact support, i.e., E* (Q) = [U E D* (0) : supp u C= S2).

Proof Suppose that u E D*(S2) and supp u C= S2. By Theorem 3.6, there is

a X E D(l) with X = 1 on a neighbourhood of supp u. We define a linear functional ii on E(52) by putting for ¢ E E(SZ),

and claim that

(i) O; -+ 0 in E(S2) implies (u, c;)Q --). (u, O)g; (ii) (il, ¢)o = (u, O)n for ¢ E D(S2). Together, these facts mean that u = u E E* (S2) when E* (S2) is viewed as a subspace of D*(S2). We remark that u does not depend on the choice of X. To prove (i), assume Oj --+ 0 in E(0). It follows at once that XOj XO

in D(cz), so (u, oi)n = (u, XOi) - (u, xO)si = (u, 0)cz. To prove (ii), assume ¢ E D(S2). Since (1 - X)0 = 0 on a neighbourhood of supp u, we have (u, (I - X)0)a = 0 and therefore (u, 0) _ (u, 0) 52 (u, (1 - x)O)si _ (u, A2. Conversely, let u E E*(S2), and suppose for a contradiction that supp u is not compact. Choose an increasing sequence of compact sets KI c K2 c .. . with S2 = U,° , K j, then u I a\KJ # 0 for all j. Thus, we can find 4 E V (S2) such that (u, cj)n = 1 and supp4J Cc n \ K3. It follows that t -+ 0 in E(S2), 0, a contradiction. so (u, /j)n

The restriction map u r-+ u In, is just one of many linear operations that can be extended from functions to distributions. For instance, to define partial differentiation of distributions one formally integrates by parts:

(ac'u, cn = (-1)I0" (u, aacc

for u E D*(S2) and 0 E D(0).

Here, the sequential continuity of 8au follows at once from the fact that if 0 in D(S2), then 8a0j ->- 0 in D(S2). Also, we define the complex ¢j conjugate u E D*(S2) of U E D*(S2) by

(u, 95) = (u, 0)

for 0 E D(S2),

Sobolev Spaces

68

and we generalise the meaning of the inner product in L2(0),

(u, On =

Jsi

u(x)v(x)dx,

by putting

(u, 4)n = (u, ¢)n

for u E D*(0) and 0 E D(S2).

When S2 = l(8", we just write (u, 0). The convolution of a distribution with a test function is defined in the obvious way,

(u * 0)(x) = (u, i0(x - ))

forx E R1, U E

D*(R")

and 0 E D(R"). (3.12)

Thus, in particular, S * 0 _ 0, or formally fyt. 8(x - y)o (y) dy = 0(x), so we can think of 8(x - y) as the continuous analogue of Kronecker's Stk. Finally, multiplication of a distribution u E D*(S2) by a smooth function * E COO(Q) is defined by

(ifu, q )n = (u, *0)j2

for0 E D(S2).

In each of the above examples, Theorem 3.7 guarantees that the generalised concept is consistent with the classical one. For instance, if the classical partial derivative aj u exists and is locally integrable on 0, then 8i (cu) = c (a; u), where i is the imbedding defined in (3.11). Distributions are a powerful conceptual tool for the study of partial differential equations, and provide, in particular, a very effective system of notation. Fortunately, we shall require few technical results from the theory of distributions. However, the following fact will be used.

Theorem 3.9 Suppose that u E D* (0) and X E Q. If supp u C (x }, then for some m > 0,

u = E ac a"3,, on 0, 1" I
where the coefficients are given by a" = (-1)I"1 (u, (. - x)') /a!. Proof Denote the open ball with centre x and radius c > 0 by

BE(x)=(YER" : IY - xI < E}, and choose co > 0 such that the closed ball K = B,,,(x) is a subset of 0. By

Fourier Transforms

69

Exercise 3.9, there exists an integer m > 0 such that I (u, ¢) I < C 1] sup 18"4) I

for 0 E DK (S2).

(3.13)

laI
Given an arbitrary 4) E E(S2), we write the Taylor expansion of 0 about x as 0 _ 01 + 02, where m

41(Y) _ J=l

li 0(j) (X; Y - x) _ j!

la15,n

a

a"4)x)(Y - x)a

and

f(l - t)m(x + t(y - x); Y - x) dt.

02(Y) = m!

Since (u, 0) = (u, 01) + (u, 02) and (u, 01) _ I"I 5,n

e"4)(x)( -x)a) 1(u, e d

aa(8*3

(-1)10'Iaa8"46(x) la l <m

,

laI<m

it suffices to show that (u, 02) = 0. By Theorem 3.6, we can choose a function X E C°°(R") such that x (y) = 1

for IYI < 2, and x(y) = O for iyl > I. Define XE(Y) = X(E-,(y -X)) so that XE = 1 on B,/2 (x), and xE = 0 outside BE(x). Hence, (1 0 on a neighbourhood of suppu = {x}, so (u, (1 - XE)42) = 0 and therefore Since laaXEI < CE-I"l and (u,102) = (u, [x + (1 - XE)14)2) = (u, 18014611 <

CE"'+1-lal

on B, (x), the estimate (3.13) implies that

I (u, 02)1 < C E sup Ia"(xE4)2)I < C E lal5nn K

lal<m

Elal-m

sup

18"4)2(Y)i < CE

lY-1:5's

for 0 < e < Eo. Thus, (u, 02) = 0, as required.

0

Fourier Transforms To motivate the definition of the Fourier transform, we begin with some heuristic

remarks on multiple Fourier series. Given L > 0, we say that a function u 1[8" -> C is L -periodic if

u(x + kL) = u(x)

for x E R" and k E V,

or in other words, if u is L-periodic in each of its n variables. We can think of

70

Sobolev Spaces

such a function as being defined on the additive quotient group TL = R" / (L7G" ),

and introduce the L2 inner product

(u, v)T =

u(x)v(x) dx,

J

where integration over TL just means integration over any translate of the cube (0, L)". Using separation of variables, we can easily find the normalised L-periodic eigenfunctions of the Laplacian (1.1): for k E Z", the function 'bk(x) = satisfies

-Aok = (27rIkI)2k

on TL,

and II0kIIL2(rL) = 1. Since -0 is self-adjoint, we expect from Theorem 2.37 that the Ok will form a complete orthonormal system in L2(TL). Thus, for a general L-periodic function u, we should have

u(x) = 1: (Ok, u)r bk(x) =

1L"

uL(kIL)e'22r(k/c).X,

(3.14)

kEZ

kEZ"

where

UL( ) =

JaI

e-ibrg-xu(x)dx.

The analogous expansion for a non-periodic function can be viewed as arising in the limit as L -+ 00. If U E L 1(1R' ), then we define its Fourier transform u =

2u by

u(t;) _ x {u(x)) =

fp

dx fort E

!lam"

and expect from (3.14) that, under appropriate conditions, u = .F*u, where.F* is the adjoint of the integral operator T, i.e.,

u(x) _

-,x{u(t)} = f

(3.15)

for x E W. In fact, we can readily prove the following.

Theorem 3.10 If both u and u = 'Fu belong to Li(R"), then the Fourier inversion formula (3.15) is valid at every point x where u is continuous.

Fourier Transforms

71

Proof. Let *(x) = e-"1"12 and `YE (x) = E-"* (e -'x). Exercise 3.11 shows that 1/r is invariant under the Fourier transform: F* = 1/r = -7-1*. Therefore, by and .F*1i E _ 'YE In other words, the inversion Exercise 3.12, formula is valid for *E, implying that

j

J

d

d =

fR. Cfa

R11

l.

d dY

= fit" u(Y) J

f,u(Y)*E(x - Y)dy 1 as c y 0 for each 1f Since 7' dominated convergence theorem that

fRna(')ei2'

E IR", we deduce from the

d = lim(1/*E * u)(x).

(3.16)

E10

Assuming u is continuous at x, let co > 0 and choose So > 0 such that Iu(x - y) - u(x)I < co for IYI < So. Observe that fR YE(Y) dy = E(0) = 1, so for 0 < E < co,

f

[u (x - y) - u(x)]*E(Y)dy

Iu(x - y) - u(x)IfE(Y)dy lyl<&o

+

f

Iu(x - y) - u(x)I*E(y) dY

yl>-So

< Eo f *e (Y) dY

+

(f Iu(x - y) - u(x)I dy) \ at^

sup *E(Y) lyl?ao

"(60/E)'

Eo +2IIuIIL,(R^)E-"e

and the result follows at once from (3.16).

0

Corollary 3.11 If both u and u are continuous everywhere and belong to L 1(IR!1), then.F*.Fu = u = .F.F* u.

72

Sobolev Spaces

We now consider the actions of .7 and 1* on the Schwartz space of rapidly decreasing, C°° functions, 8(W1)

E C°°(R") : sup Ix"afl¢(x)I < oo XER"

for all multi-indices a and

}.

Sequential convergence in this space is defined by interpreting the statement

¢j -+ 0 in S(R't) to mean that, for all multi-indices a and 0,

x"0O(x) -+0 uniformly forx E R". Elementary calculations show that if 0 E S(R"), then and

F:,,g[(-i27rx)"O(x)} (3.17)

so the Fourier transform defines a (sequentially) continuous linear operator

.F : S(R") -* S(R"). Moreover, by Corollary 3.11, this operator has a continuous inverse, namely

the adjoint.1'' : S(R") -* S(R"). By Exercise 3.8, the inclusions D(R") C S(RI) C E(R") are continuous with dense image, so we have

E*(1(g") c S*(R") c D*(

),

and the elements of S*(R"), i.e., the continuous linear functionals on S(IR'1), are called temperate distributions. A sufficient condition for a function u E LI,,,,(R") to be a temperate distribution is that it is slowly growing: u(x) _ O (Ix I'') as Ix I -+ oo, for some r. The formulae

(J u, 0) = (u, TO) and

(.F*u, ') = (u, F 4 )

are obviously valid if both u and 0 belong to S(R"), and serve to define extensions

S* (R") -). S*(R")

and

J'" : S* (R") -> S*(k8")

We also have the following result, known as Plancherel's theorem.

Sobolev Spaces - First Definition

73

Theorem 3.12 The Fourier transform and its adjoint determine bounded linear operators

.F: L2(R") -a L2(R") and F* : L2(R") -+ L2(

n

with .F-' = .F". Furthermore, these operators are unitary: (.Fu, .Fv) _ (u, v) = (.F*u, .F*v) for u, v E L2(Il8").

Proof. If u, v E S(R"), then (.Fu,.Fv) = (.F*.Fu, v), and .F*.Fu = u by Corollary 3.11, because u E S(W) c LI(W), so (.Fu, Fv) = (u, v). In particular, taking v = u, we see that II.FuIIL2(Rn) = IIuIIL2(RI) for U E S(Rn). Corollary 3.5 implies that S(R") is dense in L2 (R"), so F has a unique extension from S(R") to a unitary operator on L2(Illi"). Furthermore, this extension satisfies (.Fu, 0) _ (u,.Fo) for all ¢ E S(lR"), consistent with the definition of Fu as a temperate distribution. In other words, the extension from S(R") agrees with the restriction from S*(If8"). Similar arguments yield the same reO

sults for .F*.

Corollary 3.13 The Fourier transform preserves the L2-norm: III fIL,(R'") _ IIuIIL2(1R")

a

Another important fact about the Fourier transform is its effect on convolutions: if u, v E L (Ilk") then

V) W) =

J

J

u(x - y)v(Y)dydx

f f e-1br(x-y)-4u(x - y)

aw

J

dy

= h()v() Sobolev Spaces - First Definition Suppose I < p < oo, and let 0 be a non-empty open subset of R". The Sobolev space WP' (n) of order r based on Ln(S2) is defined by

Wp(E2) = {u E Lp(Q) : 8Yu E L,(c2) for Iaj < r}. Here, of course, 8au is viewed as a distribution on n, so the condition 8"u E L p (Q) means that there exists a function g,, E L p (n) such that (u, 8"O) s- = (-1)I"I (ga, O)n for all 0 E D(S2), or equivalently 8'u = tga where t : L1j,(S2)

Sobolev Spaces

74

-+ D*(0) is the imbedding defined by (3.11). Such a function ga is often described as a weak partial derivative of u. The completeness of L p (S2) implies that WP (0) becomes a Banach space on putting

Ilullw;,(12) _

(tr1PdX)

1/p

To define Sobolev spaces of fractional order, we denote the Slobodeckil seminorm by

lu(x) - u(y)Ip lulu,p>sa =

CJsi J

oo

I x- y I"+P"L

dx dy

)1/p

for 0 < µ < 1.

(3.18)

Notice that the integrand is the pth power of lu(x) - u(y)I/lx - yliL+"/p, so for p = oo we get the usual Holder seminorm. For s = r + µ, we define

Wp(l) = {u E W,(2): Iaaulµ.p.n < oo for lal = r}, and equip this space with the norm

Ilullw;(n) =

E Iaaulµ.P", Ia1=r

For any integer r > 1, the negative-order space WT (S2) is defined to be the space of distributions u E D* (Q) that admit a representation

u = E as fa

with f, E L p(S2).

(3.19)

lal
This space is equipped with the norm \ i/p

Ilullw,,r(n) = inf G IlfallLP(sz)) IaI
where the infimum is taken over all representations of the form (3.19). Using Holder's inequality, it is easy to verify that I(u, u)QI < Ilullw;.(cz)llVIIw"(cI)

where p* is given by (3.1).

foru E WW-.r(0) and V E D(0),

Sobolev Spaces - Second Definition

75

In this book, we will rarely use Sobolev spaces with p 2, and so adopt the abbreviation W1 (Q) = W2 (Q). For any integer r > 0, the norm in W"(n) arises from the inner product (u, V) W, (Q) _

J

a" u (x)a' v(x) dx,

and likewise if s = r + p then the norm in W' (0) arises from the inner product (u, v) W, (a)

f fn

_ (u, v)W,

IaI=r si

[aau(x) - aau(y)l[aav(x) - a,v(y)] dx dy. yI11+2u

Ix -

Thus, W' (0) is a Hilbert space for all real s > 0.

Sobolev Spaces - Second Definition In this section, we introduce a second family of Sobolev spaces, which later will turn out to be equivalent to the one given in the preceding section. For S E R, we define a continuous linear operator ,75 : S(RI) S(lR"), called the Bessel potential of order s, by

d for x E R.

J5u(x) = fR11 (1 +

In this way,

x-. (,75u(x)} _ (1 + I I2)s"2u( ),

(3.20)

so under Fourier transformation the action of ?S is to multiply u by a function that is D(I IS) for large . We can therefore think of ?SEas a kind of differential

operator of orders; cf. (3.17). Notice that for all s, t

Js+' = JS Jt ,

R,

= J--, Jo = identity operator.

It follows from (3.20) that

(Yu, v) = (u, ,75v)

and

(.75u, v) _ (u, .7sv)

for all u, v E S (R"), giving a natural extension of the Bessel potential to a linear operator ?5 : S* (W) -+ S* (WI) on the space of temperate distributions.

Sobolev Spaces

76

For any s E R, we define HS(R"), the Sobolev space of order s on R", by Hs(R??) = {u E S*(JRf) : JSu E L2(R")),

and equip this space with the inner product (u, v)H=(R") = (JSu, 3Sv)

and the induced norm (3.21)

(u, u)H3(R") =

Notice that the Bessel potential

,7S : HS(R") - L2(R") is a unitary isomorphism, and in particular, since J°u = u,

H°(R") =L2(R"). Several facts about HS(R") follow immediately from standard properties of L2(R ). For instance, HS(R") is a separable Hilbert space, and D(R") is

dense in HS(R") because ,75[S(R')] = S(R") is dense in L2(R"), and the inclusion D(R") c S(W) is continuous with dense image. Also, one sees from (3.2) and (3.3), with p = 2, that H-S(R") is an isometric realisation of the dual space of HS (RII ), i.e.,

H-S(R") = [HS(R")]*

fors E R,

(3.22)

and sup

I(u, v)1

OOVEH3(R") IIuIIH=(R")

=

sup

1(u, v)I

o#vEH=(R") IIVIIHI(R")

for U E H-'(RI). Plancherel's theorem (Theorem 3.12) and (3.20) imply that IIUIIH=(R,t) =

j(1 + 12u2d, "

so if s < t then IIuIIH=(R") < IIuIlH,(R") and hence H'(R") c HS(R"). This inclusion is continuous with dense image. For any closed set F C R", we define the associated Sobolev space of order s by

HF.=(uEHS(R"):suppucF),

Sobolev Spaces - Second Definition

77

whereas for any non-empty open set 7 c Rn we define

HS(S2) _ {u E D*(S2) : u = UIn for some U E HI (R")). We see at once that H. is a closed subspace of HS (RI), and is therefore a Hilbert

space when equipped with the restriction of the inner product of H''(R"). A Hilbert structure for HS (0) is defined with the help of the orthogonal projection

P=P,,n: HS(R")-f which satisfies

PUI n = 0 and (I - P)UI n = UI n

for all U E HS(R").

Noting that if U I n = 0 then P U = U because U E HI \n, we see that a well-defined inner product on H' (S2) arises by putting

(u, u)HI(n) = ((1 - P)U, (I - P)V)HX(R,,)

if u = U112 and v = VI

for U, V E HS (R" ). Notice that the induced norm satisfies IIuIIH=(n) =

(u, u)H°(n)

= vin

uEHt(R»)

IIUIIHS(R,I),

(3.23)

because if U In = u then IIUIIHs(R") = IIPUIIHa(R") + II(1- P)UIIH

(R

II(I - P)UIIHt(R") =

The map U r-* (1 - P)Ul n is a unitary isomorphism from the orthogonal complement of onto HS(c2). Therefore, H4(S2) is a separable Hilbert space. Also, (3.23) shows that the restriction operator U H UIn is continuous from HS (R") to HS (0), and thus the space

D(7)=(u:u=Ulnforsome UED

11)

I

is dense in HI (Q) because D(R") is dense in H' (R'). We also define two other Sobolev spaces on 0, HS(S2) = closure of V(S2) in HS(R"), Ho (S2) = closure of D(S2) in HS(S2),

which we make into Hilbert spaces in the obvious way, by restriction of the

78

Sobolev Spaces

inner products in HS (R") and in HS (0), respectively. It is clear that HS (S2) c

H

and

H" (S2) c Ho (S2),

and later we shall establish the reverse inclusions subject to conditions on 92 and s. Note that an element of H is a distribution on R", but, provided the n-dimensional Lebesgue measure of the boundary of n is zero, the restriction operator u H uIn defines an imbedding

H&cL2(0) fors?0.

(3.24)

(If U E H and uIa = 0, then suppu c a2 = SZ \ S2, implying u = 0 on R".) In general, if s < -Z, then Hazy {0} no matter how smooth the boundary of 0, so we cannot imbed H. in a space of distributions on S2; see Lemma 3.39. The necessity of introducing more than one kind of Sobolev space on S2 can be seen already from the next theorem, which extends our earlier observation

that H-'(R") is an isometric realisation of the dual space of H`(R"); see also Theorem 3.30. Theorem 3.14 Let S2 be a non-empty open subset of R", and let s E R.

(i) If fl` (Q) = HI'r, and if we define (u, v) a = (u, V) for U E H-1(S2) and v = V IQ with V E HI (R"), then H''(0) is an isometric realisation of HS (0)*. (ii) If HS (S2) = Ham, and if we define

(u, v)n = (U, v) foru = UIn with U E H-'(R"), and V E H5(S2), then H-5(n) is an isometric realisation of H5(S2)*.

Proof First note that

(u, V) = 0 if u E D(Q), V E HS(R") and VIsi = O, so (u, v)c is well defined for u E H-s(S2) and V E H'(S2). We claim that (lu)(v) _ (u, v)Q defines an isometric isomorphism t : H-S(S2) -* HS(S2)*. Indeed,

I(lu)(v)I = I(u, V)I

IIUIIH-S(R,1)IIVIIH-(R")

whenever v = VIQ,

so I(lu)(v)I < IIUIIH-r(n)IIVIIH'(a) and hence IItuIIH-(Q)» < IIuIIH-=(O). Fur-

thermore, given a functional f E H3(S2)*, the map V H f(V In) is bounded

Equivalence of the Norms

79

on HS (R") because the restriction map V i-3 V I n is bounded from H3 (RI)

onto H'(Q). We know already that H-3(R!) is an isometric realisation of [HS (R")]*, so there exists u E

H-S (R") satisfying

f(Vlc) = (u, V) for all V E HS(R"), and

It(Vlra)I o#VEH'(R")

II V II Hs(a^)

If V E D(R \ n), then V I = 0, so (u, V) = 0, showing that suppu c S2, i.e., u E His. Assume now that H-S(S2) = H 3. In this case, u E and we see from

f(v) = t(Vlg) = (u, V) = (tu)(v)

for v = Vlo and V E HS(R'l)

that f = tu, sot is onto. Finally,

It(Vln)I < implying that IIuIIH-,(n) = IIulIH-'(a°) <_ IItuIIHs(c) Thus, t is an isometry. Part (ii) then follows because every Hilbert space is reflexive.

Equivalence of the Norms

When 0 = R" and s > 0, a simple argument based on Plancherel's theorem shows the equivalence of the two kinds of Sobolev norms; see also Exercise 3.13. We use the abbreviation

(LI I Ixx)

Ylu(Y)I2

n+2µ

dxdy /!1/2

for the Slobodeckii seminorm (3.18) with p = 2, and write I u 1, , = the usual way.

Lemma 3.15 If 0 < .t < 1, -then Iulµ

=

a".,f

where

apt, = Ijwl=1 lei2t - 1 >0

l2

dco dt.

I u I1,,.

in

80

Sobolev Spaces

Proof. Define the forward difference operator Sh by

Shu(x) = u(x + h) - u(x), and consider the Fourier transform

I)i ( ).

.FShu( ) _

(3.25)

By making the substitution h = y - x, applying Plancherel's theorem and then reversing the order of integration, one finds that

f

2=

IIShUIIL_(Rn)

l

Ihl'-u+n

FC"

f

f

dh = R

IhI2µ+n

We transform the inner integral to polar coordinates, letting h = pw, where p = I hl and co = h/IhI. Since dh = pi-1 dp dw,

f

112

'H

Ihl2u+n

A=f

p-2µ-1 >o

lei2rrpl;."

- 112 dcodp = au l

I2µ,

0

where we used the substitution p = I

that f

f

1-1 t

and exploited radial symmetry. Note

lei2'

(,,j_1 ' - 112 dw is O(t2) as t J. 0, and is 0(1) as t Too, so that aµ is a finite, positive real number for 0 < µ < 1.

Theorem 3.16 Ifs ? 0, then W'(R') = H' (RI) with equivalent norms. Proof. Let r be a non-negative integer, and let 0 < p < 1. In view of (3.17), Plancherel's theorem gives IIu11w'.(R")

_

j br( )lu( )led

1:

lal
where

(I +

br( ) _

1512

)r,

proving the result if s = r. By Lemma 3.15, ifs = r + µ, then IIUIIW(Rn) + E laauIA

=

f

lal=r

')I2d +

,

fRn

(1 +

la l=r

fR'

)12d

Equivalence of the Norms

81

Corollary 3.17 For any non-empty open subset 0 C R", there is a continuous inclusion Hs (Q) C Ws (S2)

for s > 0.

Proof. Given U E Hs (Q), we can find U E Hs (R l) such that u = U I si and IIu11HIM) = IIU11H=(R") By the theorem, U E

Ws(1Rl), so is E W1 (Q) and

Ilullw=(n) _< IIUIIws(w°) - IIUIIHs(a") = IIul1H1(sz)

The next theorem shows that the reverse inclusion holds if there exists an extension operator for 0. The existence of such operators is proved in Appendix A, under appropriate assumptions on S2; see also Theorem 3.30.

Theorem 3.18 For any non-empty open set Q C R" and any real s > 0, if there exists a continuous linear operator E : Ws (0) -> Ws (R") such that Eu I n = u

for all u E Ws (0), then

H'(Q) = W3(c) with equivalent norms.

Proof. If U E Ws(S2), then is = Uln for U = Eu E Ws(R") = Hs(R"), so u E Hs(S2) and IIuIIH,'(n) _< IIUIIH=(R") - IlEullwS(R,,) < Cllullws(j2),

giving a continuous inclusion W1 (S2) c H3(0). No extension operator is needed to establish the corresponding result when s is a negative integer.

Theorem 3.19 For any non-empty open set 7 C R", and for any integer r > 0,

H-r(2) = W-r(2) with equivalent norms.

Proof First consider the case 0 =1R' , and recall that [H'(R"))* = H-r (Rn) We define a Banach space isomorphism J : Wr(W") --+ H -1 (WI) by (Ju, v) = (u, v)Wr(R,.)

foru, v E Wr(R") = Hr(Rn),

Sobolev Spaces

82

and introduce another inner product and norm for H-r (R),

((u, v))-r = (J-'u, J-'v)wr Obviously, Illu III-r

and

((u, u))-r =

IIIuIII-r =

IIJ-iullwr(tt").

flu II H-' (>a")

If U E H-r(R") and V E H" (R), then

(u, v) _

(J-lu,

where fa = (-1)Ialaa J-1u E W-r(R") with IIuIIW-r(R^)

(aaJ-lu, aav) _

v)wr(R") =

(aafa, v),

IaI
IaI
Wr-I«I(R")

c L2(R"). Thus, u = F-Ial
-

< > IIfaIIL2(R") IaI
IIa(rJ-lull2 laI
(J-lu, J-`u)Wr(Rn)

= IIIUIII?r

Conversely, if u E W-r(R") has a representation u = F-lal
(aafa, v)I = 11: (-1)'aI(fa, 8av)

I(u, v)I = I

IaISr

Ial:Sr

1/2 112L,

C

(R")

Ilyllwr(R^)

IaI
for ally E Wr(1R")=Hr(Rn),sou E H-r(R") andIIUIIH-r(R")
Now consider the case when S2 # R", and let u E H-r(S2). We choose U E H-r(R") = W-r(RL8") such that u = U112 and Ilullx -r(Q) = IIU11x-1 (R^), and then choose Fa E L2(R") such that 80T.,

U=

and

IIUIIv-r(tt") < E IaI
IaI
Put fa = Fa I a E L2(Q), so that u =

IaI
W-r(S2), and IIfalIL2(n) <

IIuIIW-r(n) < IaI-
<

U112

E IaI
IIFaIIL2 z(R")

H II UII-r(an) =

IIUI12

H-r(n)'

IaI as f", on 0 with fa E Conversely, suppose that u E W -r (0) satisfies u = L2 (S2). Extend fa by zero outside Q, and denote this extension by Fa E L2(IR").

Localisation and Changes of Coordinates

83

Put U = EIaI
IIFotIIL2(R")

IaIsr

-

IIJ

L2(n)'

IaI
Thus, U E H-r(7) and IIuIIH-rM) < CIIuIIw-r(n)

Localisation and Changes of Coordinates Our next result shows that multiplication by a smooth cutoff function defines a bounded linear operator on HI (Q) or on F11 (0).

Theorem 3.20 Suppose that 0 E Ccomp(R") for some integer r > 1, and let IsI < r. If U E HS(S2), then 4u E H5(S2) and II-0UIIH5(n) <- CrliIOiiW,(R")IIuIIH-(n).

The same holds with HS (S2) replaced by Hs (S2).

Proof. Suppose first that Q = R". In view of Theorem 3.16, the result is clear for s = r, and hence by the duality relation (3.22), for s = -r. The case -r < s < r then follows by interpolation, using Theorem B.7 (from Appendix B). An alternative proof, leading to a different norm for 0, is given in Exercise 3.16. Now let 7 be any open subset of IE,i;", and let it = U I st for some U E Hs (R").

Since Ou = (0U)In or, strictly speaking, q5nu = (¢U)In, we see that II0uIIH5(n) < IIOUIIH=(R") <- CrII4llwr (R")IIUIIH1(R"),

and the desired estimate follows after taking the infimum over U. With HS (S2) replaced by F11 (Q), the proof is even easier because IIouIIH$(s2) = II0u1IHI (R") and IIuIIH=(n) = IIuIIHs(R").

0

In conjunction with Theorem 3.20, the following notion is often useful; cf. Exercise 3.19. A partition of unity for an open set S C R" is a (finite or infinite) sequence of functions 01, 02, ... in C°O(R") such that

1. Oi > 0 on R" for each j; 2. each point of S has a neighbourhood that intersects supp 4j for only finitely many j ;

3. J:j >t Oj(x) = 1 for each x E S.

84

Sobolev Spaces

Notice that condition 2 implies that the sum in condition 3 is finite for each x E S. If S is not open, then we say that the cj form a partition of unity for S if they form a partition of unity for some open neighbourhood of S. Suppose now that W is an open cover for S, i.e., W is a family of open sets for which S C U W. We say that a partition of unity (4)> 1 is subordinate

to W if for each j there exists W E W such that supp cj C W. Theorem 3.21 Given any open cover W of a set S C R", there exists a partition of unity (q5j) j>1 for S subordinate to W. Moreover, the 4j can be chosen in such a way that supp .ij is compact for each j.

Proof Put 0 = U W. We begin by constructing open n-cubes Q 1, Q2.... with the following properties: (i) the family { Q j l j> 1 is an open cover of n;

(ii) for each j there exists a set W E W such that Q j C W; (iii) each point of 9 has a neighbourhood that intersects only finitely many of the Q p Let 01 C 02 C SZ3 C . be a strictly increasing sequence of bounded open sets whose union is 0 and that satisfy SZj C= S2 j+1 for each j > 1. For convenience,

we put 0-1 = S20 = 0, and then define the compact sets K j = S2 j \ S2 j-1 for j > 1. Since K j does not intersect S2 j_2, given x E K j we can find an open cube G centred at x with G j,s C= W \ S2 j-2 for some W E W. The family {G j.X : x E K j } is an open cover for K j, so by compactness we can extract a finite subcover Q p After relabelling the cubes, we obtain a countable family Uj> 1 Qj = (Q1, Q2, ... } with the required properties (i)-(iii). (The set Q j is disjoint from each cube in Q i+2 U Q j+3 U .... and so intersects only cubes in the finite family Q1 U U Qj+1.) For each j > 1, we can use Exercise 3.6 to construct a function 1/rj E C ,p (]Il;") satisfying i/ij > 0 on Q j, and ij = 0 on R" \ Q p. Property (iii) of the Q j implies that the sum 11(x) = > j> 1 *j (x) defines a function E CO° (S2), and property (i) implies that > 0 on Q. Hence, we obtain the desired partition of unity by defining q 5j (x) = *j (x) / ' (x) for x E 0, and O j (x) = 0 otherwise.

Corollary 3.22 Given any countable open cover {W1, W2, ...} of a set S C R", there exists a partition of unity (P1, 02, ... for S having the property that supp q5j C Wj for each j > 1.

Density and Imbedding Theorems

85

Proof. Let 01, 02, ... be a partition of unity for S subordinate to the given open cover, define the index sets 11 = {k > 1 : supp 0k C= WI) and

Ij = {k > 1 : supp Ok C= W3 and k f I, U ... U Ij _ 1) for j > 2, and then put O! (x) = >kEI; Ok(x) for j > 1. We will now show that the Sobolev spaces on ]R" are invariant under sufficiently regular changes of coordinates; u o K denotes the composite function defined by (u o K)(x) = u[K(x)].

Theorem 3.23 Suppose that K : IR" -* ]R" is a bijective mapping and r is a positive integer, such that a"K and FK-1 exist and are (uniformly) Lipschitz on R" for J a I < r - 1. For 1 - r < s < r, we have u E H'(1R") if and only if u o K E HS(IR"), in which case 11U

0 K11 H-

(RI-)

11U11

S(R")

Proof. It suffices to show that for 1 - r < s < r, 11U 0KIIii

(R1-) < Cr11UIIH'(R-')

If s = r, then the estimate follows directly from the chain rule, because H" (IR") = W r (]R" ). The same estimate holds for s =1- r because H 1-r (]R") [Hr-1 (R'l)]* and

(u o K, v)

= (u, (v o K-1)I det(K

The case 1 - r < s < r then follows by interpolation, using Theorem B.7.

Density and Imbedding Theorems We saw earlier that D(SZ) is dense in H8(S2), but it is easy to find examples where D(S2) is not dense in Ws (0); see Exercise 3.18. However, we have the following theorem of Meyers and Serrin [64]. The proof relies on a technical lemma. Lemma 3.24 Lets E ]R and c > 0. For each u E HS (I8") there exists v E D(W' ) satisfying 11U

- v1IH-I(tt'-) < E

and

supp u c {x E ]R" : dist(x, suppu) < E).

Proof. See Exercises 3.14 and 3.17.

Sobolev Spaces

86

Theorem 3.25 For any open set 0 and any real s > 0, the set W5(S2) fl g (o) is dense in Ws(9).

Proof. Define a strictly increasing sequence of bounded open sets W1 C W2C ... by Wj = {x E S2 : Ix1 < j and dist(x,R" \ 0) > 1/j), and choose a partition of unity 01, 02, ... as in Corollary 3.22. Let U E WS (S2) and c > 0. For each j, the function 4j belongs to D(S2), so Oju E WI (R-1) = HI (W) and we can apply Lemma 3.24 to obtain a sequence (v)1 of functions in D(S2) satisfying

IItju - vj11wT(n) :

2jj

and

suppvj c Wj+i.

(Here, we use the fact that 110j u - vj II w=(n) = II /. ju - vj 11 w'(ttn).) Define v(x) _ F_1 v j (x), and note that this sum is finite for x in any compact subset

ofS2,sovEE(c2)and 00

Ilu - v11w(n) = T(Oju

00

j=1

E

1

- vj) W (SZ)

j=1

0 Next, we prove the Sobolev imbedding theorem, which shows that if s is large enough then the elements of HS (1[8") can be thought of as continuous functions, and the elements of Ho (S2) as functions that vanish on the boundary of n.

Theorem 3.26 Suppose 0 < tt < 1. If U E H"t 2+u (R` ), then u is (almost everywhere equal to) a Holder-continuous function. In fact, IUWI <- C II u lI H-1n+,t (R,1)

and

-YI'

lu(x) - u(y)I < for x, y E R".

Proof By the Fourier inversion formula (Theorem 3.10) and the CauchySchwarz inequality, if u E S(R") and X E R", then Iu(x)I <

f

dl;

where

C2 = f (1 +

112)-n/2-u

d < oo.

Density and Imbedding Theorems

87

Now let u E H"/2+1, (1[8"). We choose uj E S(R") such that uj -+ u in H"/2+4 (R"), and observe that, by the estimate above,

lu/(x) - uk(X)I < cllu/

-

Therefore, we can define a uniformly continuous function U : R" C by U (x) = lim1.._, 00 u/ (x) for x E R". Let l E D(R" ). On the one hand, (uj, 0) -+ (u, q5) because u/ -+ u in H"/2+u (R"), and on the other hand (uj, q5) -+ (U, q0)

because uj -a U uniformly on IR". We conclude from Theorem 3.7 that, for almost all x E I[8", u(x) = U(x) and

Iu(X)I = 1U(X)1 =j-,0o lira luJ(x)I -< Cj-+oo lira Similarly, we see from (3.25) that Shu(x) = u(x + h) - u(x) is bounded by

f

dl; < MA(h)11u11 H,t/2+u(R,,)

where Mm (h)2 =

f

(1 +

1412)-n/2-u

-1 I2 d

It is clear that M,u (h) < C for all h E R", and if 0 < l h 1 < 1 then M1, (h)2 < C

f

(I +

h12d

ICI<1/Ihl

+4f

(1 +

112)-n/2-u

d

t1>1/Ihl

< C1h12 (i + f l

1/IhI

l

p1-2u dp J + C Jr00 p-1-2u dp 1/IhI /l

< Clh12(l + 1h12u-2) + Clhl2u < CIh121' , SO lShu(X)I <

for allx E R".

We shall also prove an important compactness result that originated in a paper of Rellich [84].

Theorem 3.27 Assume -oo < s < t < oo. (i) If K is a compact subset of I(8", then the inclusion HK c HK is compact. (ii) If S2 is a bounded, open subset of R", then the inclusion Hr (0) C HS (S2) is compact.

Sobolev Spaces

88

Proof To prove part (i), let (u)1 be a bounded sequence in HK for some compact set K C= R". We want to show that a subsequence converges in HK. Choose a cutoff function X E D(R) satisfying X = 1 on K, so that

uj(

)=Xuj(t)=f

n

Using the Cauchy-Schwarz inequality and Peetre's inequality (see Exercise 3.16), we find that

(I + ItI2)`Ii{{j(f)I2 < 2111

(1 + It

\J

-

r1I2)1nhIX(t

-17)I2dr1)

X (f

Likewise, since 81u j = (a"j() * u j = j( * u j where X,, (x) = (-i27rx)"X (x), we have I4I2)hIa°`uj(t)I2

(1 +

< 21t"IIX.,112

.

It follows, in particular, that the sequence of Fourier transforms (j) ° 1 is uniformly bounded and equicontinuous on any compact subset of JR". Let K1, K2, K3,... be an increasing sequence of compact sets with U ° 1 K, = JR" . By the Arzela-Ascoli theorem (Theorem 2.15), there is a subsequence i that converges uniformly on K1. From this subsequence, we can extract a subsequence u that converges uniformly on K2. Continuing in this way, we obtain successive subsequences such that u'. converges uniformly on K,. For brevity, we now denote the diagonal subsequence ui by u j. Thus, the Fourier transforms u j converge uniformly on any compact subset of Ill;", and it suffices to show that the functions u j themselves are Cauchy in HK . Given e > 0, we first choose R large enough so that

f

(I + ItI2)SIij(t) - uk(t)I2 d4 1>R

(1 +

(I + ItI2)`Iuj(t)

R2)S-t

fn

IIuj - ukllH,(R-.)

(I + R2)(-3

- 2(IIuj

2

(1 +

- uk(t)12d Il ukll

E

2

Lipschitz Domains

89

for all j, k > 1, and then choose N large enough so that

f

(1 + 11;12)5 lug

uk (i; ) 12 dt < 2

for all j, k > N.

I
) < E for j, k > N, completing the proof of part (i). i is a bounded sequence in H'(S2). By hypothesis, Suppose now that 0 is a bounded subset of R", so we can find a compact set K C=1[8" together Hence, I l u 1 - Uk i i

with a cutoff function x E DK (R") such that cZ C K and x = 1 on 0. For each j, choose U1 E H'(]R) With II UjIIH'(R") = IIUJ IIH'(n3- By Theorem 3.20, is bounded in HK, so by part (i) there is a subsequence, the sequence (x x Uj E HK again denoted by (x UU )_1, that converges in H. Put U = limb.

and u = UIn E H5(S2), and observe that Ilu1 - UIIHs(n) = II(xU.i - U)IQIIHs(Q) <- IIXU; - UII H' -

Thus, uj -* u in HS (S2), proving part (ii).

O

Lipschitz Domains Denote the boundary of the open set S2 by

r=au =s2n(w\Sl). Thus far, no use has been made of any regularity assumption on IF, but henceforth we shall require that, roughly speaking, the boundary of S2 can be represented locally as the graph of a Lipschitz function (using different systems of Cartesian

coordinates for different parts of r, as necessary). The simplest case occurs when there is a function : R"-1 -* R such that

S2={x

ER"-I}.

all

(3.26)

If 4 is Lipschitz, i.e., if there is a constant M such that

MIx' - y'I

for all x', y' E

(3.27)

then we say that 0 is a Lipschitz hypograph.

Definition 3.28 The open set cZ is a Lipschitz domain if its boundary r is compact and if there exist finite families (WJ} and (0j) having the following properties:

Sobolev Spaces

90

(i) The family (Wj) is a finite open cover of I', L e., each W J is an open subset

of w, and I' C U; Wj. (ii) Each Qj can be transformed to a Lipschitz hypograph by a rigid motion, i.e., by a rotation plus a translation. (iii) The set Q satisfies W3 n s2 = w j fl S2j for each j. Notice that if 0 is a Lipschitz hypograph as in (3.26), then

I'={x ERn-1 :x

E

nI

We also remark that although, in our definition, the boundary of a Lipschitz domain must be compact, the domain itself may be unbounded. In particular, if SZ is a bounded Lipschitz domain, then R" \ SZ is an unbounded Lipschitz domain. Sometimes, a different smoothness condition will be needed, so we broaden

the above terminology as follows. For any integer k > 0, we say that the set (3.26) is a Ck hypograph if the function : lR' -+ ]f8 is Ck, and if 81 is bounded for lad < k. In the obvious way, we then define a Ck domain by substituting "Ck" for "Lipschitz" throughout Definition 3.28. Likewise, for 0 < It < 1, we define a domain by adding the requirement that the kth-order partial derivatives of be Holder-continuous with exponent µ, i.e.,

18' (x') - d' (Y') i < Mix' - A,

f o r all x', y' E Rn-1 and IaI = k.

Hence, a Lipschitz domain is the same thing as a CO, 1 domain. Notice that in the definition of a Ck or domain, we can assume if we want that has compact support, because r is always assumed to be compact. The class of Lipschitz domains is broad enough to cover most cases that arise in applications of partial differential equations. For instance, if k > I and r, is a compact, (n -1)-dimensional Ck submanifold of R", then 0 is a Ck domain and hence also a Lipschitz domain. Furthermore, any polygon in RI or polyhedron in RI is a Lipschitz domain. One can construct many other examples using the fact that if K : R" - * R" is a C 1 diffeomorphism and if 0 is a Lipschitz domain, then the set K(S2) is again a Lipschitz domain. Figure 2 shows some examples of open sets that fail to be Lipschitz domains: (i) is disqualified because of the cusp at the point A; (ii) because of the crack B C (a Lipschitz domain cannot be on both sides of its boundary); and (iii) because in any neighbourhood of the point D it is impossible to represent r as the graph of a function. For a Lipschitz domain, in fact even for a CO domain, a much stronger density result than Theorem 3.25 holds.

Lipschitz Domains

91

(i)

0

Figure 2. Examples of regions that fail to be Lipschitz domains.

Theorem 3.29 If 0 is a CO domain, then (i) D(S2) is dense in WS (Q) for s > 0; NO D(S2) is dense in H or in other words HS (S2) = Hn for S E R. Proof. Suppose to begin with that n is of the form (3.26) for some continuous function : ]R"_' - ]R having compact support.

Lets > 0, u E WI (0) and e > 0. For S > 0, we define

ua(x)=u(x',x"-S)

and

528=(x ER" :x,,

so that ua E WS(Qs). Since a"us = (a' u)8, we can choose 3 small enough so that Ilu-uslsalIW$(si) < 2

and then choose a cutoff function X E E(]R") satisfying X = 1 on 0 and X = 0 on ]R" \ 52(8/2), so that Xus E WS (]R"). Hence, by Theorem 3.16, there exists V E D(]R") such that E

Ilxua-VIIWs(atn)<2.

Sobolev Spaces

92

implying that the restriction v = V In satisfies

IIu - vllwa(n) = Ilu - usln + (Xus - V)Inllwl(n) IIu - U lnllw$(n) + IIXus - Vllw=(RlI) < E.

Thus, D(S2) is dense in WS(Q). To complete the proof of part (i), we suppose now that S2 is a Co domain, and let be a finite open cover of r as in Definition 3.28. Define one

additional open set WO = {x E Q : dist(x, R" \ S2) > S}, choosing a small enough 8 > 0 so that S2 c_ U'=o Wj. We may assume that Wj is bounded for I < j < J, but WO will be unbounded if 0 is unbounded. Let 0 be a partition of unity for S2 such that supp j c W j for all j. By the case of a Co hypograph considered above, if 1 < j < J then there exists vj E D(l) such that Iloju - vj II w.,(n) < E/(J + 1). In fact, by Lemma 3.24, the same is true also when j = 0, because 4ou E W1 (R"). Put v = F_J=o V j E D(S2); then J

11U - v1Iw.(n) = E(Oju j=o

IIOjU-vj11Wx(n) <E.

- vj)

W (n)

j=o

To prove (ii), assume once again that 0 is of the form (3.26), and let s E R, u E HS (S2) and r > 0. This time we put us (x) = u (x', x,, + 8), and observe that us E HI (R") and suppus c {x E R" : x" (x') - 8}. Choose S small enough to ensure IIu -US IIH.(ttl') <

2

E,

and then apply Lemma 3.24 to find v E D(Q) satisfying 11us - vIIH=(R,I) <

2

Since 11u -vIIH=(n)= 11(U - us) + (us - v)IIHs(R) < E, we see that 1)(0) is a dense subspace of HS (S2). As with part (i), the result carries over to Co domains with the help of a partition of unity. Theorems 3.29 and A.4 allow us to apply Theorems 3.14 and 3.18, and hence deduce the following important result.

Theorem 3.30 If Q is a Lipschitz domain, then

(i) HS (Q)* = H-S (S2) and HS (S2)* = H-S (0) for all s E R; (ii) WS(S2) = HS(Q) for all s > 0.

Lipschitz Domains

93

We remarked earlier that HS (S2) C Ho (S2). The next two technical lemmas will enable us to establish the reverse inclusion apart from certain exceptional values of s.

Lemma 3.31 Suppose U E D(R). If 0 < s < Z, then f f °Cx-z.`Iu(x)12dx < CS J 0

0

,

, (u(x) -u(Y)12 dxdy. Jo Ix r

Y11+2s

If, in addition, u (0) = 0, then the inequality holds also for 1 < s < 1.

Proof. Observe that the double integral converges for 0 < s < 1. For x > 0, define

v(x)

1

x

u(y)dy f'[u(x) -u(y)]dy=u(x)-J x X

o

and

w(x) = r°° X

V

dY Y

Since v'(x) = u'(x) - x-1v(x) and w'(x) = -x-1v(x), we see that

u'(x) = v'(x) - w'(x) forx > 0. Furthermore, u has compact support, and both v(x) and w(x) tend to zero as x tends to infinity, so

u(x)=v(x)-w(x) forx>0. 'By the Cauchy-Schwarz inequality, Iv(x)12 <

x

f

Iu(Y) - u(x)12 dY,

0

implying co x-l-2s

00

x-2SIv(x)12dx < fo fo

=

f

f X Iu(Y)

u(x)12dydx

0

x-1-2slu(Y)u(x)12dxdy y

°° Iu(x) - u(Y)12

°° Jo

Jo

Ix - y11+2s

dxdy

94

Sobolev Spaces

for 0 < s < 1. By Exercise 3.20, °O

1

x-2slw(x)I2dx < /

00

1

(2

- s)

fors <

x-2slv(x)I2dx

I':

z'

and the first part of the lemma follows. One easily verifies by Taylor expansion that v(x)

0 as x -* 0+, so w(x) _ v (x) - u (x) -+ -u (0) as x -* 0+. Thus, if u (0) = 0 then w (0) = 0, implying that

w(x)=w(x)-w(0)=w(x)-V(Y)dy=- f x!(Y)dY J0° Hence, by Exercise 3.20,

I

00

x-2slw(x)l2dx <

f

I (s-

y

Y

Jo

00

2

x-2slv(x)I2dx

fors >

2'

2)

giving the second part of the lemma. Lemma 3.32 If S2 is a Lipschitz domain and u E E) C2), then

fn

dist(x, I')-2slu(x)I2dx < CIIuIIH,( for0 < s < Z < s < 1.

If, in addition, u = 0 on T, then this inequality holds also for 2

Proof. We prove the result for S2 a Lipschitz hypograph given by x, < (x'). If y E I' and M is a Lipschitz constant for , as in (3.27), then yn = f (y') and so

VX') - Xnl = IYn - X. + (x') - (Y')I < Ix,1 - Yni + Mix' - Y'I <

1+M2Ix-yl,

implying that Xn dist(x, r) > (x') 1+M2

for X E 0.

5 <;(x') f

Using the substitution x _ (x') - t, followed by Lemma 3.31, we see that

J

dist(x, r)-2slu(x)l2 dx < (1 + M2)s f

=C u

[

(x') -

jt'Iu(x'(x') - t)12 d t dx'

Lipschitz Domains

I

C

R"-t

95

r

r

Y<{(x')

z<M')

Iu(x' ,

y)-u(x'

,

z)12

Iy - z11+2s

x dydzdx', so if u = UIn where U E D(R"), then, arguing as in the proofs of Lemma 3.15 and Theorem 3.16,

1

dist(x, I')-2jlu(x)12 dx < C J

R

I U(x', x"I i h

U(x) 12

dx dh

JJ

f

00

_ C J R" I U(h)f'`

Ihll+zs

00

=cJR-

dh d


and the result follows because D(RI) is dense in H' (R ?)

Notice that the value s = 1 is excluded in the two lemmas above; cf. Exercise 3.22. Also, recall our earlier discussion of the imbedding (3.24). Theorem 3.33 Lets > 0. If S2 is a Lipschitz domain, then

P(Q) = fu E L2(52) : u E H'(R")) C Hp(S2), where u denotes the extension of u by zero:

u(x) =

u(x)

if x E 92,

0

ifxER"\S2.

In fact,

H's(Q) = Ho(S2)

provideds 0 {2, 2, 2,

}

Proof. For the moment, we think of the elements of H' (S2) as distributions

on R. If U E Hs(S2), then the restriction v = ulst belongs to L2(S2), and u = v as a distribution on R", so D E H'(R"). Conversely, if u E L2(S2) and u E H' (R"), then supp u c S2, so u E H = HS (S2). We have already seen that HS (S2) c _Ho (S2).

Now view HI(Q) as a subspace of L2(c2), and let u E D(S2). For any integer r > 0, Theorems 3.16 and 3.30 give IIuIIHr(p) = IIuIIHr(R")

IlaauIILz(R") Ial5r

=

IIUI1Hr(si),

-

Ila"uIIL,(n) IaI
96

Sobolev Spaces

so Hr(0)=Hp(0).For s=r+µwith 0

I

+

Ix -

xR

IaI=r

a

_

aau(x) - aau(y)l2

dx d y

l aau(X) - aau(y)12

2

Ila uIILZ(sz) Ial=r

+

y12µ+n

Jf2 xf2

Ix - y12µ+n

dxdy

1 aau(X)12 dx dy Jf2x(R11\s2) IX - yl2IL+n IaI-r

+

laau(y)12 Ian=r

(R"\12)xS2 Ix - yl2u+n

dxdy

= Hull W$(Q)+2 E J laau(X)I2wµlX)dX, IaI=r

2

where the weight w12 is defined by

dy

wµ(x) = fR,l\f2 lx - y12µ+n

for x E Q.

Introducing polar coordinates about x, we see that

wµ (x) < C dist(x,

I')-24

for X E S2,

so by Lemma 3.32, "(S2) H < C1,11U112..(n) 1: f w(x)laau(x)12dx < CN, E IlacU112 IaI=r

IaI=r

provided s

integer + z . Hence, in this case, Ho (2) c Hs (Q).

Sobolev Spaces on the Boundary Any Lipschitz domain SZ has a surface measure a, and an outward unit normal v

that exists a-almost everywhere on F. In fact, by Rademacher's theorem [83], [ 105, Theorem 11 A, p. 272], if lR' ' -->. R is Lipschitz, then is Frechetdifferentiable almost everywhere with Ilgrad0lLo.(w"-I) < M,

Sobolev Spaces on the Boundary

97

where M is any Lipschitz constant for , as in (3.27). If 0 is the Lipschitz hypograph (3.26), then

do:, =

a (x'), 1) 1 + grad (x')12 dx' and v (x) = (- grad

for x E F. (3.28) The divergence theorem can then be proved in a straightforward manner.

Theorem 3.34 If 0 is a Lipschitz domain, and if F : R" -+ R" is a C' vector field with compact support, then

I divFdx=J

r

Proof Assume to begin with that 0 is a Lipschitz hypograph (3.26). For 1 < k < n - 1, we define Uk : R11-1 -+ R by Ox')

U k (x') =

J

Fk (x', x,,) d x , , . 00

f

akuk(X') = Fk(X',

J

S(-x')

8kFk(x)dxn, 00

and fR-,-, ak uk (x') dx' = 0 because Uk has compact support. Thus,

I

<('(x')

akFk(x) dx = -

f "- Fk(x',

--

dx' for 1 < k < n -

with

f

a,, F.(x)dx= f

Fn(X',y(X'))dX,

so that

jdivF(x)dx z

= fat-- F(x',

x')) (-grad (x'), 1) dx' =

JF. v da.

Now let 0 be a Lipschitz domain, and take a partition of unity (.0j) J_o for S2 as in the proof of Theorem 3.29. Since q5o E D(22), it is obvious that

f

ak(0OFk) dXk = O, 00,

sr Sobolev Spaces

98

so fn div(00F) dx = 0. Hence, from the case of a Lipschitz hypograph treated above, J

f

J

r

r

divFdx=>2J div(OjF)dx=>2J v- (b1F)dcr= j v Fdc,

a

If c2 is a Lipschitz hypograph, then we can construct Sobolev spaces on its boundary I' in terms of Sobolev spaces on R"-1, as follows. For U E L2(F) _ L2(F, Q), we define

forx' EI[8", put

for0 < s < 1,

HS(T) _ {u E L2(I') : u E HS(R"-')) and equip this space with the inner product (u, v)Hs(r) _ (u;, VC) H' (R"- 1)

Recalling that dci is given by (3.28), we put IIu1IH-q(r) _ (Iut

for0 < s < 1,

1 + Igrad

and then define H-S(l') to be the completion of L2(F) in this norm. It follows that H-1(F) is a realisation of the dual space of HS(F), with sup

IIuIIH-5(r)

I(u, v)rI

OovEH'(r) IIVIIH'(r)

=

I(u, v)rI

sup o#veH'(r) IIUIIHtr)

for. IsI < 1,

where

(u, Or =

Jr

u(x)v(x)da(x) and (u, v)r =

Jr

u (x) v (x) da (x).

If K (Sl) is a Lipschitz hypograph for some rigid motion K : R" --+ ]R", then we define HS(F) in the same way except that u[K-1(x', Ox'))}.

Suppose now that SZ is a Lipschitz domain. Using the notation of Definition 3.28, we choose a partition of unity 10j) subordinate to the open cover ( Wj )

of F, i.e., we choose O j E D(W j) satisfying > j 4 (x) = 1 for all x E F. The

Sobolev Spaces on the Boundary

99

inner product in Hs (r) is then defined by (u, V)Hs(r) _

(Oiu,fj v)H-(r1),

(3.29)

where r, = 8 S2,. Theorems 3.20 and 3.23 imply that a different choice of { W, },

{S2, } and {0, ) would yield the same space Hs (r) with an equivalent norm, for Is l < 1. If 0 is C't-" fork > 0, then HS (r) is well defined for Is l < k. We shall also require Sobolev spaces defined over only a part of the boundary

of n. Consider a disjoint union

r=r1UIIU1-2,

(3.30)

where 1`1 and 172 are disjoint, non-empty, relatively open subsets of r, having 11 as their common boundary in r. When S2 is a Lipschitz hypograph, we call (3.30) a Lipschitz dissection of r if there is a Lipschitz function Q : Ri-2 -+ R such that

{x E r : xi_1 < Q(x")},

TI= 172= {x Er:xi_1 >Q(X")),

where x" = (x1, ... , xn_2); for n = 2, the function q reduces to a constant. In the obvious way, we extend the notion of a Lipschitz dissection to the case when S2 is the image under a rigid motion of a Lipschitz hypograph.

Next, suppose that n is a Lipschitz domain. We say that (3.30) is a Lipschitz dissection of r if, in the notation of Definition 3.28, there are Lipschitz dissections 8 S2, = r,, u l1, U r2, such that

W,nr1 = W,nr1,,

W,nfI= W,nII,, W,nr2= W,nr2,,

for all j. We remark that, in this case, the subsets r 1 and 1`2 are not necessarily

connected. LetD(r1) = 1-0 E D(r) : supp0 c r1}; by defining

Hs(r1) = {U1r, : U E Hs(r)), Hs(171) = closure of D(171) in HI (r),

Ho (r) = closure of D(rI) in Hs(ri), the properties of Sobolev spaces on Lipschitz domains in R carry over to Sobolev spaces on r1, subject to the condition that Is I < 1, or Is I < k if (3.30) is Ck-1.1 in the obvious sense.

Sobolev Spaces

100

The Trace Operator In studying boundary value problems, we shall need to make sense of the restriction u I r as an element of a Sobolev space on r when u belongs to a Sobolev space on 7. The main idea is contained in the following lemma.

Lemma 3.35 Define the trace operator y : D(IR") -* D(IR"-') by

yu(x) = u(x', 0) forx' E

IR

n-

Ifs > 2, then y has a unique extension to a bounded linear operator

y : H$(1R") -4 H" '/2(1R"-'). Proof. For u E D(1R"), the Fourier inversion formula (3.15) gives

f

Yu(x') = f,'

u(',n)

(f

dt = J

f

"

oo

and so 00

Yu(')=J 0000 u(', n)dSn=J

(1+1 12)-S/2(1+1 12)s'%u 00

Applying the Cauchy-Schwarz inequality, we obtain the bound

f

W

(1 +

where, using the substitution t;,, = (1 + oo

Ms( ') =

1W1I2)'/2t,

f

00

dtn

00 (1+I 112+I n12)S

(1 +I

112)S-1/2

The integral with respect to t converges because s >

dt (1+t2)S.

oo

so if we write MS =

MS (0) then

(1 +

MS

f

(I +

do

00

Integrating over ' E 1R" gives MSIIUIIHs(Rn),

and since D(1R") is dense in H5 (R"), we obtain a unique continuous extension

for y.

The Trace Operator

101

The lemma above is sharp in the sense that

Hs-l/2(R"-') = {yu : u E HS(R")) for s > 1, because y has a continuous right inverse rio, as we now show.

Lemma 3.36 For each integer j > 0, there exists a linear operator

77j:S(1R"-')-* S(R") satisfying

a" (rij u) (x', 0) =

8",u(x')

if a = j,

0

if

for x' E Ri-', U E S(R"-)) and any multi-index a = (a', a"). Moreover, rij has a unique extension to a bounded linear operator i7 j :

Hs-j-1/2(Rn-i) -+ H' (W') for S E R.

Proof Choose a function O j E D (R) satisfying 9 j (y) = yj /j! for I y j < 1, and define z1

u(x) =

dl;' forx ER".

(1 +

JR1

Since 9j(k) (0) = S jk, we see that

aa(77ju)(x', 0) =

J

j

gives

as required. The substitution x = (1 +

11 u() _

(1

+ ,i )j/2

a"'u(x')s j"

ei2nt' X'

f4 (

L(1 + I

I)

x] dxn

j[(1 +

_

(1

gives

and the substitution 4n = (1 +

4-1 X

J

I

,12)1+l

[(1+1 12)-i/2 n]I2d ndS 00

Sobolev Spaces

102

where 00

CS = J 0 (1 +t2)SIdj(t)I2dt < oo,

for all s E R. For Sobolev spaces on domains, we can now prove the following.

Theorem 3.37 Define the trace operator y : D(S2) -+ D(F) by

Yu = uIr If SZ is a

Ck-1,1 domain,

and if 2 < s < k, then y has a unique extension to a

bounded linear operator

y : H$(Q) -+

(3.31)

HS-112(r),

and this extension has a continuous right inverse.

Proof Since H5(]R") is invariant under a Ck-1.1 change of coordinates if 1 - k < s < k, one sees, via a partition of unity and a local flattening of the boundary, that if z < s < k then IIYUIIHs-1/2(r) <_

CIIUIIHs(R'

if u = Uisi for U E D(R").

Hence, IIYuIIHs-112(r) < CIIuIIHscQ> for all u E D(O), and we obtain a unique continuous extension because D(S2) is dense in Hs (S2). A right inverse for y can be pieced together using the same partition of unity, by means of the operator '1o from Lemma 3.36.

The preceding theorem applies, in particular, for 1 < s < 1 if 0 is a Lipschitz domain. For technical reasons, we shall require the following, stronger result of Costabel [14].

Theorem 3.38 If S2 is a Lipschitz domain, then the trace operator (3.31) is bounded for 1 < s < z Proof. It suffices to consider a Lipschitz hypograph (3.26). Let U E D(1R"), and put

u(x) = u (x', (x') + x") for x = (x', x")

E lR".

The Trace Operator

103

By definition, IIYUIIH'-112(1) =

and to estimate the right-hand side, we introduce the notation 00

u(x', n) = f

x,) dx, 00

for the partial Fourier transform of u (x) with respect to x12.Observe that uC(x', 412) = ei2- ,,C(x')u(x', n), so

n)IIL2(R"-') = Ilk', n)IIL,(R"-') and

n)IIH< Cliu(,

C ,ZIIu(,

n)I12

00

IIuIIEs = f

n)I1Hl(R°-1)]d

,t

00

f then

where as(h) = I nI25 + I nI2s-2(1 + RUCHES <_ CIIu11E'

fors E R.

It is easy to see that

fors > 1,

11uI1E5 < CIIu11Hs (R.")

and we claim

IIu(,

CIIuflE,

In fact, the substitution n = (1 + d

f7a, (

" = C5(1 + )

1

,12)-(s-1/2),

for z < s < Z.

yields where CS =

f

00 00

t -2(l+ t t2)'

104

Sobolev Spaces

with C, < oo for 2 < s < 2, so, applying the Cauchy-Schwarz inequality,

Ilu(,

0)II2

Hs-1i2(Ra-1)

f

J R°-r

(1

J - -l

(1 +

I

hI2)s-I/2I f

2

00

u( '> n) dSn 00

f (J-00 as ()

)

00 a,()II ( )12dn)

d'

00

=Csf as()Iu()12d =C'11U112Es 1'

Thus, we see that Ilut(, 0)IIHf-II2(RI-r) -< CIIul1El < C11U11El < CIIUIIHS(R")

for 1 < s < 2

which, combined with Theorem 3.37, shows that the trace operator (3.31) is

bounded for 1 < s < 2 . The next lemma is a version of a standard fact [41, p. 47] about distributions supported by a hyperplane, and will allow us to characterise Ho (S2) using the trace operator. The symbol ® means the tensor product of distributions, so, formally, (vj ® SWjW)(x) = vj(x')SWD(x"). In the proof, we use the notation R+ = {x E R'r : x" > 0) for the upper half space.

Lemma 3.39 Consider the hyperplane F = {x E R" : x = 0).

(i) Ifs > - 2, then HF = {0). (ii) If s < - 2, then HF is the set of distributions on R" having the form

u = E uj ®S(j)

with vj E

H''+j+l/2(R'r-t).

(3.32)

0:5j<-S-1/2

Proof. First we show that any u of the form (3.32) belongs to Hi.. Obviously, supp u c F, and since {v j (x')S(j) (xn)) = D j (') (i2ir n)j, we have I1vj ®3(j,112

R) =

f(l + n

The substitutions = (1 + 1'12)I/2t gives vj

®scj>II 2 Ht(R")

where Ci.,s =

f

=

00

(1 +t2y12rrt12' dt,

J 00

and here Cj,, < 00 for s + j < - Z , so u E Hi..

Cj,sIIVjIIHs+i+h/2(R"-1),

(3.33)

The Trace Operator

105

Next, we show that if u E HF, and if 0 E D(R") satisfies

8;¢(x',0)=0 for0< j < -s - Z, then (u, 0) = 0. Indeed, by Exercise 3.22, if we define

0(x) ifx E R't, 0

otherwise,

then 0± E H(R). It follows that there is a sequence (0)n° 1 in D(R \ F) converging to in H_s (R") as m -+ oo. Hence, (u, 0) = Urn,. (u, ¢,") = 0. In particular, u = 0 if u c- HF. for s > - ? . Suppose now that u E H F . with -k - 2 < s < -k - f o r an integer k > 0, z and assume 0 < j < k. Let ri; be as in Lemma 3.36, and define v; E D* (][8"- ) by

(v1,4) _ (-1)j(u, rl;0) for d E D(R't-'). Observe that I(v;, 0)1 <_ IIu11Hs(R )II?1;OIIH-J(ut't) <_ so IIVi IIH=+;+U=(R

Il2(RI-I),

') < CIIuIIHI (tt"), and that k

u-

(u, p)

vi

for 0 E D(R")

;-o where k

p = 0 - E'1;>/il with *;(x') = dO(x', 0). ;=o

Since 8; p (x', 0) = 0 for 0 < l < k, and since -s - z < k + 1, we have (u, p) = 0 and so (3.32) holds.

It only remains to deal with the case s = -k - 2. The argument above HFk-"2 shows that if u E then u = I _O v; ®S(J) with v; E Hj-k(IEP"-') for 0 < j < k - 1, and with Vk E H-E(IRH_L) for any E > 0. Thus, it suffices to show that vk = 0. In fact, (3.33) implies v; ®S(j) E for 0 < j < k - 1, giving Vk ®S(k) E H-' '/2 (R"). However, 2 -k-J/2-. IIv k ®S (k' lIH

and

, = k,_k_1 2_E IIv kII HC'

oo as c --> 0, giving the desired result.

Theorem 3.40 Assume that cZ is a Ck-1 1 domain.

i

H-k-1/z(Wi)

106

Sobolev Spaces

(i) If 0 < s < 2, then Ho (1) = HS (S). (ii) If 1 < s < k, then Ho (S2) = {u E H'(S2) : y (8au) = 0 for J a < s - ? Proof It suffices to deal with a half space Q = R+. We will use the characterisation of the dense subsets of a Banach space given by Exercise 2.5. First suppose 0 < s < z . If W E HS (7)* = H-S (S2) satisfies (w, -0) = 0 for all q5 E D(S2), then supp w is a subset of the hyperplane F = {x E R" : x" = 01, and we conclude from part (i) of Lemma 3.39 that w = 0. Hence, D(E2) is dense in HS (S2), i.e., Ho (S2) = HS (S2).

Next suppose that s > Z, and let E = {u E HS(7) : y(8au) = 0 for (aI < }, noting that this definition makes sense because y o 8' H' (Q) -z HS-111(F) for kal < s - 2. Let f E E* satisfy £(o) = 0 for all ¢ E D(Q). By the Hahn-Banach theorem, there is a w E HS (S2)* = H-S (S2) such that f(o) = (w, gyp) for all 0 E E. Since W E HFS, part (ii) of Lemma 3.39

s-

shows that w = Eo<j<s-1/2 Vi ® 3(j) with vj E

H-s+j+1/2(R"-1)

Hence, for

every q5 E E,

> (-l)J(vj, Y(3

)) = 0,

o<j<s-1/2

and so D(S2) is dense in E, proving part (ii).

0

Vector-Valued Functions Thus far, the present chapter has dealt only with spaces of scalar-valued (generalised) functions. The results obtained extend in a straightforward manner to spaces of vector-valued functions

u: S2-+ c", and this final section does no more than establish some notational conventions. We denote the space of compactly supported, C"'-valued, C°O test functions by

D(Q)," = D(S2; C').

The (sequentially) continuous linear functionals on D(O)"' are then the ("valued distributions on 0, and we view these objects as generalised C"'-valued functions, by writing

(u, v)n = 1 u(x) v(x) dx,

Jn

(3.34)

where the dot denotes the bilinear form on cm whose restriction to R" coincides

Exercises

107

with the standard Euclidean inner product, i.e., "1

U.V=EuJVJ. j=1

The set of all Cm -valued distributions on SZ is denoted by D* (0)"' = D* (S2; C'").

We think of u as a column vector or m x I matrix, and let u* denote the row vector or 1 x m matrix obtained by transposing the complex conjugate u. Using matrix multiplication, we may then write the standard unitary inner product in CC' as m

u*V=U.V=Eujvp I=1

In this way, the sesquilinear form associated with the bilinear pairing (3.34) is given by

(u, On =

u(x)*v(x) dx. fn

Of course, if u and v are square-integrable functions from S2 to CC', then (u, v)n is their inner product in L2 (S2)m = L2 (S2; C"'). The definitions of the vector Sobolev spaces on S2, W'(S2)' = Wp (S2; (C'" ),

H3 (S2)" = HS (S2; (C'"),

HS (S2)m = HS (S2; (Cm),

should now be obvious. Likewise for the vector Sobolev spaces on r. Occasionally, we shall encounter normed spaces of matrix-valued functions, such as L,, (S2)mx,n = L,,(12; C">°"), whose meaning should also be obvious.

Exercises 3.1 Suppose that u E Lp(S2) satisfies I(u, v)nl < MIIvIILp.(n)

for all V E Lp.(S2).

(i) Show that if 1 < p < oo, then II u 11 L,,(sa) < M. [Hint: take v = ] sign(u) lulp-1

(ii) Show that if p = oo, then for every measurable set E C 0 with I E l > 0, the mean value of l u I over E is bounded by M, i.e., E1

I11JElu(x)Idx<M.

Deduce that 11U IIL (n) < M. [Hint: take v = sign(u) XE, where XE is

the characteristic function of E.]

Sobolev Spaces

108

3.2 Prove that convolution is associative:

(u*v)*w=u*(v*w) foru,v,wEL1(R") 3.3 For 1 < j < k, let f j E L 1(R") be a compactly supported, non-negative 1, and let 0 < X j < 1. Fix X E 1I8", and

function satisfying II fj II L,

define

g(A)=(fi' *...* f,R)(x) forA=(At,...,Ak). (Take f to be identically 1 outside as well as inside supp f3.) ° that g (e j) = 1 where ee j E Rk is the vector with compo(i) Show nents (ej )1 = 1 - S jl. (ii) Use the fact that, for any positive a j and any non-negative A j and µj, k

k

k

j=1

j=I

j=1

H ajt-r)xj+ruj = exp (1 - t) L log a^' + t L log aµ' to show that the function g : [0, I ]k --> [0, oo) is convex. (iii) Deduce that g(A) < 1 if At +...+Ak = k -1. [Hint: A Aj)ej.] (iv) Hence show that k

(1-

1

if E-=k-1. j=1;pj 3.4 Show that supp(u * v) c supp u+ supp v = {x + y : x E supp u and y E supp U).

3.5 Recall the notation (3.7). (i) Show that

(d)k dt

u(x + ty) = u(k)(x + ty; y).

[Hint: k!/a! equals the number of permutations of k = IaI objects when there are a j objects of type j, for I < j < n, and it is assumed that objects of different types are distinguishable, but objects of the same type are indistinguishable.] (ii) Use integration by parts to verify Taylor's formula for a function of one variable: k

f (s) =

f(j)(0)

E j j=o

1

Sk+t

Si +

k1

1

J

(1 - t)k f(k+I)(ts) dt.

Exercises

109

(iii) By taking f (s) = u(x + sy), derive Taylor's formula (3.8) for a function of n variables.

3.6 Define f : R -+ R by

f(t) =

e-' 1'

10

if t > 0,

ift<0.

(i) Show that f (i) (t) -* 0 as t y, 0, for each j > 0. (ii) Deduce that f E C°°(R).

(iii) Construct a CO0 function g : IR - R with g > 0 on (-1, 1) and with supp g = [-1, 1]. (iv) Construct a COG function * E C mP(R") satisfying (3.9). 3.7 Let S2 = (0, 1), choose any 0 E D(S2) not identically zero, and define

¢j E D(S2) by 0, (x) = 0 (j -' x). Show that -Oj -+ 0 in E(Q), -but not in D(S2).

3.8 Establish that the inclusions D(S2) C E(S2) and D(R'1) C S(R") E(1E8") are continuous with dense image, by proving each of the following statements:

(i) If ¢j - 0 in D(S2), then qj -+ 0 in E(S2).

(ii) If 4i -+ 0 in D(R), then ¢f - 0 in S(R"). (iii) If 4j -* 0 in S(R"), then Oj - 0 in E(R"). (iv) Let Ki C K2 C be an increasing sequence of compact sets whose union is S2, and let Xi E D(S2) satisfy Xi = 1 on Kj. If 0 E E(S2), then Xicb -+ 4) in E(S2).

(v) Let X E D(W) satisfy X (x) = 1 for IxI < 1, and define Xf E D(R") for each positive integer j by X,i (x) = X (j _'X). If 0 E S (W), then

XjO -* 0 in S(W). 3.9 Consider a linear functional f : D(S2) -+ C. Show that a is sequentially continuous (and hence a distribution on S2) if and only if for each compact set K C S2 there exists an integer m > 0 such that

It(4))I -S CK,," E sup laaol for all 4) E DK(S2). Ia1
[Hint: to prove the necessity of the condition, suppose for a contradiction

that there is a K for which no such m and CK,,,, exist, and deduce the existence of a sequence c 0 in DK(S2) such that £(4j) = 1.] 3.10 Prove from the definition (3.12) that if u E D*(W) and 0 E D(R' ), then

u*0isC°O,with 8a (u * 0) = (a' u) * 46 = u * (a"4)).

Sobolev Spaces

110

3.11 Show that

.Fx,

'1 {e-n1x1' 1 =

l

J

J

1

.%_)

00

e-i2n jxj-nx dx = e-nl J

l''

00

3.12 For * E L) (RI), show that (E-lx)l)

_

and

3.13 Let k be a positive integer. We denote the kth-order forward difference operator by 8 , and then define the kth-order L2 modulus of continuity by k (t, a) u) = Sup II SI U II Lz (RI I)

for t > 0.

IhI
(i) Adapt the proof of Theorem 3.16 to show that if 0 < s < k, then 2

2 IIuIIHA(R")

ti IIuIIL2(R") +

f

2

Ilsh uiiLZ(R,,) " IhI2T+n

dh.

(ii) Show that [cvk(t, u)]2 < Ck J

(iii) Deduce that for 0 < s < k, kU I

u L,(R. 11

fRIhI'-s+n

) dh

f

00

[COk(t' u)]2 t2s+)

dt

00

r l221s[cok(2-j, u)]2. j==-oo

3.14 Let Xj E D(]R") be as in part (v) of Exercise 3.8, and lets E R. Show that if u E Hs(]R"), then Xju -3 u in Hs(IR") 3.15 Consider a distribution u E V* (0) with supp u c K C= Q. (i) Show that there is a unique u E D*(]R") satisfying It = u on 0, and u = 0 on 1R" \ K. [Hint: use a cutoff function X E D(Q) with X = 1 on K.] (ii) Show that if s E ]R and u E Hs (S2), then II u II Ha (Ruu) < Cs. K II u II Hs (n)

3.16 Give an alternative proof of Theorem 3.20 for 0 = R", as follows.

Exercises

11 l

(i) Prove Peetre's inequality:

fore, n E R' ands E R.

(1+1e12)s < 21s'(1+11; _1 I2)1sl(1+InI2)s

(ii) Use the relation 4u =

* u to deduce that if u E Hs(R'), then

Ou E Hs(R") with II0UIIH.'(Rn) < CsIIUIIH.(Rf), where Cs = 21sJ12

f

(1 + I

de.

3.17 Let * and *' be as in (3.9) and (3.10). (i) Show that if u E D* (RI), then the convolution uE = Vrr * u belongs to £ (Rn) and

supp uE c {x E R" : dist(x, supp u) < E}. (ii) Lets E R, and show that if u E Hs (R71) then and

IIUEIIH-(R'I) <_ IIuIIH-I(R'I)

l o IIuE - UII HS(R.,) = 0.

3.18 Show that if S2 is the crack domain shown in Figure 2(ii), then D(S2) is not dense in HI (Q) for s > n/2. 3.19 Let U E V* (Q) and S E (i) Suppose W is an open set and X E E) (W). Show that if u E HI (w n 0), then XU E HI (0) and 11Xu1IH,(92) < Cx,s1Iu1IHs(wns ).

(ii) Suppose (¢i )

is a partition of unity of the type used in the proof of Theorem 3.29. Show that u E H-'(9) if and only if 95i u E Hs (Wi n o)

for 0 < j < J, in which case I IIUIIH=(n)

^' L .i=o

3.20 Prove the following inequalities, due to Hardy: for a > 0 and 1 < p < oo,

dY\ dx LJ'(x-" 0

Jo

X

If(Y)I Y

I/P

<

x

a

f

IY-"f(Y)IP

dy1'lP

o

JJ

and

00( CJo

Cx",1

d

(oo

If(Y)I

PdxlhhP

y) x

J

1(foo < a

d

1/P

.

ly"f(Y)IP y

l

[Hint: make the substitution y = xt in the inner integral, and then apply Minkowski's inequality, i.e., think of t H f (- t) as a map from (0, 1) or (1, oo) into a weighted LP space on (0, oo).]

Sobolev Spaces

112

3.21 Let1
fb`

p

p x-a f a If(t)I dtl/ dx < ( p- 1

b

p

If(t)Ipdt,

I

Ja

1

f (b -x , If(t)I dt)pdx < \

u

p

/paIbIf(t)Ipdt

.p-

[Hint: use Exercise 3.20.] (ii) Show that, for u E D(R2), fffb a

fblu(x,x)-u(Y,Y) p('Jdx)(-v/-2 dy)

x-Y

a

(p2p 1

)'f'f

Y)I P+Iazu(x,Y)IP]dxdy.

u(x, x) - u(y, y) = fx a2u(x, t) dt + f: aIu(t, y) dt y <x.] [Hint:

for

(iii) Let yu(x') = u(x', 0) for x' E R"-1 and u E D(IR"). Show that

ff , -,

IYu(x') - Yu(Y')I p dx'dy' < C,,,, Ix' - y' I p

J

i=

R

18fu(x)Ip dx.

(iv) Show that, for u E D(IR"), IIYUIIL,,(W'-1) < CIIUIIW;(R")

8 (X u) (x) dx for a suitable function

[Hint: write y u (x') X(X") .1

(v) Deduce that y : WW(R")

for each integer k >"0.I.

3.22 Consider the half space Q = {x E R,1 : x" < 01. Let U E D(S2), and define U(X)

U (X) =

if x" < 0,

0

(i) Show that Ck."(1 + It'I)-k(1 + 14"1) - I for every k > 0. (ii) Hence show that U E Hi = HS (S2) for s < 1

(iii) Show that if a,u(x', 0) = 0 for 0 < k < j, then U E Hr (S2) for s < j + 3 .

4

Strongly Elliptic Systems

We are now ready to begin our study of boundary value problems for linear elliptic systems of second-order partial differential equations. The first task is to explain how, via the first Green identity, such problems fit into the abstract scheme treated in Chapter 2. We then define the class of strongly elliptic operators, and investigate when such operators are coercive. After that, an existence and uniqueness theorem for weak solutions in H' (S2)" is given, expressed in the form of the Fredholm alternative. Next, we prove regularity of the solution on the interior and up to the boundary, under appropriate assumptions on the data and the domain. We also prove the transmission property, which will be used later to show regularity at the boundary of surface potentials for smooth domains. The final section of the chapter presents some rather technical estimates relating the H1-norm of the trace and the L2-norm of the conormal of

derivative. These estimates will allow us to prove some limited regularity of surface potentials for Lipschitz domains.

The First and Second Green Identities Suppose that Q is a non-empty open, possibly unbounded subset of ll8", and consider a linear second-order partial differential operator P of the form n

it

It

Pu=->>8J(Ajkaku)+j:AjBJu+Au onc2,

(4.1)

j=1

j=1 k=1

where the coefficients

Ajk = [apgJ,

AJ

= `a',q],

A = [apgl

are functions from S2 into C""", the space of complex m x m matrices. Thus,

I < p < m and 1 < q < m, and P acts on a (column) vector-valued function 113

Strongly Elliptic Systems

114

U : Q -- C'" to give a vector-valued function Pu : cZ -,, Cm, whose compo-

nents are M

M

(POP

- L+ L Lr nn

nn

aJ (ap4aku4) +

j=1 k=1 R=1

nn

j=1 q=1

M

ap9u9

ap9aju4 + 9=1

fort

r

12

D(u, V) =

J

(

n

n

n

E E(Ajkaku)*ajv + J:(Ajaju)*v + (Au)*v dz.

(4.2)

j=1

j=1 k=1

(Recall that * denotes the conjugate transpose of a matrix or vector.) It will always be assumed that the coefficients A jk, A j and A belong to L,"' (S )"'X'n, so that 0 is bounded on HI (Q)m: 14) (u, v)I

_

CIIu1IH1(92)'" IIvIIH- (a)

foru, V E HI(S2)m.

If, in addition, the leading coefficients A jk are Lipschitz, then P : H2(Q)"' -± L2 (2)' is a bounded linear operator. When the lower-order terms are dropped from P, we are left with the principal part Po, which can be written in divergence form as n

Pour

where 13ju = EAjkaku. j=1

(4.3)

k=1

If 0 is a Lipschitz domain, then the conormal derivative

>2 vjy(Sju) on I',

is defined by (4.4)

j=1

where, as usual, v is the outward unit normal to 0, y is the trace operator for 0, and r = 8S2 is the boundary of Q. The conormal derivative arises naturally via the following lemma, known as the first Green identity. Lemma 4.1 If S2 is a Lipschitz domain, and if the coefficients Ajk are Lipschitz, then

1'(u, v) = (Pu, v)o +

yv)r

foru E H2 (0)"' and V E HI(S2)m

The First and Second Green Identities

115

Proof. By the divergence theorem (Theorem 3.34), if w E C.IpmP(S2) then

I 8jwdx = Jr

vj wda,

and one sees with the help of the density and trace results in Theorems 3.29 and 3.38 that this formula holds in fact for any w E H 1(S2). Taking w = (,t3 j u)*v, we obtain n

a [(B;u)*v]dx = fr vjy[(Bju)*v]dc

J

for U E H2(0)"' and V E H (SZ)n',

and the result follows after summing over j, because by (4.3), n

n

aj[(Bju)*v] = -(Pou)*v + 1:(Bju)*ajv. j=1

J=1

0

In order to state a dual version of Lemma 4.1., we define It

Bju = EAkjaku+A*u, k=1

and put n

n

n

aku) - Eaj(A*u)+A*u

P*u = j=1 k=1

j=1

n

_-E8jBju+A*u on S2, j=1 and

_ B vu =

n

E vjy(Bju) on P.

(4.5)

j=1

In fact, by arguing as before, but now with w = u*B j v, one easily verifies the following identity. Lemma 4.2 If c2 is a Lipschitz domain, and if the coefficients A jk and A j are Lipschitz, then

4 (u, v) = (u, P*v)n + (Yu, Bvv)r

foru E H1(S2)m and V E H2(c2)n'.

Strongly Elliptic Systems

116

Thus,

(Pu, v)n =' (u, v) = (u, P*v)Q because yv =

for U E Hz(S2)'" and V E D(S2)"',

0 on T. Hence, if u E H1(S2)"', then we can define Pu

as a distribution on S2 by

(Pu, v)n = t (u, v) for v E D(c2)'", even if the coefficients Ajk are not Lipschitz, but only belong to Loo(S2)''"Likewise,

we can define the distribution P*u for any u E H 1 (S2)' by

(P*u, v)u = (D*(u, v)

for u E D(S2)'".

The operator P* is called the formal adjoint of P. Its principal part is given by n

n

!t

(P*)ou=-E1: aj(A*

j=1

j=1 k=1

which coincides with the formal adjoint of Po, allowing us to write

Po = (P*)o = (Po)*. However, the conormal derivative of u relative to P* is n

n

vjy(Axjaku) = 9,u -

vjy(A!u), j=1

j=1

which coincides with I3,u if and only if A j = 0 for all j. One says that P is formally self-adjoint if P* = P, i.e., if the coefficients of P satisfy

A* = Ajk, In this case, l3

Aj = O,

A* = A.

(4.6)

13, and the sesquilinear form (4.2) is Hermitian, i.e.,

(D(v, u) _ 4(u, v)

for u, v E H'(SZ)"'.

The next lemma will allow us to extend the definition of the conormal derivative.

Lemma 4.3 Suppose that S2 is a Lipschitz domain. If U E H1(S2)m and f E H-I (Q)m satisfy

Pu = f

on 0,

The First and Second Green Identities

117

then there exists g E H-1/2(r)'" such that

0(u, v) = (f, v)n + (g, Yv)r for v E

HL(S2)m.

Furthermore, g is uniquely determined by u and f, and we have IIgIIH-"2(r)" < C

IIUIIH'(2)1° + C11f 11x-I(ny

Proof By Theorem 3.37, there exists a bounded linear operator n : H 1 /2 (r)^' HI(E2)1 satisfying v for all v E H'/2(r)"'. Since [Hl(S2)"']* _ H-' (S2)"' and [Hh/2(r)"']* = H-1/2(11)"', we can define g E H-'/2(11)'" by

(g, w)r = 0 (u, 77 w) - (f, r)w)a for w E Ht/2(11)'". Given V E H1(c2)"', consider the function vo = v - 77y v. Since yvo = 0, we have vo E Ho (S2)'" by Theorem 3.40, so there is a sequence o in E)(0)"' that converges to vo in H 1 (0)1. Hence, using the fact that Pu = f on Q,

c(u, vo) = h

(D(u, 0;) =1lim (f, 0,i)s2 = (f, vo)Q,

and by the definition of g,

1(u, v) = (D(u, vo + )7Yv) = (f, vo)n + (g, Yv)r + (f, r1Yv)o

= (f, On + (g, Yv)r, as required. Finally, if g, and $2 both satisfy the conclusions of the lemma, then

for the difference g, - $2 E H-1/2(11)"' we have (g, - 92, yv)r = 0 for all V E Hl (2)'", and therefore (g, - $2, w)r = O for all w E H1/2(11)'", implying

91 = g2 Note that g is not uniquely determined by u alone, but depends on the choice off . The problem is that we could have Pu = f, = f2 on S2, with the difference f, - f2 a non-zero distribution on R" having support in F. However, provided f is clear from the context, we shall write g and call this distribution

the conormal derivative of u. In particular, if Pu E L2(0)"', then we always define B ,u by making the natural choice Pat

f - {0

on S2,

on R" \S2,

thereby ensuring consistency with the original definition of the conormal deriva-

tive. We extend the definition of 13,u in the same fashion, with the help of Lemma 4.2. The next theorem follows at once; cf. (1.8) and (1.9).

Strongly Elliptic Systems

118

Theorem 4.4 Let 0 be a Lipschitz domain, and suppose that u, v E H I (Q)n'.

(i) If Pu E L2 MY', then the first Green identity holds:

c(u, v) _ (Pu, v)n + (13u, Yv)r (ii) If P*v E L2(S2)"', then

c(u, v) _ (u, P*v)Q + (Yu, B

v)r

(iii) If both Pu and P*v belong to L2(S2), then the second Green identity holds:

(Pu, On - (u, P*v)st = (Yu,13,,v)r - (13,u, Yv)r Strongly Elliptic Operators Let V be a closed subspace of H1(Q)"', such that V is dense in L2(0)"'. Following the terminology established in Chapter 2, we say that (D and P are coercive on V if Re 4) (u, u) > cIIUIIHI(n)s.

- CIIuIIi,(0),0I

for U E V.

Obviously, in this context L2 (S2) acts as the pivot space for V. When seeking to determine whether or not a given differential operator is coercive, we can ignore the lower-order terms, and consider just the sesquilinear form corresponding to the principal part, n

4>0(U, v) =

E(Ajkaku)*8jvdx.

Jj=.1

k=1

Lemma 4.5 The differential operator P is coercive on V if and only if its principal part Po is coercive on V.

Proof. For any 6 > 0, we have I'D (u, v) -'Do(u, v)I -< C11U11HI (n),,, IIv11L,(n)" < C(EIIU1121

so if Po is coercive, i.e., if Re co (u, u) > c II u 11 H

+E-'IIVI1L2(s2)

Al" - C II u II L2(2)"' , then

Re4D(u,u) > and by choosing E sufficiently small, we see that P is coercive. The converse is proved in the same way. 0

Strongly Elliptic Operators

119

The differential operator P is said to be strongly elliptic on S2 if "

It

Re>2>2 [Ajk(x)

for all x E 0, l; E R" and >) E C"'.

k 1 *Sj77 >

j=1 k=1

(4.7)

Depending on the subspace V and the regularity of S2, this purely algebraic condition on the leading coefficients is often necessary and sufficient for P to be coercive.

Theorem 4.6 Assume that the coefficients Ajk are (bounded and) uniformly continuous on Q. The differential operator P is strongly elliptic if and only if it is coercive on Ho (S2)1'1.

Proof. Suppose that P is strongly elliptic. First we consider the special case when the leading coefficients A jk are constant. Let U E Ho (S2)'" = H' (S2)"',

i.e., let u E H1(R")"' with supp C S2. Since .F,,k[aju(x)} Plancherel's theorem implies that

f (Ajkaku)*aju dx = (27r )2 R11

)J* ju(S) dS,

JR"

so, taking ri = u(l) in (4.7), Re(Do(u, u)

(27r

)2

f

c>2

g

f. Iajul2dx

j=1

CIIUI12'(2)u' -CIIUIIL2(s2)"

By Lemma 4.5, we see that P is coercive on Ho (S2)"' To handle the general case, let c > 0 and choose 8 > 0 such that

max IA jk(x) - Ajk(Y)I < E j,k

for Ix - yI < S.

(4.8)

Cover SZ with a locally finite family of open balls B1, B2, B3, ... , each of radius S. (If 0 is bounded, then the family of balls will be finite.) Since the diameters of the balls are bounded away from zero, we can assume that for each d > 0, there is a number Nd such that any given set of diameter less than d intersects at most Nd balls. By Corollary 3.22 and Exercise 4.6, we can find real-valued functions 01, 02, 03, ... in C,1,,mp(W) with 01 > 0 and supp,0) c B1, such that 01(x)2 = 1, 1>1

>2cbi(x) < C, and >2I8j0,(x)I < C, 1?1

!?1

forx E S2.

Strongly Elliptic Systems

120

Note that the number of non-zero terms in each sum is finite, and is bounded independently of x. Since [Ajkak(4lu))*aj(Oly) = 01 (Ajkaku)*ajll + (akOl)0!(Ajku)*ajv + O1(aj0l)(Ajkaku)*v + (akOl)(ajO,)(Ajku)*v, we have 0o(0lu, 01u) < CIIuIfHI(s2)'n IIu1IHI(2)n, 1> 1

and also Re (Do(u, u)

>

Re4 o(01u, 01u) - CIIu1IHI(n)n' IIuIIL,(9),1 . 1>1

Let fio denote the sesquilinear form obtained from (Do by freezing the coefficients Ajk (x) at x = x1, the centre of the ball BI, and observe that

4'o(0tu, 01u) - Co(01u, 0tu) = f {[Ajk(x)

- Ajk(x!)Jak(01u)}*aj(olu) dx.

From the special case considered earlier, we know that (Do is coercive on Ho (S2),

with constants independent of 1, and by (4.8),

IAjk(x) - Ajk(x!)I < E forx E BI, so

Re to(Otu, 01u)

Re (Do(01u, 01u)

-

6110,UI12

> (c -E)IIfiluIIHa(n),n -CII01uIIL,(n)"1, and

Re Do (u,u)> 1>1

-C

1101U112

),n -

CIIuIIHo(S2)n, IIu11L2(szyn

1>1

Since the 0,2 form a partition of unity,

II0IUIIL2(n) = f E0l(x)2lu(x)I2dx = IIUIIL2(n),n !>i

l>1

Strongly Elliptic Operators

121

and

Il018;u + (a;o,)ull2L2(),H IIajul1L2(n)N, - C11

uIIHo(Q),,,11u11L2(n)"'-

Using the inequality ab < (E'a2 + b2/E'), we see that 2

/

Re(Do(u, u) > (c - E - E')IIUIIHo(n)m - Cf l +

1

E,

)IIU112,(si)u'

so P is coercive on Ho (S2).

To prove the converse, take a real-valued cutoff function >/r E C mp(R") satisfying

*>0onR", Jr=0forlxl>1,

*(x)2dx=1. fRII

Let xo E 0, and put *E (x) _ E-"j21/r(E-l (x small,

- xo)), so that for E sufficiently

E C mp(S2) with

r 'VE >

0 for Ix - xol > e,

0 on n,

J

/rE(x)2 dx = 1.

Thus, '1/!E (x)2 converges to 8 (x - x0) as c 4. 0. Consider the function uE(x) _ 1E(x)e`t.XI?. Since

IIUEIlL2(n)"' = 1171,

and ajtfE = E-'(aj*)E, we have

and since ajuE =

Now,

(AjkakuE)*ajuE =

'YE (Arjk

+i1IE(ak /E)(Ajk17)* J

-',,/E(aj'YE)(Ajk k?I)*17 + (ak

so if we define

A'k

=

f1/Ie(x)2Ajk(x)dx,

t

E)(aj*E)(AjkY1 !)*TI,

Strongly Elliptic Systems

122 then

ReE

C(E-2

j11 > ReIo(uE, uE) -

j=1 k=1

If we now assume that P is coercive on Ho (0)', then Re'Do(uE, uE) _> c11 uEII HacWN - CIIuEllc2(si),,, >-

c(E-2 +

CIrjJ2,

implying that n

Re

C(l + E-2 +

kr1)* j17 ?

it

j=1 k=1

Now replace by tl; where t > 0, divide through by t2, and send t -+ 00 to obtain (4.7) with A)k in place of A,k. Since Ask -+ Ajk(xo) as c y 0, we conclude that P is strongly elliptic. 0

For scalar problems, i.e., when m = 1, the strong ellipticity condition (4.7) simplifies to n

Re

1: 1: Ajk(x)44k4'j > it

for allx E S2 and

E R",

j=1 k=1

and the next result is usually sufficient for establishing that the differential operator is coercive on the whole of H 1(S2), not just on Ho (S2); cf. Exercise 4.1.

Theorem 4.7 Assume that P has scalar coefficients (i.e., m = 1), and that P is strongly elliptic on 0. If the leading coefficients satisfy Ak j = A jk

for all j and k,

on S2,

then P is coercive on H 1(S2).

Proof Define F : 0 x C" --* C by !Y

n

F(x,

Ajk(x) k `;j. j=1 k=1

The symmetry condition on the leading coefficients implies that

F(x, + ir1) = F(x, ) + F(x, >)) for x,17 E R",

Strongly Elliptic Operators

123

and so by strong ellipticity, Re F(x, l;) > cI:;12 for all l; E C" (not just for L"). Hence, for all u E H' (S2),

E

cgradull?.().

Re (DO (u, u) = j Re F(x, gradu) dx z

El

In a similar fashion, when m > lit is easy to see that P is coercive on H' (S2)" if Akj = Ask and n

n

n

E[A,k(x)k]*;

Re

j=1 k=I

>c

lei l2

j=1

for all x E cZ and 1, ... , l; E R'",

(4.9)

but this assumption excludes some strongly elliptic operators with important applications; see Exercise 10.3. Using an approach due to Ne6as [72, pp. 187-195], we shall prove a sufficient condition for coercivity on H' (S2)"` in the case when the leading coefficients can be split into sums of Hermitian rank-1 matrices, i.e.,

t Ajk =

brj r=1

where the blj are (column) vectors in C". It follows that Po must be formally self-adjoint, and that L

(Do(u, v) =

J

2

It

uNvdx

where Nu = E b* 8j u.

(4.10)

J=I

1=1

Note that the first-order differential operator N acts on a vector-valued function u to produce a scalar-valued function Nu, and that L

b0(u, u) =

QNulli2cn) >_0

for u E H' (p)'".

r=1

An important example of a strongly elliptic operator of this type is described in Chapter 10; see in particular Theorem 10.2. The proof of coercivity is based on the following technical lemma, whose proof turns out to be surprisingly difficult.

Strongly Elliptic Systems

124

Lemma 4.8 If l is a Lipschitz domain, then for any integers p > 0 and q > 1, and for any u E D(S2), IIuIIH-P(s2) <- CIIUIIH-1-q(92) + C T, 11 VU 11 H-1-11 (9) IctIsq

Proof. Since D(S2) is dense in HS (S2) if s < 0, it suffices to consider u E D(S2). Plancherel's theorem gives

C

f

m

(i \ + lai=q Ir

(1 +

2 <- C I I u I I H

l2)Iu(t)l2d

C E II a°` u II H-n-a (R") , IaI=q

so by Exercise 3.15, IIuIIH-1(n) <- CK (lullH_P (n) + 57, II a" u II H

(lz)

ifsuppu c KC=S2.

Ial=q

In doing away with the dependence on K, we can assume that 7 is a Lipschitz hypograph, given by x < (x'). Our strategy is to make a change of variable x = x(y), with x E 92 and y in the negative half space R.

For E > 0, let

'NE be as in (3.9) and (3.10), introduce the C°° function f (y', c) = (`YE * ) (y'), and define

KE (Y) = (Y', f (Y', -Ey) + y,1) Since grad

E L,,. (R"- 1), we find that a

(

for y < 0.

(ayn-1)«,,-, (aE

I ) «I ...

ay,

C )a,r f (Y', E) < EIaI-1

for laI > 1.

(4.11)

Thus, a,(KE)n(y) = 1 - Ea. f (y', -Ey11) = 1 + O(E), and we now fix c small enough so that c < 8,1(KE),1(Y) < C

for y < 0,

and write K = KE. In this way, K (y) is a strictly increasing function of y, E (-oo, 0), with K. (y) f ' (y') as y71 T 0, and so K : lR" - 0 is a C°O diffeomorphism, and it can be shown using (4.11) that Ia"K(Y)I <

CI-1 IYn l

for lal > 1.

Strongly Elliptic Operators

125

In the substitution x = K(y), we have x' = y', so the Jacobian is simply

detDK(y) =

K. (y).

Also, by differentiating the equation xn = f (x', one sees that ay,

-ajf(x', -Eyn)

axj

1 - Eanf (x', -Eyn)

yn with respect to x,


and by differentiating with respect to x,,, one sees that ay" ax,,

1

11 -Eanf (x', -Eyn)I

The higher-order partial derivatives of K giving

<_ C.

can be estimated in a similar fashion,

afor lal > 1.

aaK-1(x)

lyn l

Let us now show that CIIuIIH-P-,(f2),

11U 0

(4.12) Ilaj(u OK) IIH-,, (J^) <

CllajuHHH-P-,(n) +

Cllanu!IH-P-I(-2).

For 0 E D(R" ), (u o K, 0)w,h I =

I

fn u(x)(cp o K-1)(x) det

DK-1(x)

dx


(g)II(0oK-1)detDK-1IIH,+i(n)+

aju(x) +

for 1 < j

and since

aj(u O K)(y) = t anU(X)a,, K. (Y)

for

f

< n-

1,

- n,

we have

(aj(u o K), O),,

CllajullH-n-'(s2)II(0 o K-1) detDK-1lIHP+i(O) +Clla,,UIlH-r-1(S2)II(4ajKn) oK-1 detDK-1IIH,,+l(s2),

where only the second term on the right is present if j = n. With the help of Theorem 3.33 and Exercise 4.3, we find that both II(10o K-1) detDK-11IH+,+t(n)

and

II (0ajK,,) o K-1 detDK-1IIHp+i(S2)

Strongly Elliptic Systems

126

are bounded by IYnl2(jal-p-1)Iact 5 (Y)12dY

C lal
implying that (4.12) holds. Also, if q5 E V(S2) then I (u o K, (0 o K) det DK)R

(u,

< C II u o K II H-p(R"-) II (0 0 K) det DK 11 ft,(R") and

II(,OOK)detDKpHP(w) < C

IaIp f

x')

I

2

Ho

CII0II2 SO 11 u 11 H-1(1z) -< C II u o K II H-p (RID.

(S2),

Hence, using the Seeley extension operator E

from Exercise A.3, we have IIUIIH-p(n) < CIIE(u o K)IIH-p(R,n) n

< C II E (u 0 K) II

C:II aj E(u 0 K) 11

H-p-I

H-p-I (Ra )

j=1 n

C E 1181(u 0 K) II H-p (Z)

< C II u 0

j=1 n

<- CIIullH-p(Q)+C11aju11H-p m), j=1

which proves the result when q = 1. The general case now follows by induction D on q.

Theorem 4.9 Assume that 0 is a Lipschitz domain and that (Do has the form (4.10), and put n

forl
The operator P is coercive on H 1(0)'n if, for 1 < r < m, there is an integer q,- > 1 such that, for every multi-index a with J a I = q,. + 1, there exist polynomials Q1, ... , QL, each homogeneous of degree qr (with scalar coefficients), satisfying L

L 1=1

taer for all E Rn,

Strongly Elliptic Operators

127

where er is the rth standard basis vector in C'. (Note that Ql depends on r and a.) Proof. Let U E D(SZ)"' and 0 E D(S2), and let Q1 be the partial differential operator corresponding to Q1(4) in the same way that N corresponds to N1( ); thus, under Fourier transformation,

and T

fix- 4{Nu(x)} = Nl(i2n1)u()

Suppose P and 8 are multi-indices with IPI = I and 181 = qr. Applying Plancherel's theorem, and taking a = p + 8 and ur = e,**, u, we have

(81ur, aa4')n = (d ur, 810) = f lq.-1(2n L

fN

t(i2rr )u( )Q,(i2

"

L

dr;

)d

L

_ >(Nu, Q10) _ 1=1

>(N1 u, Q10)a, 1=1

so L

I (anal ur, 4'Tl <_ C L IINruIIL?(n)IIQ14IILZ(sa) 1=1

L

< C:

II L2 (sa)11011,9q'. (a)"

1=1

implying that L

IlNullf,(la) = Ccpo(u, u).

C 1=1

Thus, by applying Lemma 4.8 with p = 0, IlalurllLA(sa)

C11aflU,112

E 11aaaflU,112 I«I :sq,


Ila"a#urll H v,(n) +c II ur II L,(Q)

+ C4)o(u, u),

and we have only to sum over 10 1 = I and 1 < r < m .

128

Strongly Elliptic Systems

Boundary Value Problems In this section, we shall see how the Fredholm alternative allows us to answer fundamental questions of existence and uniqueness for the solutions of elliptic boundary value problems. Suppose that the boundary of the domain S2 has a Lipschitz dissection

r= ID UIIUFN, and that boundary conditions of Dirichlet and Neumann type are specified on I'D and FN, respectively. Thus, our task is to find u E H' (S2)" satisfying

Pu = f on S2, (4.13)

YU = gD on FD,

l3vu = gN on rN,

for given f, gD and gN. Using our definitions of Pu and B,u as distributions, we see that (4.13) is equivalent to

yu = gD on rD and c(u, u) = (f, v)D + (gN, yv)rN

for v E HD(S2)"', (4.14)

where

HD(S2)"' _ {v E H' (Q)' : yv = 0 on rD}. Recalling Theorem 2.27, we expect that if there exist non-trivial solutions to the homogeneous problem

Pu = 0

on S2,

yu=0

onrD,

0

on FN,

(4.15)

then we ought to consider also the homogeneous adjoint problem,

P*v=0

on S2,

yv = 0

on rD,

O

on rN.

(4.16)

Theorem 4.10 Assume that 0 is a bounded Lipschitz domain, and that P is coer-

cive on HAM)"'. Let f E H-' ( 7)m, gD E HI/2(rD)m and gN E H- 1/2 (r,4 yn, and let W denote the set of solutions in H' (S2)' to the homogeneous problem (4.15). There are two mutually exclusive possibilities:

Boundary Value Problems

129

(i) The homogeneous problem has only the trivial solution, i.e., W = (0). In this case, the homogeneous adjoint problem (4.16) also has only the trivial solution in H 1(S2)'", and for the inhomogeneous problem (4.13) we get a unique solution u E H 1(S2)". Moreover, CII f

CH

DIIH'1'tro)- + CIIgNIIH-""2(rN)^'

(ii) The homogeneous problem has exactly p linearly independent solutions, i.e., dim W = p, for some finite p > 1. In this case, the homogeneous adjoint problem (4.16) also has exactly p linearly independent solutions, say v1, ... , VP E H 1(Sl)"', and the inhomogeneous problem (4.13) is solvable in H 1(0)'" if and only if

for I < j < p.

(v1, f )Q + (Yv1, 9N)rN = (Evv1, 9D)rp

When the data satisfy these p conditions, the solution set is u + W, where u is any particular solution. Moreover

IIu+WIIH'(i)"lw
Proof. Put V = HD(S2)"' and H = L2(S2)"', and consider the operator A : V -+ V * determined by (D in the usual way. We note that since S2 is bound-

ed, Theorem 3.27 applies, so the inclusion V C H is compact. Hence, by Theorem 2.34, A is Fredholm with index 0. Furthermore, each distribution fo E H-1 (0) gives rise to a unique functional Fo E V*, defined by (Fo, v) _ (fo, v)n for v E V (although different fo's can give the same F0 if r'D 0 0). Thus, for uo E V and fo E H-1(Q), the equation Auo = F0 is equivalent to

forvEV.

yuo=OonFD and 4)(uo,v)=(fo,v)n

(4.17)

To handle the inhomogeneous Dirichlet condition in (4.13), we write u = H1/2(r')n, and : H1/2(r),n _+ H1(S2)m uo + iEgD, where E : H1/2(rD)"' --+ are extension operators constructed with the help of Theorems A.4 and 3.37. 1

In this way, yu = gD on rD if and only if yuo= 0 on r'D. Choose any extension gN E H-1/2(r')"' of gN, and define fo ER -1 (0)"' by

(fo, v)c = (f, v)n - ID(r7EgD, v) + (gN, Yv)r

for v E H1(S2)'n,

so that (4.14) is equivalent to (4.17), or in other words, so that (4.13) is equivalent

Strongly Elliptic Systems

130

to the equation Auo = FO. We remark that uo can be thought of as a solution of

Puo = fi

on Z,

yuo = 0

on I'D,

13vuo = 81

on FN,

where f, = f - PiEgD and gi = gN -13vri EgD. Notice that for v E V, I(Fo, v) I = I(fo, v)r21 < C11f

11N-I(Q)

IIvjjHi(n)'" + CIIrjEBDIIH'(52)"" IIviiW(s2)",

+ CII8NIIH-'r(rN)- IIYvIIH1/?(rN),"

< C(11f IIH-x(52)" +

II9DIIH"/2(rD)" +

II8N11H-./2(rN)"')IIviIH'(n)'n

so

IIFoIIv- <

C11f11X-'(s2)"'

+CIIBDIIH'/'-(FD)"" +CIIBNIIH-1/'-(rN)"'

The homogeneous problem (4.15) is equivalent to Au = 0, so W = ker A. Likewise, the homogeneous adjoint problem (4.16) is equivalent to

yv = 0 on FD and 4)(u, v) = 0

for U E V,

which in turn is equivalent to A*v = 0. Thus, in case (i) there exists a unique uo = A-' FO, and hence also a unique u = uo + r?EgD, with IIuiIH'(s2)"H < IIuoIIv + IInEgD11H'(s2)"' -< CIIF0IIv + CI18DIIH'/'-(r0)-,.

In case (ii), the equation Auo = FO is solvable if and only if (Fo, vj) = 0 for 1 < j < p. Since the first Green identity gives 4)(?7EgD, vj) = (rlEgD, P*vj)c + (Yr1EgD, Evvj)r = (8D, 13vvj)rD,

and since (RN, yvl)r = (gN, yvj)rN, it follows that (4.13) is solvable if and only if

(f, vj)n - (8D, kvj)ro + (8N, Yvj)rN = 0

for 1 < j < p.

When these p conditions are satisfied, Il uo + W ll v/ w < C II Fo II v , and by choosing w E W such that Il uo + w II v = II uo + W II v/ w, we have

IIu+whlH'(s2)-" < Iluo+wlly+IIlEBDIIHI(r2)-' :S CIIFolfv*+CIlgDIIHI/2(rD)",,

giving the required estimate for IIu + W II H 1(Q)m/ w

0

Boundary Value Problems

131

Note that for a pure Dirichlet problem, i.e., when I, = I'D, any strongly elliptic operator with leading coefficients in W,,,.(Q)mxm is coercive on V = HD02)"' = Ho (S2)"' by Theorem 4.6. Also, we may take f E V* = H- I (Q)1n, because no use is made of the conormal derivative. For a pure Neumann problem, i.e., when r = FN, the proof of the theorem above is greatly simplified because

u=uo E V=H'(U)"' andFo= fo EV*=H-'(S2)"` Next in importance after the Dirichlet and Neumann problems is the third boundary value problem:

Pu = f

on S2,

=g

on F.

(4.18)

Here, the coefficient B is a known function (matrix-valued, if m > 1). The third boundary value problem reduces to a pure Neumann problem if B is identically zero. In fact, for non-zero B, (4.18) is only a compact perturbation of the Neumann problem, and we can state the Fredholm alternative in terms of the homogeneous problem

Pu=O B,u+Byu =0

on S2,

(4.19) on IF,

and the homogeneous adjoint problem

P*v=0

on S2,

(4.20)

on F, as follows.

Theorem 4.11 Assume that 0 is a bounded Lipschitz domain, that the difLet ferential operator P is coercive on H' (0)m, and that B E

f E H-'(S2)"' and g E H-'l/2(F)m, and let W denote the set of solutions in H' (c2)"' to the homogeneous problem (4.19). There are two mutually exclusive possibilities.

(i) The homogeneous problem has only the trivial solution, i.e., W = (0). In this case, the homogeneous adjoint problem (4.20) also has only the trivial solution in H' (0)"', -and for the inhomogeneous problem (4.18) we get a unique solution u E H' (S2)". Moreover, IIUIIa (2)" < CII.f

CIIgIIH-w(r)-.

Strongly Elliptic Systems

132

(ii) The homogeneous problem has exactly p linearly independent solutions, i. e., dim W = p, for some finite p > 1. In this case, the homogeneous adjoint problem (4.20) also has exactly p linearly independent solutions, say U1, ... , up E H' (S2)'", and the inhomogeneous problem (4.18) is solvable in H' (0)"' if and only if

(vi, f)n + (Y vi, g)r = 0 for 1 < j < p. When the data satisfy these p conditions, the solution set is u + W, where u is any particular solution. Moreover IIu + WII H'(S2)"'/w < Cll f 111,-i(ny" + CIIgIIH-"(r)

Proof Put (Au, v)S2 = fi(u, v) and (Ku, v)Q = (Byu, yv)r for u, v E H' (0)"'. The operator A : H' (S2)"' - . H-' (S2)' is bounded, and for any 0 <

E <'

I (Ku, v)!al <_

so K : H 1/2+E (S2)'"

C II uII H1r_+f(sa)'" IIv11H'(a),",

H-' (0)"' is bounded and hence K: H' (S2)'"

H-' (S2)'" is compact. Since A is coercive on H' (S2)'", it follows that A + K : H' (S2)"' -* H-' (S2)'" is a Fredholm operator with index 0. By the first Green identity, a function u E H' (0)"' is a solution of (4.18) if and only if

((A + K)u, v)n = (.f, On +

Yv)r + (Byu, Yv)r,

so (A + K)u = F where (F, v)o = (f, v)n + (g, yv)r. The estimate I(g, Yv)rI < CIIg11H-'/'--(r)I" IIY-IIH""2(r)_< C11811H-"12(r)IlullH'(a)"

shows that F E F1 -I (S2)'", so the results follow directly from Theorem 2.27 after noting that, by the dual version of the first Green identity (Lemma 4.2), the adjoint of A + K is given by

(u, (A + K)*v)Q = (D(u, v) + (Byu, Yv)r

= (u, P*v)n + (yu,

B*yv)r,

assuming in the usual way that P*v is a specified distribution in H-' (0)m. We conclude this section with a result on the spectral properties of elliptic operators.

Theorem 4.12 Assume that 0 is a bounded Lipschitz domain, that P is coercive on HD(0)"1, and that BE Lc.(I')""". If P is formally self-adjoint, and if

Regularity of Solutions

133

B* = B, then there exist sequences of functions 01, 02, -03, ... in H'(0)'", and o f real numbers A1, A2, A3, ... , having the following properties:

(i) Each 4i is an eigenfilnction of P with eigenvalue Aj:

PC = A;o; on 0, YO/ = 0

on rD,

13,'q5;+Byq;=0

on rN.

(ii) The eigenfunctions 01, 02, 03, ... form a complete orthonormal system in L2(0)"'

(iii) The eigenvalues satisfy -C < Al < A2 < A3 < ... with AJ -+ 00 asj -+ oo. (iv) For u, v E HD(SZ)"', 00 ' (u, v) _ EA!(u, 0j)n(0i, v)n

and

j=1 00

E('; +

C)1(.0;, u)n12.

j=1

Proof Put H = L2(2)and V = HD(2)n', and consider the operator A V -+ V * defined by

(Au, v)n = c(u, v) + C(u, v)cy + (Byu, yv)rN

for u, v E V.

Since A is self-adjoint, as well as positive and bounded below on V for C sufficiently large, the desired results follow at once from Theorem 2.37 and Corollary 2.38.

Regularity of Solutions A key feature of the elliptic equation Pu = f is that, away from the boundary, the solution u is smoother than the right-hand side f. We shall prove this fact, and also a result on regularity up to the boundary, using a method introduced by Nirenberg [78] based on estimates of the lth partial difference quotient,

AI.hu(x) =

u(x+he1)-u(x) h

for l <1
(4.21)

(Here, el denotes that lth standard basis vector for R".) The method of proof relies on the fact that 8; commutes with 't.h for any j and 1, and also on the

Strongly Elliptic Systems

134

next lemma, which allows one to deduce L2-estimates for a,u from uniform L2-estimates for O,,hu. Lemma 4.13 Let 1 < l < n, and for brevity write 1j u II = II U II L,.(Ru)m

(i) Ifa,uEL2(R")'",then II A1,011 < Ilatullforallh E ]R, and I1At,hu-atoll -

0 ash

0.

(ii) If there is a constant M such that II LX t,h u II < M for all h sufficiently small,

then a,u E L2(R")' and Ilatull < M. Proof. To prove part (i), suppose that atu E L2(1R")'". We have i

falu(x + the,) dt,

I!,hu(x) =

so the Cauchy-Schwarz inequality implies that IAI.hu(x)12

-

18,u(x+thet)I2dt. 0

By integrating with respect to x, reversing the order of integration, and making

the substitution y = x + the,, we obtain the estimate IIDt,hull2 < Ilatull'. It atu in L2(IR")' if u is smooth with compact support, so is clear that D,,hu for each c > 0 we choose uE E D(R")"' such that 11a,uE - atull < E. From the estimate

Ilot.hu - atoll < Il ot.h(u - uE)II + IIAI,huE - atuEll + IlalUE - atoll (l/t.huE - atuEll +211atu - a,ull < II Ll.hUE - atuEll +2E, we have lim

II A,,h u - at a ll < 2E, showing that A,,,, u -+ al u in L2 (]R" )'".

To prove part (ii), assume that IIAI,hull < M. By Theorem 2.31, there is

a sequence hj - 0 and a function v E L2(1R")"' such that O1,h,U - v in L2(R")",, i.e.,

lim (A,,hru, 0) = (v, 4)

for each ¢ E L2(1R")'Ja00

If ¢ E D(]R")'", then

-(u,

lira (u, Al,-h;th) = lira (A1,h;u, 46) _ (v, 0),

1>00

J-),00

SO a,u = v E L2(R)'". Part (i) now implies that A,,hu -* a,u in L2(IR")'", and thus ll atu ll = limb->o II AI.hu ll < M.

0

Regularity of Solutions

135

In stating the next lemma, we use the summation convention, i.e., we sum any repeated indices from 1 to n, except where indicated otherwise. The proof involves only routine calculations, and is left to the reader.

Lemma 4.14 Let [P, Q] = PQ - QP denote the commutator of P with Q. (i)

The commutator of P with any pointwise multiplication operator x : u t-+ x u is a differential operator of order 1 (not 2):

[P, x]u = (ajx)(Aju - Ajkaku) - aj[(akx)Ajku]. (ii) The commutator of P with a; is a differential operator of order r + 1 (not

r + 2): r f(a,-PAjk)apaku P

P

-

r=1 P-1

Cr) P

[(ai-PAi)aPaju + (a; -PA)apu].

(iii) The commutator of 1t.h with any pointwise multiplication operator u

x u is given by

[Al.h, X]u = (Al,hX)u( +het). We require two other properties of At,h; again, the proof is left as an exercise for the reader. Lemma 4.15 Assume that supp u c s2 fl (92 - he,) and supp v c 92 fl (92 + het ).

(i) If u, v E L2(92)m, then (Al,hu, v)SZ = -(u, At,-hv)SZ (ii) If u, v E H' (9Z)"' and if the coefficients of P satisfy IAl,hAjkI < C and I L I,h A j I < Con 0, then

I4'(At,hu, v) + 1(u, Lt,-hv)I < We now prove regularity in the interior.

Theorem 4.16 Let 921 and 02 be bounded, open subsets of R", such that 921 C 922, and assume that P is strongly elliptic on 922. For any integer r > 0, if u E H1(922)' and f E Hr (922)"' satisfy

Pu = f on 02,

Strongly Elliptic Systems

136

and if the coefficients of P belong to Cr,l (S22)mx"1, then u E Hr+I(Q I)," and

UUIIHI-+2<_

+Ciif1IHIcn,r"

Proof. Choose a real.-valued cutoff function x E D(522) with x = I on 521. Part (i) of Lemma 4.14 gives

P(XU)=fl

with

IIfi IIL,(sz2)" _< IIXf IIL2(sz2) + CIIulIH'(nl)",

(4.22)

so

(Dsz,(Xu, v) = (ff, v)n2

for V E Ha (S22)"

Thus, by part (ii) of Lemma 4.15 followed by part (i) of Lemma 4.13,

I'sz2(Ai,h(Xu), v)j

I'a2(Xu, Ar,-hv)I +

IIVIIH,(sz,)°-

= I(fl, At.-hv)Q,I + CIIXUIIH'(sz,)" IIVIIH'(O,)°-

(IIfi II+ IIxUIIH'((z2Y')IIvIIH'(p2)" if h is sufficiently small and v has compact support in 522. The operator P is coercive on Ho (02)"' by Theorem 4.6, so by taking v = Ai.h (x u) we obtain the estimate 2

IIAi,h(xu)IIH'(n2)" < CIIAr,h(Xu)IIL,(02) + (IIfi IIL,(sa,) + IIxuIIH'(sz2)-")IIAI,h(Xu)IIH'(sz,)-

Applying the inequality ab <

(Ea2 + E-i b2) with c sufficiently small, we 2

conclude that IIAI.h(xu)IIH(S 2)"

CIIA1,h(xu)IIL2(sz2) + Cll f IIL2+ CIIxuIIH(n,) (4.23)

CIIuIIHl(22) + CII!IiL2(s22)'

Part (ii) of Lemma 4.13 now gives the result in the case r = 0.

Proceeding by induction on r, we let r > I and choose an open set 0' satisfying S21 C= 0' C S21 C= 522. By the induction hypothesis, II u II H'+-(sz; )H < C II u II H' (02)" + C II f II H'- t (sz,) N

,

and by part (ii) of Lemma 4.14,

P(81 u) = f2 on SZi,

(4.24)

Regularity of Solutions

137

with

IIf2IIL2(nI)M ` IIar f

ciiuIIH'+'(2 )m < IIf

IIHr(Q2)nr + C11ullH'(s22)n,.

Since f2 E L2 (0'0"', we can apply the result for r = 0, and deduce that IIa uII

CI1a1 ul1HI(2,),,, + CIIf211L2(2,)n1

CIIUIIH'(f22)n, +CIIfIIHr(2,).n,

so the induction goes through.

Next, we consider regularity up to the boundary. As well as assuming con-

ditions on f and the coefficients of P, we require extra smoothness for the trace or conormal derivative of u (i.e., for the boundary data), and also for the boundary itself. In the proof, we estimate the tangential derivatives of u using difference quotients as above, but another trick is needed to deal with the normal derivatives. Hence the next lemma. Lemma 4.17 If P is strongly elliptic, then each diagonal leading coefficient has a uniformly bounded inverse, or equivalently, I nI < CIAj;ril (no sum over j)

for ij E C. Proof Take l;j = Sir in (4.7), and get Re(Arrri)*>) > cIi]I2. Refer to Figure 3 for an illustration of the sets used in the next theorem.

Theorem 4.18 Let G 1 and G2 be open subsets of IE?, such that G 1 C= G2 and G i intersects the boundary F of a Lipschitz domain 0. Put

SZ1 =GlnP, 02=G2n0, I72=G2nF,

Figure 3. The sets used in Theorem 4.18.

Strongly Elliptic Systems

138

and suppose, for an integer r > 0, that F2 is C'+'- 1. Assume further that P is strongly elliptic on 522, that u E H1(S22)"' and f E Hr (Q2)"' satisfy

Pu = f

on 522,

and that the coefficients of P belong to Cr" 1(S 2),n xm

(i) If yu E Hr+3/2(r2),", then u E Hr+2(S21)'" and IIUIIHr+2(nI)m < CIIUIIH'(si,)n +CIIYUIIH"+a1'-(r2)"

(ii) If P is coercive on H1(S2)m, and if

E H''+1/2(1'2)"', then u E

Hr+2(521)"' and IIu1IHi-}2(si,)nt -< CIIu1IHIM,)N1

Proof After a

+CIIB,,UIIHI+I/2(r2)" +CIIfIIHl-

Cr+1.1 change of coordinates, we can assume that S2 is the half

space xn < 0 (see Exercise 4.2). To prove part (i) in the case r = 0, weassume first that y u = 0 on F2. Choose a cutoff function X E V (G2) satisfying X= 1 on G 1; then X U E Ho (S22), and by arguing as in the first part of the proof of Theorem 4.16 we see that Ila/(xu)IIHI(n2).I, < CIIuIIHI(n,)"' + CII f 42(n2)°'

for 1 < I < n - 1.

We cannot estimate an (X u) in this way, because Al,h (X u) might not belong to Ho (02) if l = n. However, the partial differential equation can be rewritten as

-Ann an u = f3,

(4.25)

where n

f3 = f + (anA"")8,1u + E aj(Ajk3ku) - > Ajaju - Au, j=1

(J.k)0(n.n)

so by Lemma 4.17, 82u11L2(a1)" 11

C n-I Il81ullH-(92,)'»,

C11 f IILZ(sll)N + C11 uII H'(n,)u +

(4.26)

!=1

giving the desired estimate for II U11 H2(S2, )^,

For non-zero yu E H3/2(r2)m, we use Lemma 3.36 to find w E H2 (02)' satisfying y w = y u on F2, and II w II H2($i2)m < C II Y u II H3/2(1'2) n . The differ-

ence u - w E H'(02) "' satisfies P(u - w) = f - Pw on 522, and y (u - w) = 0

Regularity of Solutions

139

on 1`2, so by the argument above,

flu - w1IH2(n,)1,, < CllU - wllHl(n,),,, +C11f -PW11L,(n,)u', and therefore

IIUIIH2(n,)<- CIIUIIH'(n2)"' + CIIf'IIL2(n2)"' + CII1IIH2(n3)1",

completing the proof of part (i) for r = 0.

Proceeding by induction on r, we let r > 1 and choose an open set G' satisfying G1 C- G C G C= G2. By the induction hypothesis, IlullH'''(n',),,, < CIIUIIH'(n2)' -f-

CIIYUIIHr+I/2(17,),,, +CII f

where 0', = G,, fl a If 1 < I < n - 1, then y (81 u) = 81(y u), so it follows from (4.24) and the result for r = 0 proved above that

C11 al UIIH'+C11 al }'U ll

H3/2(r2)+C11f211L2(nj).,,.

Thus, Cllf IIH'(si,)n,

11 al U11H2(n1)n, -< CIIUIIH'(n2)^' +

for1<1
= af3 + p

(rtai+2u P

)

Hence, n-t

Ilan+2U IIL2(12,)n, < CIIfIIHr(n,),,, +Cflu11Hr+1(n,)^' +C1:

II8/UIIHr+1(n,p,11

1=1

(4.27)

and the induction goes through. Turning to part (ii), the first Green identity applied to the equation P(Xu) _ fl gives

'(Xu, v) = (f1, v)n2 + (l,(Xu), Yv)r, for all v E H'(SZ2)"'.

(4.28)

Here, fl is the same as in (4.22) from the proof of interior regularity, but now x does not vanish on the boundary, so we need coercivity on H' (U)"', not just on Ho (S2)"'. If 1 < 1 < n - 1, then we can repeat the argument leading to (4.23). The only change is the presence of an extra term involving

Strongly Elliptic Systems

140

the conormal derivative of xu. In this way, we arrive at the following estimate for the tangential difference quotients: IIAI,h(Xu)IIHI(122) < CIIUIIH+ C11 f l1i,(12),,, + CI(13v(Xu),

YAl.-hv)r2I'

where v = El,h (X u). Let Fi = G1 fl I'2. We can assume that supp X C G1, and

then, since [B,, X]u = vjy[(akX)Ajku], IIx8vulli1/2(r;)N, + IIvjY[(akX)AjkUIIlHin(r,,),n < CIIBvuIIH-/2(r2),- + CIIYuIIHI/2(r2)^,.

By Exercise 4.4, IIYAl,-hVIIH-'/2(r;)" = IIAl.-hYVIIH-1/2(r,,)

II81YVIIH- /2(r;)n,

CIIYVIIH'/2(r,,)< CIIvIIH'(12),,,, so

(13v(Xu), YA1,-hv)r,l = I(13v(xu), YL1.-hv)r, (4.29)

ll8v(xu)IIHm/2(r;)IIYAl.-hVIIH-'/2(r,)'"

C(IIBvuIIH"/2(r2),- + IIuIIH-(122))IIEl,h(Xu)IIH'(922)" '

and thus, IID1,h(xu)IIH'(s22)" :5

+CIIBvuIIH'/2(r2y, +CIIfIIc2(Q2)

CIIuIIH'(122)"

forl <1
for r = 0. For r > 1, we make the induction hypothesis that CIIUIIH'(n2)"

IIullH'

+CIIB,uIIH'-"/2(r2),,, +CIIfIIH'-'(n2)°,.

Since

r-I

(B"u)

al

13 (al u)

-YP

( )(a'Aflk)(afaku)

\Pl

-,

we see th at if 1 < 1 < n - 1, then II

IIBvuIIHr+i/'_(r,),,, + CIIUIIHr+t(12',),"

The Transmission Property

141

and so, with f2 as in (4.24),

IlaruIIHZ(nl),,,
fort
The Transmission Property In our later study of surface potentials and boundary integral equations, we will often consider two equations simultaneously, both involving the same op-

erator P, but with one over the interior domain S2- = Q and the other over the complementary exterior domain S2+ = R" \ (Q U F). We then have the disjoint union

=S2+UrUQ-, with I, = 8 S2+ = 8 Q- the common boundary of the two domains, as depicted in Figure 1 of Chapter 1. The vector v will always denote the outward unit normal to c2-, and therefore the inward unit normal to 52+. (If one thinks of S2+ as locally the half space x > 0, then v = e,,.) We denote the one-sided trace

operator for n' by y±, and the sesquilinear form and conormal derivative and L3v , respectively. On account of our convention for SZ} by '1 regarding the meaning of v, the first Green identity (Lemma 4.1) takes the form

(D+(u, v)

= (Pu, On- T (B}u, y±v)r

for u E H2( 1)"' and V E Hl(S2t)"',

(4.30)

and dually (Lemma 4.2)

+(u, v) = (u, P"v)12t : (y±u, BV Or

for u E H) (S2±)"' and VE

H2(i)m.

(4.31)

As explained in the discussion following Lemma 4.3, we extend the definitions of B} and B to make these identities valid for u, v E H 1(S2#)"' whenever in the former case Pu, or in the latter case P*v, belongs to k-1 (01)'In this setting, it is convenient to think of u as a function defined on the whole

of R", but possibly having jumps in its trace and conormal derivatives across

Strongly Elliptic Systems

142

the surface 1,. We denote these jumps by

[ulr = y+u - y-u,

[Bvul r = 13,,'u - Bvu,

[Bul r =13 u -

provided both of the corresponding one-sided quantities make sense. When the jump vanishes, the + or - superscript is redundant and will often be dropped, i.e., we shall write

yu = y+u = y-u if [u]r' = 0, and similarly for the conormal derivatives. For brevity, we sometimes write

u = uln= to emphasise that we are considering the pieces of u separately.

Lemma 4.19 Let f } E H-1(SZ±)"', define f = f + + f - E H_I (RU)"', and suppose that u E L2(R")"' with u± E H' (SZ±)'". If

Pu} = f ± on Sgt,

(4.32)

then

c+(u+, v) + 4-(u-, v) _ (f, v) - ([B,u]r, yv)r for v E H'

(]E8")"',

(4.33) and

(Pu, 0) = (f, 0) + ([ulr, BvO)r - ([Bvulr, YO)r for 0 E D(R")"'. (4.34)

Thus, Pit = f on R" if and only if [ulr = [Bvulr = 0. Proof. Equation (4.33) follows at once from (4.30). The definition of Pu as a distribution on R!' gives (Pu, 0) = (u, P*O) = (u+, P*O)Qa- + (u-, P*O)n-, and by (4.31),

(u}, P*4)n- = 4±(ut, 4) + (Y:-u, BvO)r, so (4.34) follows from (4.33).

0

We can now prove the transmission property for (4.32): if the jumps in u and its conormal derivative are smooth, and if the right hand sides f + and f - are

The Transmission Property

143

smooth up to the boundary, then the restrictions u+ and u- must be smooth up to the boundary. Jumps are also allowed in the coefficients of P, although we shall not use this fact in later chapters. The proof again uses Nirenberg's method of difference quotients. Results like the following theorem, but involving more general types of transmission conditions on F, appear in work by Schechter [90] and Roitberg and Seftel [89]. Theorem 4.20 Let G 1 and G2 be bounded open subsets of R" such that G 1 C= G2 and G 1 intersects 17, and put

S2 =G;ns2l and

for j = 1, 2.

Suppose, for an integer r > 0, that x2 is

Pu± = f±

Cr+1. t, and consider the two equations on S22 ,

r+1

where P is strongly elliptic on G2 with coefficients in C'' 1(SZ )! L2(G2)"' satisfies

u± E H1[ulr E H'+312 (x2"

If U E

[B,,u]r E H(x2)"'

,

and if f ± E Hr(S22)"', then U-1- E H''+2(Q+)'" and IIu+II Hr+2(n ),,, + II U

GIIu+IIHI(n

),,,

II

+CIIU IIHI(1

+ C II [u]r2 II

)8;

C II [Bvulr, II Hl+',Z(r,)-

+CIIf+IIH,(Q2),,, +CIIf Proof As in the proof of Theorem 4.16, it suffices to consider the case when SZ+ is the half space x" > 0. Suppose to begin with that [u]r = 0 on r2i so that u E H1(G2)r by Exercise 4.5. We fix a cutoff function X E D(G2) such that X = .l on G 1, then, as with (4.22), (x u:-)

on Q:'

where the functions fl and f satisfy II f1 IIL,(Q: (Q:)- < C11 Xf IIL,(si})r, +C1lu}IIH1(0) .

By Lemma 4.19,

4) G,(Xu, v) = (fl, V) G, -

Yu)r,

for V E Ho (G2)"',

Strongly Elliptic Systems

144

an equation eerily like (4.28). Repeating the argument from the proof of interior regularity, but with an extra term involving [B (Xu)]r, we see that < CHUIIH(GZ)" + CIIf1IIL2(G2)"

11Al.h(XU)112

+ CI ([B,, (X 01r, y A,, -h v) r2

where v = O,./,(Xu); cf. (4.23). If 1 < 1 < n - 1, then the argument leading to (4.29) shows that I([Bv(xu)]r, Yol,-hv)r, I < (II[Evu)rlIHI/2(r2)"' + IIUIIH'(G2) X Ilol.h(Xu)Ilk'(G2)1'-,

and therefore Il a,(xu)IIH'(G2)" -< CIIUIIH'(G2)" + CII[E,1u]rHIH"12(r2)"' + Cll f1IIL2(G2)

Of course, 8"(Xu) is generally not in HI(G2)'", because [8u]r # 0, but as in (4.25),

f3

on n2" ,

with

CIIftIIL2(7

)1" + CIIuIIH'(nt),,, + C> IIa,UIIH'(s2'),,,. 1=I

Hence, WE E H2(7 )'" and the desired estimate holds for r = 0.

For non-zero [ulr E H312(F2)'", we use the extension operator 770 of Lemma 3.36 to construct w E H2(G2)"' satisfying

Yw = [u]r on I'2

and

IIB,wIIH'12(r2)'" + IIwIIH2(G2)1,, < CII[u]rl!H3P(r2)'".

Consider the function

I u+

UI =

onQ

u- +w on Q2.

Since

Put = )

f

on Q21

f-+Pw oncz

,

with [u1]r = [u]r - w = 0 on I'2, and [B ullr = [Buu]r -

E

HI/2(I'2)m, the preceding argument applies, showing that ui E H2(S2 )"'.

Estimates for the Steklov-Poincare Operator

145

Therefore, u± E H2(0)"' and Ilu

Ilui IIH2cn;

IIH2co, .

Ilu1 Ilx'csa >>° + Ilwllx'csi .^

< CIIu1IIHt(G2)1" + C11[8,,ui]r1iH"r(r2)" + Cflf+IIL2c2;>^'

+Cllf +PzIIL2(n)" +Ilwllx2(n;),,,, which, because CIIwitH2(n2)ur

< CII[u]rllx3/2cr2yn,,

shows that the desired estimate for the case r = 0 holds also when [u]r 0 0. An inductive argument like the one used for part (ii) of Theorem 4.18 takes care

ofr> 1. Estimates for the Steklov-Poincare Operator Consider the semi-homogeneous Dirichlet problem,

Pu = 0

on Q,

(4.35)

yu=g onl' and the adjoint problem

P*v = 0

on cl,

yv=ci

onr.

4.36)

If the fully homogeneous problem has only the trivial solution in H' (S2)"', i.e., if g = 0 implies u = 0, then under the usual assumptions we are able to define solution operators

U:gHu and

V:OF-).v,

with

U: H'/2(r)m -)-H'(S2)m

and V: H'/2(r )ra -+ H'(P)"'.

We can also form the Steklov-Poincare operators 13,U : g H 0H that satisfy

H'12(r)n, -+ H-1/2(1')'' and

13,V :

Hi/2(r)"'

--

(4.37) and 13,V :

H-'/2(1')"'. (4.38)

Strongly Elliptic Systems

146

The purpose of this section is to prove that, under certain conditions, 13,U

are also bounded from H' (r)m to L2a fact that will be used

and

later in our study of surface potentials and boundary integral operators; see Theorem 6.12. Notice that

(Bvug, O)r = t'(Ug, V-0) = (g, B,VO)r,

(4.39)

so (B,U)* =13 V. If SZ is at least C", then the regularity estimates of Theorem 4.18 apply, and we can extend (4.37) and (4.38) as follows. C'+'.1 domain, for some integer Theorem 4.21 Assume that SZ is a bounded, If r > 0, and that P is strongly elliptic on S2, with coefficients in Cr.1 (0) the Dirichlet problem (4.35) has only the trivial solution in H 1(SZ)'" when g = 0, then the solution operator has the mapping property

U : Hs+1/2(r)m

Hs+l (S2)m

for 0 < s < r + 1,

and the Steklov-Poincare operator has the mapping property

B,U : Hs+1/2(r)m -+ Hs-1/2(r )m for -r - 1 < s < r + 1.

Proof. The case s = 0 is covered already in (4.37) and (4.38). Part (i) of Theorem 4.18 shows that U : H'+3/2(r)m -+ H'+2(Q)m, and thus 8,U: Hr+3/2(r)m -+ H'+1/2(r)m, which means that the result holds for s = r + 1. Boundedness for the range 0 < s < r + 1 now follows by interpolation, i.e., by Theorems B.8 and B. 11. The same arguments apply to V and B, V, so, in view of (4.39), we can extend X3VU in a unique way to a linear operator that is

bounded for -r - 1 < s < 0. Our task is much harder when c2 is permitted to be Lipschitz. In this case, with the help of the following integral identity. we will estimate Here, for the sake of brevity, we use the summation convention, i.e., we sum any repeated indices from 1 to n. Lemma 4.22 Assume that cZ is Lipschitz, and that the leading coefficients Ajk belong to W111 (c2)m"". For any real-valuedfunctions h 1, h2,

... , h" E W1 m),

and for' any u, v E H2(Q)m,

v,y{[(hlAJk - hJAlk - hkAjl)aku]*aiv} dx Jr

_ f {(Djkaku)*ajv +

(hk8ku)*(Pov)} dx,

Estimates for the Steklov-Poincare Operator

147

where

Djk = at(hIAjk) - (alhj)Alk - (alhk)Aji. Proof By the divergence theorem, it suffices to show that 8({[(hlAjk - h jAlk

=

(DjkakU)*ajv

- hkAjr)aku]*ajv} + (Pou)*(hjajv) + (hkaku)*(Pov).

In fact, the left-hand side expands to a sum of five terms,

[8r(hlAjk - h jAlk

- hkAjl)(aku)]*ajv

+ [(hlAjk - hkA j,)8,aku]*ajv + [ - h jAlkalaku]*ajv

+ [(h,Ajk - h jAik)aku]*alajv + [ - hkAjIaku]*a,ajv. The second term vanishes because its factor (...) is skew-symmetric in 1 and k, and likewise the fourth term vanishes because its factor (...) is skew-symmetric in I and j. The third term equals

h j [Pou + (alA1k)aku]*ajv = (Pou)*(hj81v) + [hj(atArk)aku]*ajv, and the fifth term equals

-(hkaku)*Aj*iatajv = (hkaku)*[Pov + (a,A;t)ajv] _ (hkaku)*(Pov) + [hk(a,Ajl)aku]*ajv, so we get the desired right hand side with

Djk = aI(hlAjk -hjArk -hkAji)+hj8lAlk+hkalAjl.

0

Rellich [85] used a special case of the above identity to obtain an integral representation for the Dirichlet eigenvalues of the Laplacian. Subsequently, Payne and Weinberger [81] generalised the Rellich identity to handle secondorder elliptic systems with variable coefficients, and used it to bound the errors in certain approximations to (D(u, u) and pointwise values of u, when u is the solution to a Dirichlet or Neumann problem. In what follows, we use the arguments of Necas [72, Chapitre 5]. We will use certain first-order partial differential operators of the form

Qu = Qky(aku) with Qk E L,,(P)mxm If vk Qk = 0 on I', then such a Q is said to be tangential to r.

Strongly Elliptic Systems

148

Lemma 4.23 Assume that 0 is a Lipschitz domain, and let u E CCIomP(S2)m.

(i) If Q is afirst-order, tangential differential operator, then IIQiIIL,(r)-n < CIIYullH-(r),,,.

(ii) The normal and conormal derivatives of u satisfy IIt3vuIIL2(r) n < Cllau/avlIL2cryn +

CIIYuIIHi(ryn,

and, when P is strongly elliptic on 2, I1au/a))1L,(r),n <- CIIBvu1IL,cr)" +CIIYUIIH1tr>n,.

(iii) For1<j
n-l

Q,(x', ox')) _

Ql(x', (x'))81 (x'), l=1

and so n-1

Q1(x', (x'))[alu(x', (x')) + anu(x',

Qu(x', (X )) t=1

n-1

_

t-t

Q1(x', 0x'))aiut(x'),

where ut(x') = u(x', C(x')). Part (i) follows at once. Next, consider the identity (vj Ajkvk)

au av

=

Qu,

where Qu = vj(Ajivivk - Ajk)y(aku).

The first half of part (ii) is immediate, because the differential operator Q is tangential to r. The second part follows because the condition (4.7) for strong ellipticity implies that the m x m matrix v1 AJk Vk is uniformly positive-definite,

so Il(vjAjkvk)au/avllL,(r)n

cllau/avIlL,.(n- Finally, to prove part (iii), we

Estimates for the Steklov-Poincare Operator

149

observe that

Y(a;u) = vj

au Qju, av +

Where Qju = (S.ik - VJVk)y(aku),

and the differential operator Ql is tangential to T.

Concerning the next theorem, we remark that only part (i) is actually used later.

Theorem 4.24 Assume that 0 is Lipschitz, that P is strongly elliptic on n, and that the leading coefficients AJk are Lipschitz and satisfy Aki = Ask.

(Thus, the principal part of P is formally self-aajoint.) Let U E H 1 (S2)' and f E L2(S2)'" satisfy

Pu= f on Q. (i) If yu E H' (1')"', then

E L2(S2)'", and

IllvullL2(r)" < CIIYuII H'(r)-' + CIIuIIW(Q)"" + CIIf IIL,(sa)--

(ii) If P is a scalar operator (i.e, if m = 1), if AkJ = Alk (so the leading coefficients are purely real), and if fi,u E L2(r), then yu E H1(17), and IlYulluI(r) <- CIIEUuIIL,(r)+CIIuIIHI(sz)+CIIfIIL,(sz)

Proof Suppose in the first instance that u E H2(S2)m. Taking v = u in Lemma 4.22, and noting that Po = Po, we obtain

vIy{[(h,A;k - hJA,k - hkAjl)aku]*aju} dx Jr

= 12 { (Djkaku)*8 j u + 2 Re [(Pou)* (h; a ju)] } dx.

(4.40)

We split the integrand on the left-hand side into a sum of three terms,

(Qju)*(a;u) + (aku)*Qku - vl[(h,Ajk)aku]*aju, where Qj and Qk are tangential differential operators, defined by

Qju = v((hlAjk - hkAJl)aku and

Qku = vr(h,A*k -

hjAk)3ju.

Strongly Elliptic Systems

150

The matrix A = v j A jk vk E L,,. (I')'n xm is Hermitian and uniformly positiveexists definite on r, because P is strongly elliptic. Thus, A.' E and is uniformly positive-definite. A short calculation shows that

(Ajkaku)*aju =

u + (Qju)*aju,

where Q'' u = (A jk - vP A jp Av' Aqk vy) ak u. The operator

is also tangential,

so if we choose the h1 such that

hjv1>c,

(4.41)

then

da

I113" ull2Z(rro < C J

r

< CIIYajUIIL,(r)"(IIQjuIIL,(r)- + IIQ'UIIL,(r)- + IIQ';uHIL,(r) +CIIuIIH(n),., +CII7'ouliL2(s)''IIUIIHI(n)

By Lemma 4.23, IIYajuIIL,(r)"N

cllau/avjIL,tr)- +CIIYuIIH1(ryST CIIL.u1IL2(r)" + CIIYulIHI(r)-,

and so CII5vuIIL,(n-11YullH-(r)- +CIIYuIIHI(ry, +CIIuIIHI(n)w + CIIPouIIL2(n),"l111IIHI(n)Since II Pou II L, (n)., < II f 11L,(92)' + C 11U 11 HI (U)"',

the estimate in part (i) follows.

Now drop the requirement that u E H2(SZ)'", i.e., allow u E H' (c2)1, but assume y u E H 1(I')". It suffices to consider S2 of the form x" < (x'), where is Lipschitz with compact support. By Theorem 4.6, the operator P is coercive on Ho (0)'", so for A sufficiently large,

4)(u. u)

clIuIIH1(nr.

for u E Ho (l)'".

Choose a sequence Sr E CI (R"-1) such that 1.

S, -*

2. r <

in L,,,, (]Ri-1), and grad r -- grad in L p (IR"-') for I < p < oo; on 1R"-', and II grad r C, for all r;

3. r(x') = (x') = 0 for Ix'I sufficiently large.

Estimates for the Steklov-Poincare Operator

151

We let Or denote the set of points x E IR " satisfying x < r (x'), and put rr = a Or . Obviously, 12,. c 0. Define g : 0 -> C'" by

g(x) = Yu(x', C(x')), so that g(x) is independent of x". We easily verify that II9IIH-(n)-

CIIYUII H'(r)"1

and

IIYrgHIH,(rr)< CIIYUIIH'(r)m,

where y,. is the trace operator for 1'r, and where, in the second estimate, the constant C is independent of r. The operator P + A is positive and bounded below on Ho (S2)"', and hence also on Ho (0r)'n, so there is a unique solution ur E H1(52r)"' to the Dirichlet problem

(P+A)ur = f +Au on Or, Yrur =Yrg

on 1`r.

Moreover,


Yrur = Yrg, II urII H'(S2)'' < IIurIIH'(52,.)"' + II9IIH'(S2\52,)'"

< CIIYuIIH'(r)r' +CIIf +AuIIL,(Q)nI.

Since rr is smooth, we have ur E H2(S2r)"' by Theorem 4.18, and so the argument in the first part of the proof shows that IIBvurIIL,(r,)"' < CIIYrurIIH'(r,.)," +CIIurIIH'(sZ)" +CIIf +AuIIL2(92r)"'

< CIIYUIIH'(r)'" + CIIuIIH'(n)"" 4 CIIf IIL,(n)111,

(4.42)

with the constants again independent of r. We claim that ur converges to u in Hi (S2)"'. Let Or denote the sesquilinear form on Or, and apply the first Green identity to obtain

(Dr(ur, v) + A(ur, v)sz,. _ (f + Au, v) Q,. + (B"ur, Yrv)r,

for V E

H1(SZr)"',

(4.43) and

(D (u, v) + ), (u, v) s2 = (f + ), u, v)n + (B u, yv)r

for v E

H1(St)"'

152

Strongly Elliptic Systems

Hence, if V E Ho (Q)"', then

(D(ur - u, v) + A,(ur - U, On = [(Dr(ur, v) + A(ur, V)str]

- [c(u, v) + JA(u, v)Q] + [('(ur, v) - 4>r(ur, V) + ,X(ur, v)n\SZ,] = (Ever, Y,.v)r, - (f +,Xu, v)S \s2, + [4)(ur, v) - (Dr(ur, v) + ),(u,-, v)12\S2r],

so by taking v = ur - u and remembering that u, = g on Q \ S2r, IIU,.

-U112

(Q)",

< CII8A-IILZ(rr)"IIYr(ur -u)IILZ(rr),n +C(IIf +AuIIL,(s2\sz,.>>n + IIgIIH'(S2\nr)'n)IIur - UIIH0(i2),n.

Define

wr (x') =

1 + I gra4-(x')12

and w (x') =

1 + I grad (x') I2,

and note that 1 < wr (x') < C, 1 < w (x') < C, and wr -+ w in LP (I

"-l)

for 1 < p < oo. We have II Yr(ur - u)IILz(r,)"' = J n- I u(x',

f


< CII

(x,))

-

U (X,,

S' (X,))

12

(x') "-'

(x') - r(x')1

4

I8"u(x', x")12 dx" dx' (XI)

11 L,. (R"-I)IIUIIH(4.44)

which, in combination with (4.42), implies that II ur - u 11 Ho (Q). -+ 0, as claimed. The sequence of functions *r (x') =13,, ur (x', r (x')) is bounded in L2 (]R"-1)'"

because IIY'rIIL,(RH-i),n <_ J

I-,

I13vur(x',

r(x,))I2wrx')dx'

= II13,u,112 r,.)n

so by Theorem 2.31, after passing to a subsequence we can assume that iJrr converges weakly to a function * in L2(Ri-1)"', i.e., (t/rr, v) -+ (+/r, v) for each v E L2(IRa-1)"'. Define (x', (x')) = ,lr(x'), and let v E D(SZ)"', say. We have

(t3vur,Yrv)rr =

J fR

(x!)*v(x', (x'))w(x') dx' _ (, Yv)r,

Estimates for the Steklov-Poincare Operator

153

and therefore, sending r -* oo in (4.43) gives (D(u, v)

v)sz +

for V E D(S2)'n

Yv)r

Hence, Bvu = j E L2(I')m, and by Exercise 2.11, the estimate of part (i) follows from the uniform estimate (4.42) for B,ur. To prove (ii), assume m = 1, and suppose once again that u E H2(SZ) and that the h1 satisfy (4.41). This time, we write the integrand on the left-hand side of (4.40) as

uzh,A jkdku8ju - Bvuh j8ju - hkakuBvu, and hence obtain, using strong ellipticity,

E IIYajUIIL,(r) < C j=1

fr

hrv1Y{Ajk8ku 8ju}dv n

<- CIIBvuIIL,(r)

IIYajUIIL2(r) j=1

+

CIIPoUIIL2(17)IIUIIHl(s2)

Thus, n CIIUIIH,

II YajUII L,(r) < CIIBvuIIL2(r) +

(-) + CII f IIL2(n),

j=I

and the estimate of part (ii) follows. Next, we allow u E H1(c2) and assume Bvu E L2(F). Define gr E L2(Fr) by

gr(x', r(X')) = Bvu(x', (x'))w(x')/wr(x'), and let Ur E H1(c r) be the solution of the Neumann problem (with A. sufficiently large, as before)

(P + A.)ur = f +),U On Or, Bvur = gr

on Fr.

We easily verify that IIgrIIL2(rr) < CIIBvUIIL2(r), and by Theorem 4.7, 2

(Pr(U, v)+A(v, On, ? CIIVIIH t(sar)

with the constant independent of r in both cases. Thus, we have the uniform

Strongly Elliptic Systems

154 bounds

IIUrIIH'(22,) < CII f + AUIIH--(SZr) +

CIIgrIIH-112(p,)

< C1IBvUIIL,(r) + CIIuIIH'(0) + CIIf IIL,(o),

and, since Ur E H2(2r) by Theorem 4.18, our earlier argument gives n

:IIYajur11L,(rr) -< CIIg1IIL2(rr)+CIIUrIIHI(S2r)+C11f1IL2(nr) j=1

CIIBvuIIL,(r)+CIIurIIH'(s2r)+CIIfIIL,(sa). (4.45) Using the method in the proof of Theorem A.4, we can extend u,. to a function in H' (R") in such a way that II U, II H' (52\52,.) -* 0. To show that ur converges to u in H' (Q), we observe that for v E Hl (SZ),

(D(Ur - U, V) + ),(Ur - U, v)S2 = [4)r(Ur, v) + a.(Ur, V)nr]

- [c(u, v) + A(U, v)cz]

+ [
(gr, Yrv)rr, - (E.,u, Yv)r - (f + A.u, v)c\i2r + cc2\a'(Ur, v) +A(Ur, v)12\nr. Since

I (gr, Yrv)rr - (13,, u, Yv)r12

5vu(x', (x'))[v(x'' Sr(x')) C11L3"U112 L2(r)

-III

L.(1"-')IIVII

- v(x', (x'))]w(x') dx'

2

2 H'(n\Qr)'

we see by taking v = Ur - u and again applying7I eorem 4.7, this time over S2 instead of SZr, that

IIU.-uIIH'(S2) C II

and so ur -+ u in H' (0). Define *r (x')

C II

11 H'

(yrur)(x', r(x')) and *(x') =

(yu)(x', (x')).Bywriting*,-(x')-1(x') _ [ur(x', r(x'))-Ur(x', 0x'))]+ (Ur - u) (x', (x')), and estimating the first term in a manner similar to (4.44), we obtain

I( r- r,v)I

[IIr-Ili( -)IlurllH'(s\n,)+IIY(ur-u)IIL2(r)]IIvIIL,(JR'I-I),

Estimates for the Steklov-Poincare Operator

155

and therefore *r + t// in L2(R"-' ). Finally, by (4.45), II*rlIH'(R"-') -< CIIurIIHt(r,) <- CIIB,,uIIL2(r) + CIIuIIHI(S2) +CIIfflL2(n),

so Exercise 2.11 shows that 1 E H' (R"-') with II * II H ' (]"-') < lira sup II ,y r II H ' M-' ), implying that u E H' (1'), and that the estimate of part (ii) holds.

It is now a simple matter to obtain the desired mapping properties for the Steklov-Poincare operators. We can also introduce a meaningful concept of a solution u = Ug E L2 (&2)' for g E L2(F)"` (but see also the sharper mapping property for U proved in Theorem 6.12). Theorem 4.25 Assume that S2 is a Lipschitz domain, that P is strongly elliptic on S2, and that the coefficients AJk and AJ are Lipschitz (not just Lam). If

Akj = AJk,

and if the solution operators (4.37) exist, then the Steklov-Poincare operato satisfy BvU :

Hs+1/2(r,)"'

+ Hs-1/2(r,)n'

and 9,V: H.s+112(r,)'n -* Hs-1/z(r,)+n

for - 2 < s < Z. Furthermore, the solution operators have bounded extensions U : L2 (1,),n

L2(2)n'

and V : L2(F)m -* L2(S2)m.

Proof. For s = 0, the first part of the theorem was established in (4.38). We obtain the result for s = 1 by applying part (i) of Theorem 4.24 to (4.35) and (4.36). The case s = -? then follows by duality, using (4.39). Finally, interpolation gives the complete range -1 < s < 1.

In the second part of the theorem, it suffices to consider U. Let g E H 1/2 (r),

and f E L2(Q)m, and put u = Ug E H' (S2)m. Our assumptions imply the existence of a unique w E H' (S2)m such that

P*w = f

on S2,

yw=0 on1. The first Green identity gives, on the one hand,

(D(u, w) = (Pu, w)n + (13vu, Yw)r = 0,

Strongly Elliptic Systems

156

and on the other hand, (D(u, w) = (u, P*w)n + (Yu,

(u, f)n + (g,

so

I(u, f)nI = I(g, Bvw)r

IIglIL2(r)'"IIBpwIIL2(r)'"

By part (i) of Theorem 4.24, IIBvwIIL2(r)'" _< CIIYWII H'(r)'" + CIIwIIH'(n)"' + Cll f IIL2(n)" < CIIfllL2(n)",,

and hence 1(u, f) n l < C II g II

L2 (r)m

II f II L, (n)m , implying that IlUg it L2 (n)m =

0

IIuIIL2(n)'" <- C118IIL2(r)m

Exercises

4.1 ShowthatPu = -8j (Ajk0ku)+Aj8ju+Au,where Ajk = 2(Ajk+Akj) _

Akiand Aj =Aj+28k(AJk-Akj). S2 be a C' diffeomorphism. We denote the Jacobian of the coordinate transformation x = K (y) by

4.2 Let K : S2K

J(Y) = I detK (Y)I =

18(x1,

... ,

and write UK = uoK and vK = voK, so that u (x) = UK (y) and v(x) = vK (y). (i) Let 0 be the sesquilinear form (4.2). Show that c (u, v) = cK (UK, vK ), where 4>K is the sesquilinear form with coefficients

Ajk(Y) _ (ay Ars (x) 8xk) J(Y), \

r

s

, Aj(Y) _ (Ar(X)2)J(Y) ax,

AK(Y) = A (x)J(y).

(ii) Let PI denote the differential operator with the coefficients in part (i).

Show that Pu = f on 0 if and only if PKuK = fK on UK, where

fK(Y) = f(x)J(Y) (iii) Show that P is strongly elliptic (respectively, coercive) on Q if and only if PI is strongly elliptic (respectively, coercive) on 7K. 4.3 Show that if f (0) = 0 and a > 2, then

t-af

00

(Jo

I

1/2

(t) 12

dt)

[Hint: use Exercise 3.20.]

1/2

1

<

t'-« f,(t)12 dt) a -

(J0

I

.

Exercises

157

4.4 Show for all s E R that if al u E HS (R' )" `, then the difference quotient (4.21)

[Hint: l e" - 11 s 101 for O E R.] satisfies II A1,hu 11 Il a,U I! 4.5 Suppose that u E L2 (W) and u± = u I r} E H I (II8'f). Show that

(a, u, 0)

= (a;u+, 0)i + (a;u-, 0)A +

J0 ([u]r, Yt)r

if l<j
where I' = R"-1 x {0}. Deduce that u E HI(R") if and only if [u]r = 0. 4.6 Show that in Corollary 3.22 we can choose the functions Oj for the partition of unity in such a way that 0, (x) = i/rj (x)2, where 1/r; E C mp t [Hint: start by considering g in Exercise 3.6.] 4.7 Consider the classical cooling-off problem [19, p. 56]: au

at - aLu = 0 av+byu=0

u = uo

on S2,

fort > 0,

on r, fort>0, on S2,

when t = 0,

where a and b are positive constants. Let 401, 02, ... and. 11, A2, ... be the eigenfunctions and eigenvalues of the stationary problem, as in Theorem 4.12, i.e.,

-a 0Oj = ,Xj¢j on 0, a0;

-}-by¢j =0

av

on!,

and derive the series representation 00

u(x, t) = > e-"(0 , uo)ccpj(x) In what sense does this sum converge?

for x E Q and t > 0.

5

Homogeneous Distributions

For a E C, a function u : R" \ (0}

u(tx) = t°u(x)

C is said to be homogeneous of degree a if

for all t > 0 and x E 1R" \ t0}.

(5.1)

To extend this concept to distributions, we introduce the linear operator Mr, defined by

MMu(x) = u(tx)

for 0 o t E'1R and x E IR",

and observe that for every u E L 1,10 (1R" ),

(Miu, 0) = Its-"(u, M1ltfi)

fort # 0 and 45 E D(1R").

(5.2)

If U E D*(IR") then (5.2) serves to define Mtu E D*(1R"), because M11, : D(1R") -* D(RI) is continuous and linear. We then say that u ED*(R) is homogeneous of degree a on IR" if M,u = t°u on 1R" in the sense of distributions, for all t > 0. This chapter develops the theory of homogeneous distributions, using Hadamard's notion of a finite-part integral to extend homogeneous functions on 1R" \ {0} to distributions on R. We consider in some detail the Fourier trans-

form of, and the change of variables formula for, such finite-part extensions. A technique used several times is to reduce the general n-dimensional case to a one-dimensional problem by transforming to polar coordinates. Most of the material that follows can be found in standard texts such as Schwartz [92], Gel'fand and Shilov [27], and Hormander [41], but the final two sections dealing with finite-part integrals on surfaces - include some less well-known results from the thesis of Kieser [48]. The results of this chapter will be applied later in our study of fundamental solutions of elliptic partial differential operators, and of boundary integral operators with non-integrable kernels. 158

Finite-Part Integrals

159

Finite-Part Integrals We begin our study of homogeneous distributions by focusing on the simplest example, namely, the one-dimensional, homogeneous function xa

10

if x > 0,

ifx <0.

If Re a > -1, then x+ is locally integrable on R, and is obviously homogeneous of degree a as a distribution on R, not just as a function on R \ {0}. To deal with

the interesting case Re a < -1, we use the following concept, introduced by Hadamard [37] in the context of Cauchy's problem for hyperbolic equations.

..., bN+2 be complex numbers, with Re a1>0andaf#0 for I<j
Definition 5.1 Let al, ... , aN and b1,

and

aj 54 ak

whenever j # k.

(5.4)

If a function g satisfies N bl g(E) _ L Eai

+ bN+1 log E + bN+2 + 0(1) as c 4. 0,

1=1

then the term bN+2 is called the finite part of g(e) as c .{ 0, and we write

f.p. g(E) = bN+2 E.J,O

When no singular terms are present, i.e., when b1 = ... = bN+t = 0, the finite part is just the limit of g(E) as c it exists, the finite part is unique.

0. The next lemma shows that, when

Lemma 5.2 Let a 1, ... , aN and b 1, ... , bN+2 be complex numbers, and assume that the aj satisfy (5.3) and (5.4). If N

lim E b' + bN+l log E + bN+2 = 0, Eaj CIO

(j=1

thenbj =Ofor1 < j
Homogeneous Distributions

160

with X j E R \ {0}, so JE-"j I =I exp(-iA. j log E) I= 1 for I< j < N, and we see at once that bN+l = 0. Moreover, there exist a sequence o and real numbers 01, ..., ON such that Em 4. 0 and limmi 6. j = eloj for 1 < j < N. Thus, putting E = Em ex and sending m -+ oo, we see that N

Lb

je-i(.Ljx+oj) + bN+2

= 0 for x E R.

(5.5)

j=1

By (5.4), we may assume without loss of generality that X 1 < k2 < . . . < AN, and by analytic continuation we may replace x with ix in (5.5) to obtain N

bj ezjx-iej + bN+2 = 0

for x E R.

j=1

oo, to conclude that bN = 0. Otherwise, X1 must be negative, so we divide through by e^tx and send x -+ -oo to conclude that b1 = 0. Repeating this argument, one sees that b j = 0 for 1 < j < N, and then (5.5) reduces to bN+2 = 0. Now suppose µ > 0. Since If AN > 0, then we divide through by eA"x and send x

N

1im E" ELO

N (--j + bN+1109 E + bN+2 j=1 E"j

= lim 4"0

biE"j-µ Rea j=µ

it follows as above that b j = 0 if Re a j = it, and repetition of this argument shows that b j = 0 if Re a j > 0, which gets us back to the case when µ = 0.

0 ForE> 0and0ES( H ), we define the integral 00

dx fs

and its finite part,

Ha (cj) = f.p. Ha.E (O) Ejo

The following lemma establishes the existence of Ha (0), and shows that we can define a temperate distribution f.p. X'- E S*(R), called the finite part extension of x+, by putting

(f.p. x+, fi(x)) = Ha(d)

for 0 E S(R).

Obviously, if x is restricted to R \ {0}, then f.p. x+ coincides with x+.

Finite-Part Integrals

161

Lemma 5.3 For any integer k > 1 and any 0 E S(R),

Ha(0) =

if Re a > -k - 1 and

(-1)kH°+k(0(k)) (a + 1)(a + 2) ... (a + k)

-1,-2,...,-k,

a

but 00

H-1(q) = -J

0'(x)logxdx 0

and

1

H-k-1 (0) =

1 O(k)(0) +

j

k! j=1

k!

1H-1

(O(k))

Proof. Integration by parts gives

_E) a

-

H + 1O,)

if a# -1.

Suppose first that Re a > -k - 1 and a ; -1, -2, ... , -k. By Taylor expansion, k-1 O(j) Ea+1O E)

=

i0)Ej+a+1

+0(6 Rea+k+l ),

j=0

so if Ha+1(q') exists, then Ha+1(0')

a+l and the first part of the lemma follows by induction. Next, integration by parts and Taylor expansion give 00

-0(E) logE -

_ -0(0) logE -

f0'(x)logxdx

J0

00 O'(x)

logx dx + O(E log,-),

implying the formula for H-1(0). Finally, when a H-k-1,, (

_-

E-ko

= -k - 1,

(E) + H-k W)

Homogeneous Distributions

162

and by Taylor expansion, k-1

(1)

1=1

J'

(k)

k

so if H_k (4') exists then (k)

+ Xk ( k

The formula for H_k_ 1(0) follows by induction.

'O

The next lemma shows that the distribution f.p. x+ is homogeneous of degree a on R, except when a is a negative integer.

Lemma 5.4 If c E S(R) and t > 0, then t-1Ha(Ml/tO) = taHa(O) fora # -1, -2, -3,

...,

t-1 H k-1(M'/to) = t-k-1 H k-1(46) + (t-k-1 log t)

(k)

but

ki0)

for any integer k > 0.

Proof If Re a > -1, then it suffices to make the substitution x = ty to obtain

t-'Ha(Mi/tcb) = t-' f OOxa¢(x/t)dx = to

f00

Ya,O (y) dy = taH.

-1, -2, ... , -k. For cf. (5.2). Now suppose that Re a > .-k - 1 and a brevity, write bk = (-1)k/[(a + 1) (a + k)]; then by Lemma 5.3, t-'Ha(Mi/t4) = t-1bkHa+k((M11 )(k)) = t-'bkHa+k (t-kMl/t4(k))

= bkt-k-lHa+k(M1/tO(k)) = bktaHO+k(O(k)) = taHa(t) However, when a = -1, we have

t-1H-l (Ml/A = -t-' J

(Ml/to)'(x) logx dx

0

_ -t-2

00

J0

0'(t-1x) l o g

dx,

Finite-Part Integrals

163

and the substitution x = ty gives 00

t-1 H-1 (MI/to) = -t-1 J

O'(Y) log(tY) dy = t-1 H_I (0) + 0 (O)t-' log t. 0

1/j, then

In general, if we let ck = (1/k!)

t-'H-k-1 (M11,O) =

1

t-'Ck(M1/iO)(k)(0) + k! k

= Ckt-k-1o(k)(O) + t kl

H_i ((M1/t0)(k))

1

H_I(M1/,0(k))

= t-k-1 (CkO(k) (0) + I H-1(O(k)))

+

0(ki 0) t-k-1

log t,

giving the second formula in the lemma. We shall also have use for the homogeneous function 0

x° = (-x)+ _

1xIa

if x > 0, if x < 0,

and its finite-part extension, E

(f.p. X!, 0 (x)) = f.P

fO -00

= f.p.

Ix JaO (x) dx

f xa0(-x)dx = Ha(M-t4b) E

It is easy to verify that

f.p.(-x)+ = f.p. x,,

(5.6)

and that f.p. xa is homogeneous of degree a on R, except when a is a negative integer. Indeed, Lemma 5.4 shows that if t > 0, then

f.p. (tx)f = to f.p. xt for a

-1, -2, -3, ... ,

but

f.p.(tx) fk-i = t-k-1 f.p.

x±k-1

+ (F1)k

t-k

log t 8(k) k

(x)

for any integer k > 0.

(5.7)

This loss of homogeneity does not occur in the case of the function x-k-1

Homogeneous Distributions

164

Indeed, the finite-part extension

x-k-10(x) dx

(f.p. x-k-1, 4b(x)) = f.p. E(O J XI>E

= H-k-1(0) + (-1)k+1H-k-I(M-10), satisfies x+k-1 + (_ l)k+1

f.p. x-k-1 = f.p.

f.p.

x_k-1

(5.8)

and so, by (5.7) and (5.6), f.p.(tx)-k-1 = t-k-1 f.p.x-k-1

if 0

(5.9)

t E IR.

One can formally integrate by parts k + 1 times to express (f.p. x-k-1, 0(x)) as a convergent integral.

Lemma 5.5 For q5 E S(R) and for any integer k > 0, 00 (f.p.x-k-1,,0(x))

r 0(k+1)(x)logIxI dx.

= k J o0

Proof. By (5.8) and Lemma 5.3,

(f.p.x-k-1, 0(x)) = H_k-1(0) + (-1)k+1H-k-I (M-1l) kk

E1

[O(k)(0) + (-1)k+I (M-10)(k)(0)]

k!J=1

(_l)k+1(M-1,)(k)),

+ k1 H-1 (.(k) + and thus, because (M_10)(k) = (-1)kM_1q5(k),

(f.p.x-k-1, q5(x)) = kI H_1 (0(k)

=

1

k1

f

°O

{

- M-I0(k)) (k+l)(x)

+.O(k+l)(-x)] logx dx,

giving the desired formula.

0

Later, when studying the Fourier transforms of f.p. xt and f.p. x-k-1, we shall encounter the distribution (x ± i0)', defined by

((x f MY', 0(x)) = li m foo (x ± iy)°4(x) dx, with the branch of z° = exp(a log z) chosen so that -ir < arg z < it.

(5.10)

Finite-Part Integrals

165

Lemma 5.6 The formula (5.10) defines a temperate distribution (x ± i0)' E S*(R), given by

(x ± i0)' = f.p. x+ + e}""` f.p. x° f o r a # -1, -2, -3, ... , and

(_ I k+l (x ± i0)-k-I = f.p. x-k-1 ± i7r

(k)

S

k

(x) for any integer k > 0.

Proof If Re a > -1, then we may apply the dominated convergence theorem to obtain the first formula. If -k - 1 < Re a < -k for some integer k > 0, so that Re(a + k) > -1, then integration by parts gives 00

(-1)k (x ± iy)a+k

foo

(a + ])(a+ 2)...(a + k)

f 00 (x + iy)aQb(x) dx =

01k) (x)

dx,

so in the limit as y 4. 0, we have (-1)k (xa+k + efin(a+k)xa+k)

((x f i0)a, fi(x)) _

(a + l)(a + 2) ... (a + k)

'

(k)

dk x+ k + (-1)kefinaxa+k dxk

and we have only to apply Exercise 5.3. However, when a = -k - 1,

L:x ± iy)14 (x) dx =

f log(x ± iy)

1(x) dx,

and since -n < arg(x ± iy) < it, yy im

log(x ± iy)

logx

ifx > 0,

log Ix I ± i7r

if x < 0.

Thus, by Lemma 5.5,

((x ±

i0)-k-1,

0(x)) =

00 flogIxI1)(x)dx

kI 1

k

_

° f(±iir)(x)dx

(f.p.x-k1, 0(x)) -

which yields the desired expression for (x ±

i0)-k-1.

ki (fiir) 0(k)(0),

Homogeneous Distributions

166

Extension from W'\{0} to 1[t" If U E L1,1oc(R" \ {0)), then we can try to define the finite-part extension f.p. u as a distribution on R' by writing

(f.p. U, 0) = f.p. f

u(x)¢(x) dx for O E D(R").

XI>E

In the special case when the finite part of the integral is just a limit, we speak of the principal value p.v. u, i.e.,

(p.v. U, ) = limJ

40 IXI>E

u(x)O (x) dx.

Suppose now that u E C°°(R' \ (0)) is homogeneous of degree a. By in-

troducing polar coordinates p = lxi and w = x/p, so that x = poi and dx = pn-1 dp dco, we find that

f

u(x)cb(x) dx = J

pat"-1-0 (pce)) dp dcv.

u(co) p>E

X I>E

This formula prompts us to define the linear operator Ra by Racb(x)

= f.p.

40 JE

po+n-1cb(px) 00

dp = (f P

p+++n-1,

(px))

for X E R" \ {0),

(5.11)

so that

(f.p. U, 0) =

JI of=1

u(c))Ra¢(co) dcv

for ¢ E S(R").

(5.12)

Here, to justify taking the finite part inside the integral with respect to co, it suffices to check that the o(1) term in the expansion of fE00 pa-n+l0(pco) dp tends to zero uniformly for lwJ = 1. As a consequence of Lemma 5.4, we are able to prove the following.

Theorem 5.7 Suppose that u E C°°(R" \ 0) is a homogeneous function of degree a.

(i) If a -n, -n - 1, -n - 2, ... , then f.p. u is the unique extension of u to a homogeneous distribution on W.

(ii) If a = -n - k for some integer k > 0, then a homogeneous extension

Extension from R" \ (0) to R"

167

exists if and only if u satisfies the orthogonality condition

whenever l a l= k.

wa u (co) d w= 0

(5.13)

In this case, the homogeneous extensions of u consist of all distributions of the form

f.p. u + Y' ca 8.8, Ial=k

with arbitrary coefficients ca E C.

Proof Consider

f

(Mr f.p. U, 0) = t-r" (f.p. U, MI/r4>) =

u(w)t-"RaMI/r4>(w) dcv.

IwI=I

Since RaMI/ra(w) = Ra4>(t-ico), we see from Exercise 5.4 that for a as in part (i), U(w)t-n(t-1)-a-lzRa4)(w)

(Mr f.p. U, 0) = f

dw = (ta f.p. u, 0).

wl=1

However, if a = -n - k, then (Mr f.p. U, 0) U(w)t-"

((t_t)kR_il_k4>(cv)

-

(t-1)klog(t-1)

Iwl=1

E aao(0)wa a

dw

lal=k

f.p. U, 0) +

t-"-k

as of

log t

a.

Ial=k

w"u(w) dw,

Iwl=1

so f.p. u is homogeneous on R" if and only if (5.13) holds. To settle the question of uniqueness, and to show the necessity of the orthogonality condition for existence if a = - n - k, let u E V* (R") be any extension of u. Since u - f.p. u = 0 on R" \ 0, Theorem 3.9 implies that

ii -f.p.u=Ecaa,3, a

where the sum is finite. The result follows because 8a8 is homogeneous of degree -n - lad; see Exercises 5.1 and 5.2.

Homogeneous Distributions

168

The next theorem complements the one above, and introduces a particularly important class of homogeneous functions satisfying the orthogonality condition (5.13).

Theorem 5.8 Suppose that u E C°O(R" \ {0)) is a homogeneous function of degree -n - k, for some integer k > 0. If u has parity opposite to k, i.e., if U (_X) = (_1)k+1 U (X) for x E R" \ {0},

(5.14)

then

(f.p. U, 0) =

p-k-1, O(pw)) dw for ¢ E S(R"),

12 f

Iwl=1

and f.p. u is the unique extension of u to a homogeneous distribution with parity opposite to k.

Proof. The parity condition (5.14) implies that (f.p. U, ci} =

f

u(-m)R-"-k.(-w) dw

Iwl=1

f

(-1)k+1u(w)R-n-k41(-w) dw,

wl=1

and by (5.6),

R-n-ko(-w) _ (f.p.

p+k-1,

(f.p.

p_k-1, O(pw)),

so we have

f =2 f

(f.p. U, ) = 1

2

u(w)[R-n-k O(w) + (-1)k+1R-n-k(-w)] dw

w l=t

u(w)(f.p. p+k-1 + (_1)k+1 f p

p- k-1, 0) dw,

wl=1

giving the desired formula; recall (5.8). The homogeneity of f.p. u follows from Theorem 5.7 because the parity condition (5.14) implies the orthogonality condition (5.13). Alternatively, one sees from (5.9) that

M, f.p. u = Itl-"t-k f.p. U

on R" fort E lR \ {0),

and in particular, f.p. u has parity opposite to k. Finally, if Ia I = k then F 8 has the same parity as k, so f.p. u is the only homogeneous extension of u having the opposite parity to k. 0

Fourier Transforms

169

The uniqueness results in Theorems 5.7 and 5.8 yield a simple proof of the following fact.

Theorem 5.9 Suppose that u E C°O(R" \ {0}) is a homogeneous function of degree a, and assume, if a = -n - k for some integer k > 0, that u has parity opposite to k. Then for any multi-index a, 8 " f.p. u = f.p.(a"u)

on I[8".

P r o o f By Exercise 5.2, if a # -1, -2, -3, ... , then a" f.p. u and f.p.(a"u) are homogeneous extensions of a"u with degree a - I a I , and must therefore coincide. If a = -n - k but u has parity opposite to k, then

a"u(-x) _(-1)k+I"I+1a"u(x) for 0 0 x E W, so 8"u is homogeneous of degree -n - (k + lal) and has parity opposite to k + la l. Thus, a" f.p. u and f.p.(a"u) are again homogeneous extensions

0

of a"u, and both have parity opposite to k, so they must coincide.

Fourier Transforms Our aim in this section is to compute the Fourier transform of the finite-part extension of a homogeneous function. Following the pattern of previous sections, the one-dimensional distributions f.p. xf and f.p. x-k-1 will be treated first. In order to state the next lemma, we require the gamma function,

'(a)

=f

00

forRea>0.

In the usual way, r is extended by means of the identity

r(a + l) = ar(a) to a meromorphic function on C having simple poles at 0, -1, -2, ... , and satisfying r (k + 1) = k ! for any integer k > 0. T:r_.4 {f.p. x' 1. If a # -1, -2, -3, ... , then

Lemma 5.10 Let IIa

}

r1Q ()

_

r(a + 1) (±i2ir)"+1

(

i0)

,

but for any integer k > 0,

IZ}k-1( ) _

(:Fi2 r

k

(1o27rll ± 12 sign() - r'(1) - E

I

j=1 I

(When k = 0, the empty sum over j is interpreted as zero.)

Homogeneous Distributions

170

Proof To begin with, suppose that Re a > -1. For any 17 > 0, the function e-2nglxlx11 belongs to LI(R), and 00

Fx,

{e-2nglxlXa l = fJ J

t

dx.

Making the substitution z = 27r (ri f ii )x, and then applying Cauchy's theorem to shift the contour of integration back to the positive real axis, we find that o

[27r(ii±i

_

(±i27r)a+l

e-zzadz

Jo

J

1

00

a1??)--1

1'(a + 1) (

Sending ri J, 0, we obtain the first part of the lemma for Re a > -1, and the

case Re a < -1 then follows by analytic continuation; see Exercise 5.6. For the second part of the lemma, consider 00

H_k-1,E

)=f

(a-i2Trl

e-ibrtxx-k-1 dx,

E

where f,.00 is interpreted as limn. fE if k = 0. Suppose l; E R}, and make ±i27rIr; Ix to obtain the substitution z = H-k-I,E(e-i2n1;,)

_

(i27rf)k

f fi00 Jti2ir I IE

e-:.z-k-1 dz.

Applying Cauchy's theorem (and Jordan's lemma, if k = 0), we see that fi0c

2,rI

i2n1? IE

f.

o00

e-zz-k-1 dz =

e-zz-k-1

dz = f 1

4

=±

e-zZ-k-I dz

- fc.,

e-zz-k-1 dz,

IE

f

e-zz-k-1

resse-zz-k-1

=

dz

(_I)_ k

o l2

(i27rj)k (H_k_I.2rIIE() T

k

i7r (-1)k 2

k!

)

Fourier Transforms

171

By Exercise 5.7 together with Lemma 5.3, we have f-

k' 0) log 27r l

P (0)

(P

k!

- (-1)k k

k

- - tog27r ICI + k! H-t 1

1

i=t J

E i=t k

1

J

- l0 g27r ICI+e-xlogxdx

I

(-i27rt)k

i7r

2 sign(t)-1

kt

(f.p. xk-', fi(x)) = f.p. f

x-k-t f

J

E

oo

,

k (1)-E _1

i=t

00

(n-k-t'

I

I

e-i2n1XO(t) dt dx

00

00 Elo

foo

where the final step is justified because the o(1) term in the expansion of can be bounded by f (E)g(t), with f (E) = o(1) as c 4. 0, and g(') having only polynomial growth as It I oo. The formula for n±k-i (t) H_k-t.E(e-i2"t')

is now established, and the one for II-k-t (t) then follows by (5.6) because the 0 Fourier transform commutes with M_ t; see Exercise 5.8.

As an immediate consequence of Lemmas 5.6 and 5.10, we obtain the formulae below; see also Exercise 5.10. Corollary 5.11 F o r a n y integer k, let 1-lk() =

.

_

1 nk(t,) = (-i2zr s'kl(t) and l1-k_, (t) _ ( )k

{f-p. xk}. If k > 0, then 1227r 7r

tk sign(t).

Turning to the general, n-dimensional setting, we require the following technical lemma.

Homogeneous Distributions

172

Lemma 5.12 Let a E C and U E D* (R" ). If u is homogeneous of degree a on R" \ {O}, i.e., if Mtu = tau on Rn \ {0} for all t > 0, then u E S*(R"). If, in addition, u is CO° on R" \ (0), then u is C°° on R' \ (0). Proof Let* E C mP (R" \f0}) be as in Exercise 5.12, and define X E C mP (R" ) by X(x)=1-J1

*(tx)

dt

forxER".

0

Put uO = Xu and ul = (1 - X)u; then uo E S* and uo E C°°(R") because uo has compact support, so it suffices to consider u I. We have

(ui, ) = (j' ir(tx)

a tu(x),

0(x)=

f '(u,

OM1

fr)

dt

for q E D(Rn),

(u, OM *) = (u, Mt (*Ml/t-O)) = (t-"Ml/tu, rMl/to)

= t-n-a(u, *M,1, 0). Let K = supp *; then there is an integer k such that

1(u, iMi,t4)I < C E max I aa(*Mltt4) I< C E t-I°`I max I a"O(t-lx)I lal
xEK

Ial
Choose an integer r > n + Re a; then because 0 gi~ K, t-IaI

max I

a"0(t-lx)I

xEK

< Ct-IaIXEK max E IxI6aa0(t-1x)1 lfll=r+Ial

< Ctr

E max IfiI=r+Ial

l(t-lx)I

aa4(t-lx)I,

XEK

so

I(ul, 0 :5 C

f

E sup 1: I#I=r+lal YER"

1

tr-n-Rea

dt

J0

showing that ul E S* Now make the additional assumption that u is CO° on R \ (0). Since X = 1 on a neighbourhood of 0, we see that u 1 is C°° on R", and (RI).

laaul(x)I < C(1 +

IxI)Rea-lal

forx E R".

Fourier Transforms

173

Hence, if L81 > n + ja I + Re a, then the function 8. [(-i2zrx)a u 1(x)] belongs to L 1(1 ' ), and we deduce from (3.17) that (i2iri; )O 8"u i

is continuous

onR R.

Lemma 5.12 shows that the Fourier transform of a homogeneous distribution always exists as a temperate distribution. Furthermore, the following holds. Theorem S.13 Let a E C. If u is a homogeneous distribution of degree a on I[2",

then its Fourier transform u is a homogeneous distribution of degree -a - n

on R. Proof. For t > 0 and 0 E D(R ),

(Mru, 0) = (Mr.Tu, ) = t-"(u, .FM1/ro), and by Exercise 5.8, t-"(u, .FM11r4) = t-"(u, t"M,.Fo) = t-"(M111u, F4) _ (t-n-au, ,F4) = (t-n-a Fu, 95),

so Mrir. = t-n-au.

If U E C°°(lf8" \ (0)) is homogeneous of degree a, then by Lemma 5.12 the finite-part extension f.p. u is a temperate distribution on 1l8", and, recalling (5.12), the Fourier transform of f.p. u is given by

(.F f.p. U, 0) = (f.p. U, ) =

dco

JIwI=1

for g5E S( (5.15)

We can express Raq in terms of the one-dimensional Fourier transform in Lemma 5.10.

Lemma 5.14 If X E 1[8" \ {0}, then

Rac(x) = (n +n-1(S

x), ( ))

for 4 E S(R").

40+11-1, (px)). To express the Proof By (5.11), we have (f.p. function p H c (px) as a one-dimensional Fourier transform, we make the substitution = i;1 + tx/Ix12, where t = i; x and thus '_r is the orthogonal

projection of onto the hyperplane normal to x. In this way,

(px) = J 0 f tl=o

t l dal dt

_

(p),

Homogeneous Distributions

174

where

0,'(0 =

1+

Ixl JX =o

IX12x

dal,

so

Rac(Px) = (f.p p++n 1, O^x (P)) = (na+n-! OS) Now see Exercise 5.11.

Together, (5.15) and Lemma 5.14 show that the Fourier transform of f.p. u is given by

f.p.u,q5)= f

))dw for

u(w)(n

Iwl=

ES(R'), (5.16)

and similarly, the inverse Fourier transform of f.p. u is given by

u(w)(II +,:-1(-x w), q5(x)) dcv for O E S(R").

(.F* f.p. U, 0) Iwl=1

(5.17)

If Re a < I - n so that

E L 1,10c (R), then we may write

(f.p. u(x)) = and

-,C{f.p. u(i )} =

L

IIa+n-1(

co)u(a)) do)

I=1

Iwsee

f

]Ia}n-1(-x w)u(w) dco;

(5.18)

Exercise 5.12 for alternative formulae that do not require any restriction on a.

Change of Variables

We wish to investigate the effect of a change of variable x = K(y), where K : S2" -+ S2 is a Cx diffeomorphism satisfying K (O) = 0,

and S2" and S2 are open neighbourhoods of 0 in R". For any E > 0, let BE={yER,':lyl<E}

Change of Variables

175

denote the open ball in 1R" with radius c and centre 0, so that if u E L 1.10c (Q \ (0} )

and 0 E D(Q), then

J

u(x)O (x) dx = J

(5.19)

Theorem 5.15 below implies the existence of the finite part of the right-hand side of (5.19) when u is homogeneous, or, more generally, when u is the sum of finitely many homogeneous functions and a remainder term that is integrable on Q.

Theorem 5.15 If U E C°°(1R" \ (0}) is homogeneous of degree a, then there exist E > 0 and functions wo, w1, w2, ... and Ro, R1, R2, ... with the following properties: (i) For every m > 0, the composite function u o K admits the expansion m

u(K(Y)) _ > wi(y) + R,. (y) for0 < IYI < E. i=o

(ii) For every j > 0, the function wj is C°O on IR" \ (0) and homogeneous of degree a + j :

wj (ty) = t'

wi (y)

fort >0 and y ER' ' \ {0}.

(iii) For every m > 0, the function R, is CO° on BE \ (0) and, for every multi-index a, IaaRm(y)1 <

C".alylO+m+l-IaI

for0 < IYI <

c.

If, in addition, a = -n - k for some integer k > 0, and u satisfies the parity condition (5.14), then for all j > 0 the parity of the function wj is opposite to that of k - j, i.e.,

wj(-x) = (-1)k-'+1 w! (x) for x E IR" \ {0). Proof Since K is a diffeomorphism, the derivative K'(0) : morphism, and since K (O) = 0, K(Y) = K'(O)y + C(IYI2)

R" is an iso-

as y -- 0.

Letting h(y) = K(y) - K'(0)y, we see that there exists E > 0 such that cIYl < IK'(0)Y + th(y)l < CI yI

for 0 < Iyl < E and 0t1.

Homogeneous Distributions

176

Thus, by Taylor expansion of u about K'(0)y,

lI u(i) (K'(0)Y; h (Y)) + Rm.I (Y),

U (K (Y)) _

j!

j=0

where

1 JrI (1 - t)mu(m+I)(K'(0)y + th(Y); h(Y)) dt.

R,,,,1(y) =

M!

0

In turn, Taylor expansion of h about 0 allows us to write m

h(Y) _ >2 hr(Y) + R,,,,2(Y), r=2

where

hr(Y) = 1 K(r)(0;

r!

and

Y)

R..2 (Y) =

1 m!

ft J 0

(1 - t),,,K(,,,+I)(ty; Y) dt.

Hence,

_

m

u(P) (K'(0)Y; h(Y)) _ > ... >2 u(P) (K'(0)Y; hr, (Y), ... , hrp (Y)) + Rm.p(Y), r,=2

r,,=2

and we see that

w3(y) = > l u(P) (K'(0) Y; hr, (Y), ... , hr,, (Y)), I

P where the sum is over all p > 0, rl > 2, ... , rp > 2 satisfying rl + ...+ rp - p = j

(Notice that j ? p > 0.) Since a"u is homogeneous of degree a - Ial, and hr is homogeneous of degree r, it follows that w j is homogeneous of degree

a - p + rI +

+ rp = a + j. The estimates for Rm(y) follow from the

bounds CIYIa+m+I-laI

IaaRm,t(Y)I <

and

IaaR,,,,2(Y)I < Cmin (1,

IYIm+I-lal)

for 0 < lyl < E. Finally, if a = -n - k and u(-x) = (-1)1+lu(x), then

8"u(-x) =

(-1)1+l-I"I8"u(x)

and so the term wj is homogeneous of de-

gree -n - (k - j), with W j (-Y) =

=

pi (-K'(0)Y; hr, (-Y), ..., hrp (-y)) > u(P) (-1)k+l-P+r,+...+rPwj(Y)

because hr(-y) = (-l)rhr(y).

0

Change of Variables

177

Now consider the left-hand side of (5.19). Since K(QK \ BE) = 2 \ K(BE), the question arises as to whether f.p. Eyo

JS2\K(BE)

u(x),o (x) dx = f.p. Eyo

r

JS2\BE

u(x)o(x) dx.

In fact, Exercise 5.7 shows that these two finite-part integrals can differ, even if K is linear, when a is an integer less than or equal to -n. Once again, we seek first to understand the one-dimensional case.

Lemma 5.16 Suppose n = 1. If a # -1, -2, -3, ..., then 00

f.p.

f

xacb(x) dx = (f.p. x+, 0(x))

(5.20)

(f)

and for any integer k > 0, f.p.

JR\K(BE)

x-k-10(x) dx = (f.p. x-k-1, 0(x))

(5.21)

Proof The case Re a > -I is trivial, so suppose that Re a > -k - 1 and a # -1, -2, ... , -k for some integer k > 1. Integration by parts gives [K (E)]a+10 (K (E))

Ha+1,K(E) ('Y')

a+1

a+1

'

and by Taylor expansion, [K(E)]a+10 (K(E)) =

k-1 0(f)(0)

E

[K(E)] a+j+1 + O(Ea+k+1 )

j=o and

k-l Ea+l+l +

[K (E)]a+j+l =

Cjl l=j

for some cjl E R. Thus, f.p.[K(E)]a+l0(K(E)) = 0, and we have -1

f' P' Ha,K(E)(0) = OE O

f.p. Ha+1K(E)(h'), a+140

Homogeneous Distributions

178

provided the right-hand side exists. Induction on k yields f.p. Ha.K(E)(W) = f.p. Elo

CIO

(-1)kHa+k,K(E)(T (k))

(a+ 1)(a+2)...(a+k) (-1)k Ha+k (O(k) )

(a + 1)(a +

k)'

which, by Lemma 5.3, shows that (5.20) holds. To prove (5.21), let where

f.p. Jk,E(b),

x-k-10 (x) dx.

Jk,E(0) = f \K(BE)

E4.O

If we can show that

Jk(0) =

ki f

(k+1)

(x) log IxI dx,

(5.22)

then (5.21) will follow by Lemma 5.5. Integration by parts gives

JO,E(4) = 0(K(-E)) log IK(-E)I - O(K(E)) log IK(E)I

'(x) log IxI dx, R\K(B,)

and by Taylor expansion, 4 (K (±E)) log IK (±E) I = ¢ (0) log IK'(0)E I + O (clog

1

f,

so (5.22) holds for k = 0. If k > 0, then E(K(E)) k[K(E)]k

=

Jk-1,CW) k

(K (-6)) k[K(-E)]k

+

k

k"¢(i)(0) /

+ f=p

J!

1

[K(E)]k-i

1

1

[K(-E)]k-iJ

+0(6).

Given any integer m > 1, we can define a C°° function f : SZ -+ IR by

(K(y))a=

1

[K'(0)]m

ifyES2\0,

ify=0,

Change of Variables

179

and so f. p. E JO

1

{K(±E)j'n

L p. EO

f (±E) =

f

(±E)m

cnn)

(0) mI

Thus,

Jk(0) =

Jk-l(0') k

and (5.22) follows by induction on k.

For c sufficiently small, the set K(BE) is approximately ellipsoidal and can be described using the function g in the next lemma. Recall that Sn-' = {w E R" : I w I = 1 } denotes the unit sphere in R". Lemma 5.17 There is an co > 0 and a C°O function g : (-EO, EO) X

n S-1

-o- IIB,

such that

K(BE)fl(pw:0
(5.23)

Moreover, g satisfies

g(E, w) = -g(-E, -w) and

IaEg(E, w)I

Cj,

(5.24)

foriEi 0. Proof. Choose po > 0 such that tw E cZ for It1 < po and IwI = 1, and define f (t, w) = sign(t) IK-' (tw)1. Since K-' (0) = 0, Taylor's theorem gives

K-' (tw) = tLw + t2M(t, w), where

L = (K-')'(0)

and

M(t, w) =

f

(1 - s)(K')2(stw; w) ds.

Thus, f (t, co) = t I Lw + tM(t, w) I,

Homogeneous Distributions

180

and, because La) 0 0 for Iwl = 1, there is a pi E (0, po) such that f (t, co) is Cx for Itl < pi and Iwl = 1. The uniform bound 8t f (0, (o) = I L(vI ? c > 0 means that we can apply the implicit function theorem and define g by

f(t,w)=E # t=g(E,w), for I E I < Eo, with co > 0 independent of w. The relation (5.23) follows because, for Ix I < co,

K(x)=pw

p=g(Ixl,w),

and because g(E, c)) is a monotonically increasing function of E. Finally, (5.24)

holds because f (t, w) = -f(-t, -w) and because I a/ f (t, w)1 < Cj for Itl < pi and lwl = 1. We are at last in a position to prove the main result for this section; see Kieser [48, Satz 2.2.12] for the original proof using the calculus of pseudodifferential operators.

Theorem 5.18 Let K : S2" -+ 0 be a diffeomorphism with K(0) = 0, as above,

and suppose that u E C°°(]R" \ 0) is homogeneous of degree a. If a # -n,

-n - 1, -n - 2, ... , or if a = -n - k (k > 0) but u satisfies the parity condition (5.14), then

f.p. J "\K(B,) u(x)c(x) dx = (f.p. u, EO

)

for

E

and hence

f f.p. J \B, u(x)4(x)dx = f.p. Elo E.(.O

u (K (y)) 0 (K (y)) I detK'(y)I dy \B,

for 0 E D(Q). Proof Using the notation in Lemma 5.17 and making the substitution x = pw, we have 00

f

u(x)cb(x) dx = "\K(B,)

JIml=1

u(w)

Jg(E.W)

pa+n-10(pw) dp dw

for0<E <Eo. If a # -n - k, then by Lemma 5.16, f.p.

oo

pa+n-io(pw) dp = Et.o Jg(E,o)

(f.p.

4(pw)) = Ra (w),

Finite-Part Integrals on Surfaces

181

and the result follows at once from (5.12). If a = -n - k and u satisfies (5.14), then

f f

f

u(w)

00

p-k-'O

(pcv)dpdo)

Jg(E,w)

=J

u(-w) J

=

f

u(w) I

g(-E.w)

p-k-)¢(pw)dpdw

-oo

Iw1=)

=

dpdcv

g(E.-w)

L.

21 fl-1=1 u(w)fR\K.(B,)

where Kw is the one-dimensional diffeomorphism defined by K (E) = g (E, w). Hence, it suffices to apply Theorem 5.8 and Lemma 5.16.

Finite-Part Integrals on Surfaces Although we shall avoid making explicit use of the results in this section they nevertheless give some insight into the nature of the surface potentials and boundary integral operators encountered in the later chapters. Consider a C°° surface of the form

F=

(5.25)

and assume that the origin has been chosen so that (O) = 0. By (3.28), if and 0 E D(r), then uE

fr u(x)fi(x)

do. =

f

wi-I

dx'.

u(x', (x'))O(x', (x')) 1 +

For finite-part integrals on 1, we have the following result of Kieser [48, Satz 4.3.9].

Theorem 5.19 Let I' be a C°O surface passing though the origin, as above, and -n + 1, suppose that u E C°°(]R" \ (01) is homogeneous of degree a. If a

-n, -n - 1, ... , or if a = -n + 1 - k (k > 0) but u satisfies u(-x) _ (-1)k+)u(x), then f.p. Elo

f

u(x)O(x) dox \B.

= f.p. E.IA

for 0 E D(r).

f IX'1>E

u(x', (x'))O(x', (x')) 1 +

dx'

Homogeneous Distributions

182

Proof We introduce polar coordinates in R"-', writing

x' = rw,

r = Ix'I,

co = x'/r E S!,-2.

For X E F, we have IX 12 = r2 + (r(0)2, and so

x E F \ BE f r l +

E.

Since (0) = 0, there exists EO > 0 and a C°O function g : (-EO, EO) X S"-2 R such that 1' \ BE = { (x', (x')) : x' = rw, r > g (E, co) and w E Sn-2 }

for 0 < E < co,

with g(E, w) _ -g(-E, -co); cf. Lemma 5.17. The result follows by arguing as in the proof of Theorem 5.18, remembering that now the integral is over RI-I instead of R". Finite-part integrals on surfaces arise as boundary values of functions of the form

f (x) _ f u(x - y),/i(y) day for x E R" \ IF, r

(5.26)

where the integral is divergent if x E F. We shall consider u of the following type.

Assumption 5.20 The distribution u is of the form

u(x) = Jct%x[v(4))

with

P( )

where p and q are homogeneous polynomials satisfying

(degree of p) - (degree of q) = j - 1 for some j > -n + 2, and in addition

q(); 0 forall ER' \{0). Thus, V E C°O(R" \ {0)) is homogeneous of degree j - 1, and so is locally integrable on lid" because j - 1 > -n + 1. By Theorem 5.13, we see that u is a homogeneous distribution on ][l;" of degree -n + 1 - j, and by Lemma 5.12, u is C°° on R" \ {0}. Also, by Exercise 5.8,

v(-l;) = (-1)'-'v(l;)

and

u(-x) = (-1)j-lu(x).

(5.27)

Finite-Part Integrals on Surfaces

183

Figure 4. Integration contours in the definition (5.28) of f }.

To begin with, we investigate the simplest case, when I' = R' ' and so

f(x) =

f

u(x' - Y', x")ir(Y) dy'

for x,,

0.

The next lemma gives an alternative representation for f in terms of the Fourier transform of *. We denote the upper and lower complex half planes by

C+={zEC:Imz>O} and C-={zEC:Imz<0}, put

and let C± and C,- be the closed, semicircular contours shown in Figure 4. If w(z) is continuous for z in the closed half plane Ct U R, and analytic for Iz I > ro and z E C}, then we denote the integral of w over C} by

f w(z) dz =

f

cr

w(z) dz

for r >ro.

By Cauchy's theorem, this integral is independent of r.

Lemma 5.21 If u satisfies Assumption 5.20, and if i,r E S(Ri-1), then

f (x) =

forx E R±,

where

m±(', x") =

f

f

Furthermore,

t-ix,,) = tim±(',

fort >0 and i'540,

(5.28)

Homogeneous Distributions

184 and

m+(-C, -xn) = (_1)r-'m-(', xn). Proof The function f has a natural extension to a distribution on R", namely the convolution u * (i/r 0 8), where (Vr (9 8)(y) = +/r(y')S(y"). Hence, for all 0 E S(II8"),

(f, 0) = (u * (tk 0 8), .F.F*O) = (F[u * ( ® S)], f*O)

= J '*O. Suppose now that supp o c R". In this case, for each i;' the function ¢( ', ) is continuous on C± U R, is analytic on C±, and satisfies where

bounds of the form

4(01:5 CM,N(1 + WD-MO + It U-" fore' E R` I and

E C} U

Hence,

H t"

f

d'n oo

and to shift the contour of integration in the "-plane, we consider the poles of putting Z(i') = ( " E C : q('', l") = 0 ). Since q is homogeneous, we have Z(ti;') = and since the coefficients of the polynomial q(i', ) are continuous functions of ',

for

f

f

00

d ,= =

v( 00

=

f v()() d = f f f

v(

)ei2'

x0 (x) dx d "

x,:) dx.

yR 'RI,

the substitution z = ti;, gives

Finally, since

m±(t ', t-ixn) =

f fv(t)ei2ht x t

dz

trm f(i;, x),

Finite-Part Integrals on Surfaces

185

the substitution z = - gives

and since

M+(-C, -xn) =

dz

Jfc;

f

C,

by (5.27).

which equals

Since m±(k', is a C°C function of x,,, we see that the restrictions f I w. and f IR,. can be extended to C°O functions on R. We now consider the one-sided boundary values of f on the hyperplane x, = 0, given by

f.+(x') =

lim

Z--s(X'.o),ZEWI

f (z) = fR11

-I

mf(',

')e'2rtX d ' for X' E R!'- 1.

Theorem 5.22 Suppose that u satisfies Assumption 5 .20, and that i E S(Il8i-1)

(i) If j < -1, then f+ W) = .t--(x') =

f

u(x' - y', 0)f(y') dy'.

(5.29)

Rn-1

(ii) If j > 0, then

f+ (x') + f_(x') = 2 f.p. E4O

f

IX'-Y'l>E

u(x' - y', 0)i(y') dy',

and the jump in f across the hyperplane x = 0 has the form

f+(x') - f-(x') = E c«a°*(x'), IaI=i

for some coefficients Cc, E C.

Proof Using the sum and difference of m+ and m_, we define us(x')

where

ms( ') =

0) + m-( ', 0),

and

ud(x') =

where md(') = m+(,', 0) - m-(', 0),

Homogeneous Distributions

186

so that

f++f_=u5*ifr

f+-f_=ud*1/r.

and

By Lemma 5.21, m5 and and are homogeneous of degree j, and satisfy

(-1)'-lm5(4') and md(- ') = (-1)'md('), so us and Ud are homogeneous distributions on R" of degree -j - (n - 1), and satisfy

u5(-x') = (-1)1-1u5(x')

and

ud(-x') = (-1)!ud(x').

Since u(x - y) is C°° for x # y, it is easy to see that if x'

supp *, then (5.29) holds (even if j > 0), and in particular f+ (x') - f- (x') = 0. Therefore

suppud(x' - ) c {x'}. If j < -1, then Ud E L111,,(Rn-1) so Ud = 0. If j > 0, then, with the help of Theorem 3.9 and Exercise 5.1, we deduce from the homogeneity of Ud that

Ud*t/t= Ecaaa*, lal=i

for some ca E C. Furthermore, u5(x' - y') = 2u(x' - y', 0) for x'

y', because (5.29) holds when x' f supp *, so the homogeneous distributions u5 and 0) are equal on R"-1 \ {0}. Since both have degree -(n - 1) - j 2f.p. and parity j - 1, we see by Theorem 5.8 (applied in R11- 1, not R") that in fact D 0) as distributions on R' 1. us = 2 f.p. Suppose now that r is the graph of a C°° function We denote the epigraph and hypograph of by

Q' _ {x E 1R" : x" > C(x')}

: IRi-1 -+ R, as in (5.25).

S2- = {x E 1R" : x < (x')},

and

and denote the boundary values oof the function f defined in (5.26) by

ft(x) =

lim

J u(z - y)*(y) day for x E F. r

It is possible to generalise Theorem 5.22 as follows.

Theorem 5.23 As before, let r be the CO° surface (5.25), with (0) = 0. If u satisfies Assumption 5.20, and if r E D(r), then the restrictions f Iu+ and f In-

can be extended to C°O functions on 1R1. Moreover, for x = (x', (x')) E F we have

(i) if j < -1, then /'

f+(x) = f-(x) = J u(x - y)f(y) day; r

Exercises

187

(ii) if j > 0, then

u(x - y)f(y)dav f+(x)+f-(x) =2f.p.J 40 r\e, (x) and, for some coefficients ba E C°O (Rn-1),

f+(x) - f-(x) = E ba(x')8 I (x', (x')). Ia1
We shall not prove this result, because techniques from the theory of pseudodifferential operators would be required; cf. Kieser [48, Satz 4.3.6] or Chazarain and Piriou [ 10, p. 280]. In all subsequent proofs, we avoid using Theorem 5.23. It does, however, help to account for some of our results in Chapter 7.

Exercises

5.1 Show that the Dirac distribution 8 E D* (R") is homogeneous of de-

gree -n. 5.2 Show that if u E CcO(R" \ {0}) is homogeneous of degree a E C as a function on R" \ (0), then for any multi-index a the partial derivative 8"u is homogeneous of degree a - lad on R" \ {0). Show further that if a E D*(R") is homogeneous of degree a as a distribution on R", then 8"u is homogeneous of degree a - IaI on R". 5.3 Show that

d -

f.p. x} = ±a f.p. x f

1

for a

-1, -2, -3, ... ,

-

but

d f.p. x fk =- Fk-f .p. xtk-1 ± (k i)k

6(k) (x)

for any integer k > 1.

Deduce that

dx

f.p. x-k = -k f.p.

x-k-1

5.4 Recall the definition (5.11) of Ra0. Show that if 0 E D(R"), t > 0 and

xEIR"\{0},then R0¢(tx) = t-a-"RaO(x)

for a O -n, -n - 1, -n - 2, ...,

Exercises

188 but

R-n-k 0(tx) = tkR-n-k4 (x) - tk logt E

8 0i )x

I"I=k

a!

for any integer k > 0.

5.5 Show that if u is a homogeneous function in C°°(]RI \ {0}), and if * E

C' (R"), then* f.p. u = f.p.(*u). 5.6 Show that for each 0 E S(R), the function a H H,,(0) is analytic for a ¢ -1, -2, -3, ... , with all simple poles, and residues ck)(0)

res

a=-k-l Ha(4) _

kI

5.7 Show that if A > 0 and 0 E S(R), then Otki0)

f.p. H_k-l,AE(O) = H-k-1(0) -

logA

Ej0

for any integer k > 0. 5.8 Show that for t 0,

M,T= ItI-"FM111,

M,.7 r'*= ItI-"-T*MI1t,

,'Mr = ItI-"M111.P, F*Mt = ItI-"Mllt.'F*. 5.9 Show that f.p. El0

J

x°-1 a-z dx = F(a)

for a E C \ (0, -1, -2, ...}.

E

5.10 Prove Corollary 5.11 directly, i.e., without using Lemma 5.10. For the first part, use (3.17), and for the second part, show that H_A_I (e- i2a

)=

(-12Jt)k+1 2kl

k

for any integer k > 0.

sign (s)

5.11 Show that if u E L1,10c (R) and 0 E D(R"), then

u(t)oa(t)dt,

.ifR." u(a x)q5 (x) dx = FOO

where

f

0. (t) = l

al I

.,.L=O O

(x' + talla) dxl, I

Exercises

189

and dx 1 is the surface element on the (n - 1)-dimensional hyperplane

normal to a. Show further that 0a E D(R), and that if u is a distribution on R, then u(a x) makes sense as a distribution on I[8". 5.12 Derive alternative formulae to (5.12), (5.16) and (5.17), as follows. (i) Show that there exists f E C mP (0, oo) satisfying

r

00

f (t)

dt t

00

=1

and fo

f (t) log t dt = 0.

[Hint: look for f in the form f (t) = Cg (At) for appropriate constants

C>0and),>0.] (ii) Deduce that the cutoff function 1i (x) = f (Ix 1) belongs to Cmp (R" \ {0}), and satisfies

I

W

(tx) t = 1 and

f0*

(tx) logt

dlog

IxI

for x E R" \ {0}.

(iii) Show that if u E C0(R" \ {0}) is homogeneous of degree a, then (f.p. U, ¢) =

J

u(x)*(x)RQ¢(x) dx

for O E S(W").

(iv) Deduce that

TX,g{f.p.u(x)} = (n

*(x)u(x))

and

)7":(f-p-U(0) = (nt+n-1(-S . x), / (f)u( )) 5.13 Show that if u E C°°(Il8" \ (0)) is homogeneous of degree -n - k for some integer k > 0, and if u satisfies the parity condition (5.14), then

",(f.p.u( )} _

fl-k-1 (-x co)u(w)dco

-1

2 1.1=i (i2ir)k+1

4k!

J WI=i

sign(x CO) (X w)ku(w) dw.

5.14 Suppose that K E C°°(R" \ {0}) is homogeneous of degree -n, and that

K(w)dw=0. Iw1=1

Exercises

190

Define

K(x-y)u(y)dy forx ER",

KEu(x)=J ly-xl>E

whenever this integral exists and is finite, and put

Ku(x) = limKEu(x), whenever this limit exists. (i) Show that if u is Holder-continuous and has compact support, then

Ku (x) = I

K(x - y)[u(y) - u(x)] dy

Ix-yl
where px > 0 is any number such that u (y) = 0 for Ix - y I > Px (ii) Show, with the assumptions of (i), that KEu -* Ku uniformly on compact subsets of R. (iii) Show that p.v. K exists and is a homogeneous distribution of degree -n on R. [Hint: see Theorem 5.7.] (iv) Show that Ku = (p.v. K) * u. C II u II Hs (R") for -oo < s < oo, and (v) Deduce that II Ku II H (w') that I Ku IK < C I u I ,,, for 0 < .t < 1. [Hint: use Theorem 5.13 and Lemma 3.15.]

6

Surface Potentials

Following the notation of Chapter 4, we consider a second-order partial differential operator n

n

n

Pu = -TL: aj(Ajkaku) +>Ajaju + Au. J=1 k=1

J=1

From this point onwards, we shall always assume that P has C°O coefficients and is strongly elliptic on W. Thus, Alk, Aj and A are (bounded) C°O functions from R" into CmXI, with the leading coefficients satisfying n

n

Re >2>2[Ajk(x)4k71]* jrl ? CIA121,712

for x,

E R" and rl E Cm .

j=1 k=1 (6.1)

In this and subsequent chapters, we shall develop integral equation methods for solving boundary value problems involving P. Such methods require a twosided inverse for P, or, more precisely, they require a linear operator !9 with the property that

PGu = u = GPu for u E £*(R")"'.

(6.2)

Since P is a partial differential operator, it is natural to seek g in the form of an integral operator:

1

CJu(x) = f G(x, y)u(y) dy for x E W.

(6.3)

R's

The kernel G is said to be a fundamental solution for P, and the same term is also applied to the operator g, although we shall sometimes refer to the latter as a volume potential. We shall also work with a kind of approximate fundamental solution, known as a parametrix, that is generally easier to construct. 191

Surface Potentials

192

The plan of the chapter is as follows. The first two sections set out the main properties of parametrices and fundamental solutions, emphasising the simplest case when P has constant coefficients. Next, we prove the third Green identity, in which the single- and double-layer potentials arise. Following the approach of Costabel [14], we then prove the jump relations and mapping properties of these surface potentials for the case of a Lipschitz domain. The final section of the chapter establishes some relations between the surface potentials associated with P and those associated with P*.

Parametrices A smoothing operator on R" is an integral operator

)Cu(x) _ ! K(x, y)u(y)dy forx E R", whose kernel K is C°O from R" such K satisfies

into C" xm a it is easy to see that any

E(

K : E* (R")'"

Conversely, it can be shown that every continuous linear operator from E* (R") into E(IR")m has a C°° kernel; see [10, p. 28].

A linear operator G : E*(Rn)"' -+ D* (W)"' is called a parametrix for P if there exist smoothing operators K 1 and K2 such that

PGu = u - Klu and GPu = u - /C2u

for U E E* (W')'.

(6.4)

Roughly speaking, a parametrix allows us to invert P modulo smooth functions. Later, we shall write G as an integral operator as in (6.3), and refer also to its kernel G (x, y) as a parametrix for P. When P has constant coefficients, we can easily construct a parametrix via the Fourier transform. Indeed, let PO and P (t;) denote the polynomials corresponding to Po and P, respectively, i.e., n

Po(e) =

(27r)2

j Ajk k j=1 k=1

and

P( j=1

Parametrices

193

For any u E S* (R")'",

and

.7=x_{Pou(x)} = Po( )u( )

{Pu(x)} =

..F

and the strong ellipticity condition (6.1) can be written as for

Re77*Po(')'1 ?

E R" and 17 E C"'.

then Thus, if b = Re r7*b < 17711b1, giving follows that the £2 matrix norm of Po(e)-1 satisfies the bound IPo( )-11 <

cII2

for 0

(6.5) Ib1. It

E R",

(6.6)

so we can find po > 0 such that n 1

Po(t)-l(i27r)>2AJ

J

4 and

1

1

AI < 4

for ICI > po,

and hence C

IP(A)-1I <

ICI'-

(6.7)

for ICI > po.

Fix a cutoff function X E C mP (R") satisfying

and define

Gu(x) =

for I I < 2po,

1

X

,

{[1

- X()lP( )-lu(g)}.

(6.8)

We observe that g is an integral operator as in (6.3) with kernel

G(x, y) = G(x - y),

where G(z) =

{[1

-

)-1 }.

(6.9)

Theorem 6.1 If the strongly elliptic operator P has constant coefficients, then the formula (6.8) defines a parametrix for P, and moreover G : Hs-1(Rn)m -+ Hs+1(R")"'

for -oo < s < oo.

Proof It is easy to see that G : S(R")' -+ S(R")"'

and

9 : S*(R")m -+ S*(R")m,

Surface Potentials

194

and since.F{PGu} = u - xu = .F{GPu} the condition (6.4) is satisfied with K1 u = 1C2u = .F* {x u}, or equivalently, with

Ki(x, Y) = K2(x, Y) = ( 0" X)(x - Y) This kernel is C°° because x has compact support. Also, the estimate (6.7) implies that

((1 + I42)S+,I [1-

IIcuIIH,+.(R")m = fR"

CJR'l(1+I I2>SF,I[1-x( )]I I-2 ()I2d C II u I I H- I (W,),,,

proving the desired mapping property.

In the general case when P is permitted to have non-constant coefficients, a parametrix g can be constructed using the symbol calculus from the theory of pseudodifferential operators; see Chazarain and Piriou [10, pp. 221-224]. The mapping property of Theorem 6.1 remains valid locally, i.e., given any fixed cutoff functions X1, X2 E Cm p(R"), X1 CJX2 :

H'-'(R")

HS+1(1[8")"`

for -oo < s < oo.

(6.10)

The next lemma will help us to describe the behaviour of the kernel G (x, y).

Lemma 6.2 Suppose that v E C°O (ll8" \ {0}) is homogeneous of degree -j for

some integer j > 1. If

u(x) = T4*'.'(f.p. v()}, then the distribution u is locally integrable on 1[8", and is CO° on 118" \ {0}. Moreover,

(i) if 1 < j < n - 1, then u is homogeneous of degree j - n; (ii) if j > n, then u(x) = u1(x) +u2(x)log1xI, where u 1 and u2 are homogeneous of degree j - n and C°O on R" \ {0}, with u2 a polynomial.

Parametrices

195

Proof Part (i) follows at once from Lemma 5.12 and Theorem 5.13, because v is locally integrable on R". If j > n, then by (5.18),

II±-x w)v(w) dw,

u(x) _ ICI=1

and part (ii) follows from Lemma 5.10.

0

We state the next theorem for the general case, but give a proof only for P having constant coefficients.

Theorem 6.3 Assume that P is strongly elliptic with C°° coefficients on R". There exists a parametrix 9 for P whose kernel admits an expansion of the form N

G(x,y)Gj(x,x-y)+RN(x,y),

(6.11)

j=U

for each N > 0, where the functions Go, GI, G2, ... and Ro, RI, R2, ... have the following properties:

(i) For each j > 0, the function G j is C°D on Il8" x (Rn \ (0)), and has the same parity as j in its second argument, i.e., G j (x, -z) = (-1)j G j (x, z). (ii) If 0 < j < n - 3, then G j (x, z) is homogeneous in z of degree 2 - n + j. (iii) If j > n - 2, then G j has the form G j(x, z) = Gj1(x, z) + G j2(x, z) log Izl, where G j I (x, z) and G j2(x, z) are homogeneous in z of degree 2 - n + j, with G j2(x, z) a polynomial in z.

(iv) If0 0. (v) If N + 1 > n - 2, then RN is C2-"+N on R", and

aaRN(x, y) = O(Ix - y12-n+(N+1)--IaI log Ix _ y;) as Ix - yI

0,forIal >2-n+(N+1).

Proof As mentioned above, we assume P has constant coefficients, and consider G given by (6.9). The choice of po ensures that there exists an expansion

Surface Potentials

196

of the form

P( )-1 =

for ICI > Po, j=o

with Vj E CO0(R" \ (0))"'11 rational and homogeneous of degree -2 - j. We define

Gj(z) _ and apply Lemma 6.2 to obtain (ii) and (iii). The expansion (6.11) serves

to define RN, and we see that G j (-z) = (-1)jG j (z) because Vj (-t) _ (-1)jV1(4) Write RN(x, y) = RN,1(x - y) + RN,2(x - y) + RN,3(x - y), where N+I

RN 1 = -X E f.p. V3,

00

RN.2 = f.p. VN+I,

RN,3 = (1-X) E V3.

j=0

j=N+2

We see that RN, I is C°O on R" because RN, I has compact support. Parts (ii) and (iii) imply that RN,2(X, Y) = RN,2(x - y) = GN+1 (x - y) satisfies conditions (iv)-(v). To deal with the remaining term RN,3 (X, Y) = RN,3(x - y), we use the bounds

ITx-, {(-127rz)fla"RN,3(z)}I = la

)I

C(1 +

if -2 - (N + 2) + I al < -n - 1, and thus 8" RN,3 is continuous on I[8" if la l < 3 - n + N.

Indeed, taking fi = 0, we see that .'{8"RN,3} E

Furthermore, by summing over I Ig I = r > 0, we see that I z I' 8" RN, 3 (z) is

bounded for z E IE8" if -2 - (N + 2) + lal - r = -n - 1, i.e., if -r = 2 - n + (N + 1) - Jul < 0, and thus laaRN,3(z)l < CIzl2-n+(N+l)-Ial if

lal>2-n+(N+1). Notice in particular that the parametrix G(x, y) in Theorem 6.3 is CO0 for x # y. We can use this fact, together with the mapping property (6.10), to extend the interior regularity result of Theorem 4.16. Theorem 6.4 Let 521 and 02 be open subsets of R", such that SZ I C= 02, and

assume that P is strongly elliptic with C°° coefficients. For s, t E R, if u E H' (522)"' and f E H-'(02)' satisfy

Pu = f on 522,

Fundamental Solutions

197

then u E HS+2 (cZ 1)' and IIuIIH=+'(sz1),,, < CIIa1IHI(n2)' + C11 f

Proof. Choose an open set 2 c 02 such that SZ1 C= 0 and SZ C Q2, and then choose a cutoff function X1 E C mp(SZ2) such that x1 = 1 on Q. We have

X1U - LC2(Xiu) = GP(xiu) = G(xif) +G[Pxiu - XIPul, and thus IIuIIH+2(&2,)1r' _ IIK2(Xiu) +G(Xif) +G[PXIU - X1Pu]IIH=+2(c1)m

Since K2 is a smoothing operator, II1C2(X1u)IIHs+2(Q,)"' < CIIuIIH,(n2)"', and

it follows from (6.10) that

II(XIGXI)f IIHs+2(n,)-n <

CIIfIIHs(S22)°; Finally, since Pxlu - x1Pu = 0 on S2, and since G(x, y) is C°O for x ¢ y, we have II G[Pxiu - x1Pu]IIHx+2(sn,)^ < CIIUIIH'(02)" 11

One interesting consequence of the above result is that the parametrix is unique modulo smoothing operators. Corollary 6.5 If G1 and g2 are parametrices for P, then !91 - 92 is a smoothing operator, and hence G1 - G2 is C°C on R" x ]R". In particular, it follows that the mapping properties (6.10), and the expansion in Theorem 6.3, are valid for every parametrix of P. Two further consequences are now obvious.

Lemma 6.6 If G is a parametrix for P, then g : D(R")"'

£(R11)"'.

Theorem 6.7 The operator G is a parametrix for P i f and only if G* is a parametrix for P*.

Fundamental Solutions A parametrix g (or its kernel G) is said to be a fundamental solution for P if (6.4) holds with 1C1 = 0 = LC2, i.e., if

PGu = u = GPu

for u E E*(R")'".

Surface Potentials

198

When P has constant coefficients, it is natural to seek a convolution kernel

G(x, y) = G(x - y) with G E S* (LR" )"""" . Indeed, taking Fourier transforms we see that such a G

is a fundamental solution if and only if

I, or equivalently,

PG = 8 on R".

(6.12)

When the polynomial P(i) is homogeneous, i.e., when P( ) = P0(e), then we can easily construct a fundamental solution as follows. Theorem 6.8 Assume that? has constant coefficients and no lower-order terms

(A1=OandA=0). (i) If n = 2, then the formula

f

G(z) ='P*->z{f.p.

[r'(1) - log2rrlw zI]P(w)-' dw

wl=

defines a fundamental solution for P. (ii) I fn > 3, then G (z) = P (l;)-' } defines a fundamental solution for P, and G is homogeneous of degree 2 - n. (iii) If n = 3, then G in (ii) has the integral representation G(z)

=

2z1

f l P(w1)-1 dwl,

where Sz = {w1 E S2 : wl z = 01 is the unit circle in the plane normal to z, and dwj is the element of arc length on Sz . Proof. We see from (6.6) that P (l;) is invertible for C°O and homogeneous of degree -2 for E R" \ {0}.

0. Thus, P (t;)-' is

Suppose n = 2. We know from Lemma 5.12 that f.p. P(l;)-' is a temperate distribution, so G(z) is well defined as the inverse Fourier transform of f.p. P(l;')-', and by Exercise 5.5, f.p.

I = .Fz,. (3(z)},

Fundamental Solutions

199

implying that G is a fundamental solution for P. Since P (-w) = P (w), we see from (5.18) that

G(z) =

12 f.1=1 [II±,(-w z) + II±1(w z)]P(co)-' dc),

II±I() = F'(1) -

sign(se),

2

giving the integral representation for G (z), and completing the proof of part (i). Part (ii) is clear from Theorem 5.13, because for n > 3 the function P ()-1 is locally integrable on R", and thus homogeneous of degree -2 as a distribution on lid".

To prove (iii), we note that by Exercise 5.12, if n = 3 then

G(z) = (IIa (-

()P( )-1)

z),

Moreover, since P(-i) =

for z E R3 \ {0}.

and since we can choose * so that

(- . z) + IIo ( z), ()P( Z(rI Observe that I1 (- z) = IIo (' z) and x+ + x° = 1, so fl + 11 G(z) =

.F{ I) = S, and therefore, if we define cp (') = 1/r () P (t) proof of Lemma 5.14, then, by Exercise 5.11,

G(z) =

_

z),()P()-1) =

Z(8( 1

21zl

t t=0

2(8, 0z) =

=

and Oz (t) as in the

2c6z(0)

P 1)-1 d l

( Y'

Introducing polar coordinates in the plane normal to z, i.e., putting l = pwl with p = and wl = l/p E Si'-, we find that

f

l Z=0

(l)P(Sl)-'d

1 = J J'1E

(Awl)P(Awl)

>O

Sl

(f o

which yields the desired formula for G(z).

Adpdwl

(Awl) dp) P(wl)-' dw1, A

Surface Potentials

200

Of course, in part (i) of Theorem 6.8 we can simply take (6.13)

zl)P(co)-1 dcv,

G(z) = Js (log IW1

because P = Po annihilates constants. We shall not prove any other general existence result for fundamental solutions, although Chapter 9 treats a particular example with A 0 0. Dieudonne [19,

pp. 253-256] discusses the history of existence proofs for fundamental solutions of general classes of partial differential operators. Gel' fand and Shilov [27, p. 122] give a reasonably simple proof for scalar elliptic operators of arbitrary order with constant coefficients, and Hormander [41, Theorem 7.3.10] considers arbitrary (not necessarily elliptic) partial differential operators with constant coefficients. Miranda [67, Theorem 19, VIII] treats second-order elliptic equations with variable coefficients.

The Third Green Identity Let us recall the notation used in our discussion of the transmission property (Theorem 4.20). The set S2- is a bounded Lipschitz domain in JE81, SZ+ is the complementary, unbounded Lipschitz domain, r = a S2+ = 8 S2-, and we have

the sesquilinear forms ct = Ogf, defined by n

n

n

cI(u, v) = f E E(A jkaku)*ajv + (A jaju)*v + (Au)*v dx; t j=1 k=1 j=1 cf. (4.2). The one-sided trace operators for SZ+ and S2- are denoted by y+ and y-, respectively, so that

y±u = (U±) I r

when u = U}1c2± for some Ut E D(1[8")"'

In the usual way, we extend y+ to a bounded linear operator

y} : Hs(c2±)m -*

Hs-1/2(r)m

for 2 < s < 2

The one-sided conormal derivatives of a function u E H2(S2±)m are defined by BV

n j=1

n

n

Vjy} EAjkaku

u

(k=1

and 13

vjy j=1

EA* k=1

with the usual generalisation via the first Green identity, as in Lemma 4.3. Remember also our convention that the unit normal v points out of S2- and into 52+.

The Third Green Identity

201

When u is defined on the whole of R, we sometimes write ut = uIn± for its restriction to Q±. To avoid redundant + and - signs, we write the onesided traces as y+u and y-u instead of y+u+ and y-u-, and similarly for the one-sided conormal derivatives. The jumps in these quantities are denoted by

[u)r=Y+u-y u, Au)r=Bvu-B-u, and we often indicate that a jump vanishes by dropping the + or - superscript; for instance, we write

yu = y+u = y-u if [u]r = 0. The first new symbols are y*, the adjoint of the two-sided trace operator, and B*, defined by

(Y*, 0) = (Vr, YO)r and

for 0 E E(R")m (6.14)

0)

By Theorem 3.38, y0 E HI-Emm for 0 < c < 2, so y*4r makes sense as a distribution on R" for any * E HE-' (F)'". Similarly, since 9.-0 E L.(1')"', makes sense as a distribution on R" for any * E Li (I')"'. we see that Obviously,

supp y*Vr c supp /r c r and

supp B* fr c supp * c r.

Using y* and B*, we can restate Lemma 4.19 as follows.

Lemma 6.9 Let f } E H-I (S2±)'" and put f = f+ + f - E

H_1 (1i$

n )n' and

suppose that u E L2(Rn)'" with u± E H1(SZt)"' If

Pu± = f } on Q±, then

Pu = f + B*[u]r -

on lR".

(6.15)

Now let C be a parametrix for P. Thus, there are smoothing operators 1C1 and 1C2 such that

P9u = u - ICiu and cPu = u - IC2u

for U E E*(Rn)"',

and of course ICI = 0 = IC2 if G is a fundamental solution. Motivated by Lemma 6.9, we define the single-layer potential SL and the double-layer

Surface Potentials

202

potential DL by

SL=Gy* and DL =GBv. Applying G to both sides of (6.15), the third Green identity follows immediately.

Theorem 6.10 If, in addition to the hypotheses of Lemma 6.9, the function u

has compact support in 1R" (and thus also f has compact support in R"), then

u = g f + DL[u]r -

K2u

on R".

The definitions above mean that

(SL V,, 0) = O1i, Yc*0)r and (DL i/r, 0)

1Z\ ifl BAG*0)r' for 0 E E( H

so by considering test functions with supp 0 C= R" \ F, and recalling from Theorem 6.3 and Corollary 6.5 that G(x, y) is C°° for x # y, one obtains the integral representations

SL*(x) =

f

G(x, y)i/i(y) dc,,

(6.16)

DL*r(x) = f [Bv.,G(x, y)*]*1/r(y) day,

(6.17)

for x E 1R" \ r. Notice also that

PSL Jr=y*Vr-ICI y*Vr and PDLKlon R, (6.18)

and hence

P SL Vr = -Ki y** and P DL

on SZ}.

(6.19)

In particular, if G is a fundamental solution, then P SL Vr = 0 = P DL Vr on 52±.

Jump Relations and Mapping Properties The surface potentials SLib and DL* are C°O on S2± because G(x, y) is C°° for x # y. We shall now investigate their behaviour at the boundary F. The results in the next two theorems, for general Lipschitz domains, are from the paper of Costabel [14].

Jump Relations and Mapping Properties

203

Theorem 6.11 Fix a cutoff function x E C o ,(R). The single-layer potential SL and the double-layer potential DL give rise to bounded linear operators

XSL: H-1/2(r )m

H1(l[$n)m,

X DL : Hl/2(r)m

HI(S2:)m,

ySL : H-t/2(r),n

H1/2(r)m,

yt DL : HI/2(r)m

HI/2(11)m,

H-1/2(r)",

B DL : H1/2(r)m

H-1/2(r),n,

B} SL : H-1/2(r)m

and satisfy the jump relations

[SL f]r = 0 and [B SL 1/rl r = -1/r

for* E H-1/2(r)m,

[DL Tf]r = Vr and [B DL *lr = 0

for* E HI/2(r)m.

and

Proof Choose a second cutoff function xt E D(W), satisfying Xt = 1 on a neighbourhood of 0- U r. For * E D(r)m and 0 E D(li8")'n, (xgxtY**,

(xSL 1/r, 4)) =

4)) = (*, Y(xiG*X)4))r,

and by Theorem 3.38 and (6.10),

y : HI (R n)m -* H1/2(r)m

and

X19*X : H-'(R)' -+

HI (Rn)nt,

(6.20) so IIY(xtg*x)4)IIH112(Rn)>-< <

CII4IIH-'(Rn)m. Hence,

I(XSLi/r, 4)I <- CIILrIIH-"2(r)

implying that

I I X SL *I I H I ta pn

II)IIH-'(W)"'

$ C I I r I I H-"i2 (r),,, .

This inequality proves the

mapping property for X SL. The mapping property for ySL and the first jump re-

lation [SL*]r = 0 follow at once because y : HI (Rf)m -+H1 /2(r)m; cf. Exercise 4.5. The mapping property for By SL is proved using the first Green identity. In fact, since P SL 1/r = -Kt y*ilr on 52-, we see by applying Lemma 4.3 that

IIB- SL IIH-itr< C11 SL1/rIIH(n-)` + CIlk] Y*1II If 95 E HI

then

OCIY*+lr, 4))a-I = I(*, YICI4))rl <_ CII'P

II4II

Hcn-n,,

Surface Potentials

204

CIIlfIIH-1/2(rp.,. Hence, using the mapping property of SL just proved, IIBy SLiIIH_112(V)"' < CIIiIIH-,r-(r),,,. Essentially the same argument, applied over SZ+, proves the mapping property for B+ SL. The only complication is that the cutoff function Xi is needed to ensure that X, SL * E H' (S2+)"; the details are left to the reader. SO II)Cly*

The jump [B SL *]r is found by applying the formula (6.15) to the function u = Xi SL 1/r. Indeed, since [u]r = 0 and B: u = B SL 1/', if S2' is an open neighbourhood of SZ- U r on which X, = 1, then

Pu = -1CJy*'tif - y*[B, SL'+/r]r on S2', whereas by (6.18),

Pu = y*c/r - JC, y** Thus,

on S2'.

[B, SL *1r) = 0, or in other words,

(ilr + [Bv SL if]r, y0)r = 0 for all O E D(R")m, and so * + [13 SL*]r = 0. All properties of the single-layer potential have now been established.

To handle the double-layer potential, we choose k > 0 large enough so that P +X is positive and bounded below on H, '(Q-)'. (Such a ), exists by Theorem 4.6.) Thus, the Dirichlet problem

(P +))u = 0

on S2-, (6.21)

y-u=g onr

has a unique solution u E H' (12_)m for each g E H112(I')m, and we can define the solution operator U : g i-+ u. Recall that this operator was discussed in the final section of Chapter 4. Let * E D(r)'" and define u e L2(R")"' by

u=

U* on S2-,

to

on 52+.

Since Pu = -1Au on Sgt, the third Green identity (Theorem 6.10) gives

u = -AGu + DL[u]r -

1C2u

and since y+u = BV +u = 0,

[u]r = -yU,/r = -z/r

and

[B,u]rr

on R",

Jump Relations and Mapping Properties

205

so

DL,/r=SLBVU r-u-AGu+K2u onR".

(6.22)

The mapping property of XSL and the mapping property (4.38) of B. U imply that IIxSLl5 U*IIH'(R")-' -<

IIH-"(r')n' <

and by (6.10), CIIU

IIx9uIIH2(R'"),,, = II (xcXI)uII

Thus, the mapping property (4.37) of U gives II X DL

II H (sz.+ )m < C II * II H ,n (r)""

The mapping property of y' DL follows at once from (6.20), and we obtain the mapping property of B DL by again using (6.22): IIB

DL,fIIH-,n(r),,, < JIB' SLB-UiI,IIH-'/2(r),,, + IIB:V'-uIIH

(r),,,

+x.IIBv GuII H--n(r),,, + IIBdK2uIIH--n(r)

< CHBu trill

H--r_(r),,, + CII(xlQxl)uIIHI(xu),A

+ IIu1IL2(R")m

-< CII*IIH"12(r)," +CII1!IIH'(sz-)< CIIiIIHii2(1-)m.

Finally, [Gu]r =

0 because Gu E H2(R), and

[SL By if *lr = 0 and

[13 SL 13V U*lr = -Bv U*,

so by (6.22),

[DL,/rlr = -[ulr = * and [13 DL *]r = -Bv U,/r -

r

_ -13v u = 0, proving the jump relations for DL.

O

Next, we show that the mapping properties of the surface potentials can be extended to a range of Sobolev spaces. Note, however, that the results below are not quite the best possible; see the discussion following the proof.

Theorem 6.12 Fix a cutoff function X E C mp (R'), and assume that -1 <

s<2,

Surface Potentials

206

(i) For the single-layer potential, we have XSL : Hs-1/2(r)m -+ Hs+l(Rrt)m, ySL : Hs-1/2(r)m --+ Hs+1/2(r)m

(ii) If P satisfies the hypotheses of Theorem 4.25, then the solution operator for the Dirichlet problem (6.21) satisfies U : Hs+1/2(r)m -+ Hs+I (Q-) M,

and for the single- and double-layer potentials we have BV SL :

Hs-I/2(r)nn

Hs-1/2(r)m,

XDL : Hs+1/2(r)m -+ Hs+l (Qf)M, Hs+1/2(r)m, y} DL : Hs+1/2(r)m

B DL : Hs+1/2(r)m

Hs-1/2(r)m

Proof We prove (i) by generalising the corresponding part in the proof of Theorem 6.11. Using, instead of (6.20),

y : H-s+l (R1)m _ H-s+ 1/2(r)'n X1JC*X :

H-s-I (Rf)m

and

H-5+1 (r')"',

(6.23)

we have IIY(XIGX)OIIH-+L/z(r)-, < CII0IIH-f-t(R,,), , and hence

I(XSLXi*,O)I = I(*1 Y(Xig*X)O)rl To prove (ii), let V : to (6.21):

CII

l

H v be the solution operator for the dual problem

(P* + A)v = 0

on Q-,

y-v=0 on1. By Theorem 4.25, B0U :

H3+1/2(r)m

-+ Hs-1/2(r)m and B0V : Hs+1/2(r)m _+ Hs-1/2(r)m, (6.24)

and also

U : L2(r)m -* L2(0-)m.

(6.25)

Jump Relations and Mapping Properties

207

We choose a number p large enough so that Ix I < p/2 for all x E S2-, and put

Q ={xES2+:IxI
up : H'/2(I')m -a H'

(0p)"'

defined by Up +g = u, where u is the unique solution of the Dirichlet problem

(P+A)u = 0 on Qp,

y+u=g onl', yp u = 0

on l'p,

and yp is the trace map from H' (Q +)R' onto H'/2(l'p)' . Now let g E D(I')"', and define w E L2 (W)"' by on S2-,

Llg

w= U,g onSZp, 0

on S2+ \ S2p+.

Define u on FP to be the inward unit normal to Q+, and let SLp denote the singlelayer potential on the (disconnected) surface 8S2p+ = F U T. Since [w]rur,, = 0 and

-.kw

on c2

,

Pw = -Aw on S2p , 0

on S2+\S2p,

the third Green identity (Theorem 6.10) implies that

w = c(-)Aw) - SLp[Bvw]rur,, + Kew on R". Using (6.25), we see that 119(-Aw) + K2W

CIIgwIIH2(n-)., +

CIIwIIL2(n-)

<- C II w L2(C2-UQ ), III +CIIU gIIL2(n+)"< CIIUOIIL2(0-)-

_< CI1811L2(ry <- CIIgI1Hf+-12(r)-

Surface Potentials

208

and by part (i) and (6.24), IISLp[13vw]rur,IlH=+-(n-)- < CII[Bvw]rur,11Hs-1i2(rur,)n'

< C11Bvug11H=-v2(r)" +C11Bvup

g1IH.,-!ntrp,1

+C11BvUp giIH=-112(r,) s7 C11911 H=+,n(r),,, .

Hence, IIldgIIH,+i(n-). = 11wIIH.,+-c92-gym < C IIgllH-+-n(F)

.

Next, consider the operator B. SL, and let *, ¢ E D(I')m. By the second Green identity (Theorem 4.4),

((P + )) SL *, Vc)n_

- (SL

(P* + A)VO)

_ (Y SL *,13-v V-0) r - (13v SL *, Y VO) r,

and since P SL i/r = -)C1y*i/r and (P* +.l)VO = 0 on S2-, and y-VO _ 0 on r', we see that (13- SL ti, O)r = (y SL,/r,13- Vcb)r + (r, YKi Vcb)r - X(SLi/r, VO)n-. Therefore, I(Bv SLR, o)rl < CIIY SLitIIH.,+w(r) ,s Ilav vOIIH-,--n(r)+ CII / II Hf-112trr,l II YKi V-PII H-=+W(r)-

+ CII SL i/rIIL2(n-)N, CII*IIHs-u2(r)(IIOIIH-,+1i2(t)'' +

and since C II O II H-s+112(r)Hi , the mapping property of 5- SL follows. We can handle 13+ SL in essentially the same way. The results for the double-layer potential now follow from (6.22). Indeed, C11XDL i11HI+I(Wk)"'

CIIxSL13v

4'(Q )" + CIIxullH:+1 (nf)N,

+C11x(KZU - XgU)11H2(R )C11Bv U*11H=-112(r)µ +C11U'IIH-+' (n-)-, + C11U11L2(W) CII

II Hs+"n(rr +

CIIu*IIH.,+1(n-)- < CIIillH.-u2(ryi,

and

II B: DL C1113

II

SLXivUSGIIHS-1/2(F) + 11B' uIIHs_t/2(r),

Jump Relations and Mapping Properties

209

+x1IBy9u11L,(r),,, +

CIlB,u*1IH-n(r),,, CIIfIIH.,+i,z(r),,, +

C11* IIHs+-n(r),,,

proving the mapping property for B DL = BI DL.

O

The proof of Theorem 6.12 breaks down if s = ±2. In particular, the trace operator no longer satisfies the mapping property in (6.23); cf. Theorem 3.38. Nevertheless, it turns out that all of the conclusions of Theorem 6.12 are valid for - 2 < s < Z , even when the principal part of P is not formally self-adjoint,

as required in Theorem 4.25. However, the proofs for the cases s = ±z are difficult, and rely on techniques from harmonic analysis. Of course, the estimates for s = f2, in combination with the interpolation property of the Sobolev spaces, yield a proof of the case - z < s < i independent of the one given above. A detailed discussion of harmonic analysis techniques for elliptic equations on nonsmooth domains is beyond the scope of this book. Nevertheless, in view of the importance of the mapping properties for s = ± , a few pointers to the i the survey by Jerison literature may be appropriate. Two useful early papers are and Kenig [43] on the Dirichlet and Neumann problems for the Laplacian on

a Lipschitz domain, and the study by Fabes, Jodeit and Riviere [21] of the classical method of surface potentials for the Laplacian on a C' domain. A key ingredient in [21] is the fact, proved by Calder6n [9], that if F is C' (or even Lipschitz but with a sufficiently small Lipschitz constant), then the Cauchy integral defines a bounded linear operator on L2(F). Subsequently, Coifman,

McIntosh and Meyer [11] extended Calderon's result to the case when r is Lipschitz (without restriction on the size of the Lipschitz constant), after which Verchota [102] was able to extend the results of [21] to Lipschitz domains. Later, other elliptic equations were treated, including the Stokes system [221 and the

equations of linear elasticity [17]; see also the survey paper of Kenig [47]. Mitrea, Mitrea and Taylor [68], [69] have only recently treated general strongly elliptic systems. Further historical and bibliographical details up to 1991 appear in a monograph by Kenig [47]. In most of these papers, not only the boundedness of the various boundary operators is of concern, but also their invertibility, a question we shall address in Chapter 7. Also, estimates of the surface potentials in Sobolev norms on the domain do not appear explicitly in most cases. Instead, bounds are proved for the nontangential maximal functions of the potentials and their derivatives, from which the Sobolev estimates follow; see Jerison and Kenig [43, pp. 62-63], [46, p. 145] and [44, Theorem 4.1].

Surface Potentials

210

When r is smooth locally, we can use the transmission property to show that the mapping properties in Theorem 6.12 hold also for s > 1. Recall Figure 3 of Chapter 4.

Theorem 6.13 Let G 1 and G2 be bounded open subsets o G 1 C= G2 and G 1 intersects r, and put

92: =G;nQ} and F =G1fl l

)I

such that

forj=1,2.

Suppose, for some integer r > 0, that 172 is Cr+1.1, and let

E H-r-2(r)"' and (i) If*Ir2 E

- 2 <s < r + 1.

HS-1/2(r2)"', then SLi/ E HS+1(cf)m and II SL `r II W+I (S2t)n-

C II 'Y II H'r-2(r)'n + C II 'Y II H'-1j2(r2)m .

(ii) If 1// Ir2 E HS+112(1'2)', then DL i/r E Hs+' (S2})"' and II DL

11 H.,+'(o

CII'Y

IIH-r-2(r).u + CII*IIH'+112(r2),,,.

Proof. Since the fundamental solution G(x, y) is C°O for x

y, we can as-

sume without loss of generality that supp ,/r C= ['3/2i where 1'3/2 = G3/2 n r and G1 C= G3/2 C G3/2 C= G2. For -Z < s < 2, we can repeat the proof of Theorem 6.12, noting that the mapping properties (6.24) now hold by Theorem 4.21, so no extra assumptions about P are necessary.

For s = r + 1, part (i) follows from Theorem 4.20 because the single-layer

potential u = SL * satisfies Pu = -K1 y*i/r on 01 with uIS2 E (SZZ [ulr = 0, [l3vulr, - -VIE Hr+1/2(1')"' and 1Cly*tfi E Hr(S2z )m. We then obtain (i) for the full range of values of s by interpolation, viewing SL as a linear operator from HS-1/2(1'3/2)n' into HS +' (S21)" Similarly, part (ii) follows because if s = r + 1 , then the double-layer po-

tential u = DL1fr satifies Pu = -1C1on S2:L with ui E Hr+3/2(['2)m, (Evulr = 0 and )C113'1/r E Hr(c )m. Mr,

E H'(S22 )m

Corollary 6.14 Fix a cutoifunction X E C mp(R"). If the whole of IF is

Cr+1.1

for some integer r > 0, and if -? < s < r + 1, then X SL : Hs-1/2(r)m

Hs+1(cf)m and X DL : Hs+1/2(r)m -+ H5+1(Qt)m.

Duality Relations

211

Duality Relations Recall from (4.30) that the first Green identity for S2} takes the form

(D±(u, v) = (Pu, v)n* + (BV 'u, Y}v)r, and from (4.31) that we have also the dual version

I}(u, v) = (u, P*v)nt + (Y}u,13v v)r.

(6.26)

Let f t E H-i (S2})"', V E L2(R")m and v} = vjc E HI (SZ})"', and suppose that

P* v} = f t on Sgt. Putting f = f + + f - E H-` (R")"', and arguing as in Lemma 4.19, we find that

([ulr,

(P*v, ) _ (f, ') +

for O E D(R")"',

or in other words,

P*v = f + 13*[v]r - Y*[8pvlr

on R",

(6.27)

which is the dual version of (6.15). Recall from Theorem 6.7 that G* is a parametrix for P*. Indeed, if ICI and 1C2 are as in (6.4), then

P*9*u = u -1C2u and 9*P*u = u -1Ciu.

(6.28)

Accordingly, we define SL and DL, the single- and double-layer potentials associated with P*, by SL = G*y*

and

DL = G*13*.

Assuming that v has compact support, we may apply g* to both sides of (6.27), and obtain another version of the third Green identity,

v = 9-f + DL[vlr -

1Ci v

on R";

(6.29)

cf. Theorem 6.10. The definitions of SL and DL mean that (SL

Yg0)r and (DL i/r, 0)

Bu

b)r

for q5 E

D(R")"',

Surface Potentials

212

and we see that for x E 1W' \ r, SL VI (X) =

jG(y,x)*lfr(y)dcry

(6.30)

and

DLVr(x) = f [Bv,yG(y, x)]*lIr(y) day;

(6.31)

cf. (6.16) and (6.17). Theorems 6.11-6.13 on the jump relations and mapping properties of SL and DL carry over in the obvious way to SL and DL, with 13, taking the place of B,,; thus,

for* E H-'/2(r)n,

[SL,*i]r = 0 and [Br, SL,f ]r and

[DL ik]r = * and

for* E HI/2(r)m

0

We remark that if P is formally self-adjoint, then 1(9 + G*) is a self-adjoint parametrix for P, which means that g can be chosen to satisfy g* _ g. Obviously, in this case SL = SL and DL = DL. The traces of the single-layer potentials SL and SL satisfy the following duality relation.

Theorem 6.15 If

E H-1/2(r')"1, then

(Y SL*, Or

Y §L

Or.

Proof. Fix a cutoff function X E D(R") with X = 1 on a neighbourhood of r. The operator XC*X : H-1(R")m -> H1(R")m is the adjoint of XcX : H-I(R")"' -+ H1(111;")m, so, noting that

y : H1(]Rn)m -4 H1/2(r)m

and

y* : H-I/2(r')"' -+ H-1(1[8")m,

we have

(y SL*, O)r = (XGXY*4,, Y*c) = (Y*

.

Xc*XY*,) = (9/r, Y SLO)r.

0 The next lemma will help us to relate the trace of the double-layer potential and the conormal derivative of the single-layer potential. The functions KI and K2 are the kernels of the smoothing operators 1C1 and K2 in (6.4).

Duality Relations Lemma 6.16 Suppose U E D(R")"', and put i/r = yu. If X E c2±, then

±DL i/r(x) = b ( G

)*, u) + fn K 2

=f

y)u(y) dy

[G(x, y)Pu(y) + K2(x, y)u(y)] dy

and

±DL* (x) =

u)+f

K,(y,x)*u(y)dy

j [G(y, x)*P*u(y) + Ki(y, x)*u(y)] dy

=

Proof. Taking u = Sx in (6.28), we see that P* G (x, )* = Sx - K2 (x, )* on R". Thus, for X E cZ±, the first Green identity gives

-(K2(x,

u)n ±

(x,

r=

VF(G(x,')*,

u)

= (G(x, )*, Pu),, ± (G(x, )*, We see from (6.16) and (6.17) that

(G(x, )*,13vu)r =

and

DL *(x),

proving the formulae for ± DL * (x). The formulae for ± DL * (x) follow in x) = Sx - KI (., x) on W. 0 the same way, because Theorem 6.17 Suppose U E H' (R")'", and put * = yu E Hh/2(1')"'. (i) For -0 E H-1/2(10"',

ytDLi/r)r =

u) + (Kzy**, u)n = f(l3 SLR, +/r)r

and

±(O, y} DL1r)r =

u) +

u)nc = ±(l3 SL 4r,

)r

(ii) For 0 E H1/2 (ryn' ±(-0, By DL*) r = (P =F (D L 0, u) + (1C2Bv0,

u)c _ ±(Bv DL 0, r)r

and

Ci

u) +

u)si$ _ +(B DL¢, )r

Surface Potentials

214

Proof Theorem 6.3 implies that ayk G(x, y) is locally integrable on R" for 1 < k < n. Hence, the function x H c1 (G (x, )*, u) is continuous on R", and we can show that ¢*(x)(D:F (G (x, )*, u) dcx

=

(SLq5, u).

Jr

For instance, the first of the three terms arising from the definition of '-F is

f

r

O(x)* f (AJk(y)aykG(x, y)*)*a,u(y)dyd6x

=

f

7T

ayk

(fr G(x, y)*O(x) ddx)*A;k(y)8;u(y) dy

(AJkak SLO)*aJu dy. QT-

Thus, by Lemma 6.16,

u) +

Y}DL )r =

fr

O(x)*

f

K2 (x, y)u(y)dydrx

rt$

u) + zf (fr

K2(x,

y)

(x) dax)*u(y) dy

_ (D'(SL0, u) + (1C2* Yu) and the first Green identity (6.26) gives I

yFu)r -(K*Y*4, u)nr ± (I3 SLR, )r,

(SL 0, u) _ (P* SL 0, u) ± (Bv SL

proving the first half of part (i); the second half holds by a similar argument.

To prove part (ii), we use the second formula for DL f in Lemma 6.16, followed by part (i) and the first Green identity. Indeed,

-±(O, B± DL Or = ±(O, By

fr

O(x)*B..X

f

{

[G(x, y)7'u(y)

+K2(x, y)u(y)] dydo,

_ ±(Y DL

(DLO, Pu)nT +

u)

u) + (K2B*0, u)cc, and since P* DLO = -K2B*o on Q:F, another application of the first Green

Exercises

215

identity gives

(DI(DL0, u) + (1C*B*O, u)s = ±(13v DL 0, 1G')r The second half of part (ii) is proved in the same way.

Exercises 6.1 With the notation of Theorem 6.3, show that if P* = P, then G1 = 0. 6.2 By thinking of G (y, x)* as a parametrix for P*, we can apply Theorem 6.3 to obtain an expansion N

G(y, x)* = E G;(x, x - y) + RN(x, y), i=o

where the Gj have the obvious properties. Show that Go (x, z) = Go (x, -z)*.

6.3

Here is another way of deriving the jump relations for the single- and double-layer potentials, assuming that the basic mapping properties of Theorem 6.11 are known.

(i) Show that if * E H-1/2(I')"' and u = SL *, then

([ulr, By ')r = ([Bvul r + i/r, Y0)r

for 4b E D(R")

[Hint: use Lemma 6.9 in combination with (6.18) and (6.19).]

(ii) Show that if 1/r E H1/2(r)"' and u = DL i/r, then

([ulr

- ", B4)r = ([Bvulr, Y')r

for O E D(W)"(iii)

Assume that S2- is C2. Show that if f c- H1/2(F)"' andg E H-1/2(F)"' satisfy

(f, By ')r = (g, YO)r for 0 E D(R")"`, then f = 0 and g = 0. (Hint: Since D(][8")"' is dense in H 2 (W)"', we can use a C2 coordinate transformation to reduce to the case 0:1- _

Rt. For r7l as in Lemma 3.36, if 0 E D(R"-1)"' and 0 = rill/r, then y¢ = 0 and 9,0 = Costabel [14, Lemma 3.5] gives a proof for Lipschitz domains.] 6.4 Fix a cutoff function X E C mp(1R"), and show that

X DL : Ha-1/2(F)' -* Hs(]R')"' [Hint: adapt the proof of Theorem 6.12 (i).]

for-! < s < 2.

216

Surface Potentials

6.5 Let the hypotheses of Theorem 6.13 be satisfied, and suppose that f I E

H- (S2±)"' with f+ having compact support. As in Lemma 6.9, we put f = f + + f - E H-' (R")"', and note that 9f E H101c (R")"' by (6.10), and [9f ]r = 0 by Exercise 4.5. (i) Show that f ]r = 0 if f E L2(IR") (ii) Prove regularity of the volume potential up to the boundary: if f 11 st2 E HT (S22 )'", then 9f" E Hr+2(E2 :)"' and

II9fIIIHr+2(n')m < ClIfIII+ GIIfIIH,«z,,,,. [Hint: use Theorem 4.20.]

Boundary Integral Equations

Using the properties of the surface potentials established in Chapter 6, we can reformulate boundary value problems over the domain n- or S2+ as integral equations over the boundary F. To describe these reformulations, we begin by defining four boundary operators (three if P is formally self-adjoint) in terms of traces and conormal derivatives of surface potentials, and by showing how to write them as integral operators, in some cases with non-integrable kernels. Next, the pure Dirichlet and Neumann problems for the interior domain Stare shown to be equivalent to boundary integral equations of the first kind, for which the Fredholm alternative is valid. The case of mixed boundary conditions is more complicated, because one obtains a 2 x 2 system of integral equations. We establish the Fredholm alternative for this system only when P is formally self-adjoint. The next section treats exterior problems, i.e., boundary value problems for the unbounded domain Q+. In such cases, a suitable radiation condition must be specified, to force appropriate behaviour of the solution at infinity. Finally, we study regularity of the solution to the integral equation when the surface and the data are suitably smooth (at least locally).

Throughout this chapter, G is always a fundamental solution (not just a parametrix) for P, and we implicitly assume whenever P is formally selfadjoint that G(y, x)* = G(x, y).

Operators on the Boundary Recall from (6.16) and (6.17) that the single- and double-layer potentials associated with P are given by

SL*(x) = DL *(x)

Jrr

(x, y) f(y) da,,,

= f[&).G(x, y)*]*fr(y) do, 217

Boundary Integral Equations

218

and recall from (6.30) and (6.31) that the ones associated with P* are given by SL 1/r (x) = DL 1/r (x)

=

jG(y,x)*1fr(y)day, (7.2)

f[13L,yG(y,x)]*1/i(y)day,

for x E W \ r. We will see that all traces and conormal derivatives of these potentials can be expressed in terms of four boundary operators, namely

R = -B, DL : H1/2(r )m - H-1/2(r)m S = ySL : H-1/2(r)m -* H1/2(r)m, H1/2(r)m, T = y+DL +Y-DL: H1/2(r)m T = y+ DL + y- DL : H112(r)m - H 1/2(r)'".

(7.3)

These mapping properties were proved in Theorem 6.11. (The reader may now

wish to turn to the first section of Chapthr 8 and look at the explicit forms for R, S and T in the simplest and most familiar case, i.e., when P = -A.) The duality relations in Theorems 6.15 and 6.17 show that the adjoints of the operators in (7.3) are given by DL : H1/2(r)m

R*

-.. H-1 /2(r)m,

S* = ySL : H-112(r)m -+ H1/2(r)m, (7.4)

T* = B+ SL +BV SL : H-1/2(F)m

H112(r)m,

T* = BV SL +B SL:

H-112(r)n.

H-112(I-)m

From the definitions above, and the jump relations in Theorem 6.11, we obtain the following expressions for the traces and conormal derivatives of the single- and double-layer potentials:

ySL* = S1/r,

ySL1/r = S*1/r,

SL 1r = 1(+1/r+T

B: SL 1/r = 1(+1/r+T*1/i),

(7.5)

y} DL 1/r =

(f1* r + T1/r),

y± DL 1(r = '-2 (f1/r + T>/r),

Z

B DL 1/r = -R1i,

B DL 1/r = -R*1/r.

If the partial differential operator P is formally self-adjoint, then

SL = SL,

DL = DL,

B, = B,,,

T = T,

S* = S,

R* = R,

Integral Representations

219

and so the eight relations in (7.5) reduce to four:

Y-1 DL ,/r = 1(f,' + T*),

ySL i/r = Si/r.

13, DL 1/r = -R*.

13:' SL l/r = Z (::F* + T**),

Theorem 6.12 implies at once that the mapping properties in (7.3) and (7.4)

extend to a range of Sobolev spaces as stated in the theorem below. Note, however,'our discussion of the end-point cases s = ±1 following the proof of Theorem 6.12.

Theorem 7.1 For -1 < s < Z, S:

Hs-1/2(r)en - Hs+1/2(r)m

and

S* :

Hs-1/2(r)m

-+ H$+1/2(r)m , (7.6)

and if P satisfies the assumptions of Theorem 4.25, then

R Hs+1/2(r)m

Hs-1/2(r)m,

T Hs+1/2(r)m

Hs+1/2(r)m,

R* : Hs+1/2(r)m -+ Hs-1/2(r)m, T* Hs-1/2(r)rn -* Hs-1/2(r)n', (7.7)

T : Hs+1/2(r)m

Hs+1/2(r)m,

T* : Hs-112 (nn,

Hs- 1/2(r)ln.

For smooth domains, a larger range of values of s is allowed; cf. Exercise 7.8. Cr+1.1 for Theorem 7.2 If r is same integer r > 0, then the mapping properties in (7.6) and (7.7) hold for -r - 1 < s < r + 1.

Proof The mapping properties for 0 < s < r + 1 follow from Theorems 6.13 and 3.37. We then get the estimates for -r - 1 < s < 0 by duality.

Integral Representations We shall now derive integral representations for each of the eight boundary operators in (7.3) and (7.4).

For p > 0 and x E R", let B,, (x) denote the open ball with centre x and radius p. If n > 3, then, by Theorem 6.3, the leading term Go in the homogeneous expansion of G has degree 2 - n. If n = 2, then Go contains a logarithm. Consequently,

IG(z, y) I dvy < rnB, (X)

CE

for Z E IR" and n > 3,

CE (1 + I log E I)

fort E B, (x) and n = 2,

Boundary Integral Equations

220

and it is easy to see that if, say, * E L,, (r)n`, then

Sr(x) = J G(x, y)if(y) day and S*Vr(x) =

J

G(y, x)*l/r(y) da,, (7.8)

for x E F. Hence, S and S* are integral operators on F with weakly singular kernels. To handle the other six boundary operators, we define

,,*(x) = 2 fr T, **(x) =

\B,(x)

[ B&.yG(x, Y)*]*f(Y) day,

2f \B,(x) B,.xG(Y,x)*y+(Y)day,

TE(x) = 2 /

r\B,(x)

[Bv,yG(Y, x)]**(Y) day,

TEr(x) = 2 J

Bv.., G(x, Y)l(Y) day,

r\Be (x)

REik (x) = - f

R:f(x) = - f

\B,(x)

Bv,x[Bu,yG(x, Y)*]**(Y) day,

Bv,x[Bv,yG(Y,x)]* (Y)day; \B, (x)

cf. the integral formulae for the single- and double-layer potentials given in (7.1) and (7.2). Recalling the definition of By from (4.3) and (4.4), and the definition of By from (4.5), we see that the kernels of the last six integral operators above are given explicitly as follows:

2[B,,,G(x, y)*]* = 2[an+kG(x, Y)Akj(Y) + G(x, y)Aj(Y)]vj(y), 2Bv,xG(y, x)* = 2[an+kG(Y, x)Akj (x) + G(y, x)Aj (x)]*v j (x),

2[Bv,yG(y, x)]* = 2vj (Y)[Ajk(Y)akG(Y, x)]*,

2Bv,xG(x, y) = 2vj(x)Ajk(x)8kG(x, y), (7.9)

-Bv,x[Bv,yG(x, y)*]* _ -vj(x)[Ajk(x)akan+nnG(x, y)Anr1(Y)]u1(Y) - vj (x)[Ajk(x)akG(x, y) Al (y)] vi (y), -Bv.x[Bv,yG(y, x)]* =

x)A,,,1(x)]*vl(x)

- vj(Y)[Ajk(Y)akG(Y,

x)Al(x)]*vl(x).

Here, we have used the summation convention, and note that an+kG(x, y) = a),,. G(x, y).

Integral Representations

221

In general, the six kernels in (7.9) are all strongly singular on the (n - 1)dimensional surface F, because the leading term in the homogeneous expansion

of VG is of degree 2 - n - Ia I. To investigate what happens as e .0, suppose that SZ- is given locally

by x < (x'), and define the directional derivative (x,

d (x', h') = lim

+ t h') - (x')

tlo

t

For X E F, i.e., for x _ (x'), we shall say that r is uniformly directionally differentiable at x if

(x' + h') _ (x') +

h') +o(Ih'I)

as Ih'I - 0.

(7.10)

h') is homogeneous of degree 1, but not necessarily linear, Note that in h'. In order to state our next theorem, we define two subsets of the unit sphere §n-1 c lf8n

T+(x) = {ro E S"-' : w >

' co))

T -(x) = [co E S"-' : w <

d )j.

In the simplest case, when is differentiable at x', we have grad (x'), and so by (3.28),

T±(x)={wES"-1:±v.v(x)>01.

h') = h' (7.11)

Theorem 7.3 Letx E F, suppose that r is uniformly directionally differentiable at x, and define

af(x) = f a}(x) =

f

an+kGo(x, w)AkJ(x)wJ du , a(x)

8,,+kGo(x, -w)*A jk(x)wj dw,

TT- (.x)

where Go(x, x - y) is the leading term in the homogeneous expansion of G(x, y). For* E D(IP)', y" DL * (x) = ±a t (x) i/i (x) + E0 2 TE r (x),

y} 5L *(X) = fa}(x)1(x) + E O 2T

(x),

Boundary Integral Equations

222

and so

Ti/r(x) = [a+(x) - a-(x)l ii(x) +

Elm

TEf(x),

T*(x) = [a+(x) - a-(x)l W (X) + li TE'(x) o Proof Suppose 11r = yu where u E

y+DL*(x) =

f

We know from Lemma 6.16 that r\B.(x)(G(x, .)*3 u),

and since P*G(x, )* = 0 on UT \ BE (x), the first Green identity gives 1012R\B,(x)(G(x, ), u) = 1TE1/f(x) + f

day, 2

naBE(x)

where v is the outward unit normal to S2- \ BE (x) and the inward unit normal

toSZ+\BE(x).Suppose y E c flaBE(x)andputy = x + Ew, where co E Sn-1 Observe that v(y) _ +W, so by (7.9) andTheorem 6.3, [8v,yG(x, y)*]* _ [an+kG(x, x + EW)Akj(X + E(0)

+ G(x, x +EW)Aj(x + EW)](+Wj) +an+kGO(x, -EW)Akj (X)&)j +

O(1

+ I)logEI) ifn=2,

10(6 Z-" )

if n > 3.

Now put

T,±(X) = (W E S" :X+EWES2}}, so that, noting an+kGO(x, -z) = -an+kGO(X, z),

fna

[Bv,yG(x, y)*]*u(y) day B, (x)

=+

f

Taxan+kGO(X, EW)Akj(x)WjU(X + Eco)e'

+O(E(1+IlogEI))

1 O(E)

ifn =2, ifn > 3.

' dW (7.12)

Since an+k Go (x, z) is homogeneous in z of degree 1-n, and since (7.10) implies that

ma ([ }(x) \ l E (x)l U[ 1 E (x) \ T (x)l J= 0, A

E

Integral Representations

223

we see that

lim]

[13,,,yG(x, y)*]*u(y)day =+a+(x)Vr(x),

40 S2T-naBEcx)

giving the formula for y t DL * (x). The expression for T * (x) then follows immediately from the definition of Tin (7.3). The formulae for y± DL *(X) and T >/r (x) follow by a similar argument, with the help of Exercise 6.2.

When I' is sufficiently smooth, the preceding results for T and T simplify, and we can deal with the other four boundary operators; cf. Theorem 5.23. Theorem 7.4 Let X E I' and Mfr E D(P)"'.

(i) If I' has a tangent plane at x, then

and T*(x) = limTEl/r(x).

Tif(x) = lim TE* (x) CIO

CIO

(ii) If r is C1,'` (with 0 < µ < 1) on a neighbourhood of x, then T*l/r(x) = 1imTE Vr(x)

and

T**(x) = 1imTEi/r(x).

E40

CIO

(iii) If r is C2 on a neighbourhood of x, then Ri/r(x) = f.p. RE1/r(x)

and

R*1/r(x) = f.p. RE*(x). CIO

w), and since TI(x) is given Proof. Since a"+kGo(x, -cv) = by (7.11), we see that a-(x) = a+ (x) and so TEi/r(x) -* T i/r(x). In the same way, a+(x) = ii-(x), so T,1/r(x) -+ Ti/r(x). Part (ii) follows from part (i) because, cf. (7.12), the combination

B,,,xG(y, x)* + 13,,,yG(x, y)* = [vi (x)Akj(x)* - vj (y)Aki

(y)*]

x a"+kGo(x, x - y)*

+

=

J 0(1+lloglx-yil) ifn=2, 1 O(Ix - y12-")

O(Ix

-

if n > 3,

you+1-n)

is only a weakly singular kernel on F, and [13,,,yG(x, y)*]* is the kernel of T.

224

Boundary Integral Equations

We now deal with the hypersingular operators. By Lemma 6.16,

R,f (x) = -BL DL * (x) = -B' SLBvu(x)

Em([X3v,.,G(x, )]*, Pu),f ,

where S2E = Sgt \ BE (x). Since P* [Bv x G (x, )]* = 0 on S2E , the second Green identity (Theorem 4.4) gives

+([13v,xG(x, .)]*, Pu)n

= -(Bv[Bv,xG(x, )]*, Yu)a,E *

+ ([B.,,xG(x, .)]

Bvu)a52, .

From (7.9), we see that ')]*,

-(Bv[Bv,xG(x,

yu)anz = RE1f(x)

± SEtnaBf(x)

Bv,x [Bv,yG(x,

Y)*]*u(Y)

day

and

([Bv.xG(x, )]*,Bvu)asa{

-

B,,,xG(x,Y)Bvu(Y)dory, (x)

where v(y) is the outward unit normal to BE(x). Thus,

Rilr(x) =

2

[::FBvu(x) + T*Bvu(x)] + im(REf(x) + CIO

fJ

2T

*Bvu(x)

{Bv,x [Bv.yG(x, Y)*]*u(Y) B, (x)

- A xG(x, y)Bvu(Y)} derv I, and by arguing as in the proof of Theorem 7.3 and noting that co), we find that

(7.13)

Go (x, -(0) _

B,,,xG(x, y)B,u(Y) dcy S2 naBE(x)

f

vj(x)Ajk(x)8kG(x, x + Ew)wl8lu(x + Ew)En-1 dw. (x)

Differentiating the expansion in Theorem 6.3 with respect to x, one obtains

as the leading term

x - y), and since

z) is odd and

Integral Representations

225

homogeneous of degree 1 - n as a function of z, we have Bv,xG(x, y)13vu(y) day, S2+naBf(x)

=

I

-2 1

Vj (x)Ajk(X)a.+kGo(X, w)a,u(x)wl do) + 0(E).

wI-1

Hence, taking the average of the + and - expressions for Ri/r(x) in (7.13), we are left with R,/i(x) = lim RE*(x) +

1

L-naBEx )

13V,x[ VyG(x, y)`]*it(y) day *

1

2 L+fl8B2 (x)

Bv,x[9v.YG(X,y)*]u(y)da,,

1

In view of Theorem 6.3 and (7.9), if we let u,,,l(y) = A,,,,(y)u(y) and ul(y) _ A,(y)u(y), then -,Bv,x[Bv.YG(x,

y)*]*u(y)

= vj(x)Ajk(x)[an+kan+,nGO(x, x - y)un:l(x) + akan+1GO(x, x - y)umt(X) + an+kan+mG1 (x, x - y)unsl (X)

an+ka,,+mGo(x, x - y)8pum!(X)(yp - xp)

- an+kGO(X, x - y)u!(x)]vl(y)

+ 0(jx - y12-',). For the leading term, we apply Exercise 7.2 with f (w) = Aml(x)wl to obtain

f

i naBf(x)

=E

Go (x, -w)

an+kan+mGo(x, x - y)v!(y) day

fT-(x)

8n+kam+kG0 (x, w)wl do) + 0(e).

Each of the remaining strongly singular terms in the integrand has the form

f (x, x - y), where f (x, z) is even and homogeneous of degree 1 - n as a function of z. Since

lim J e10

S2{naBE(.r)

f (x, x - y) day: =

JT'(x)

f (x, co) dw,

the contributions from T+(x) and T- (x) cancel, and part (iii) follows.

Boundary Integral Equations

226

The Dirichlet Problem We now show how the single- and double-layer potentials allow a pure Dirichlet problem to be reformulated as a boundary integral equation of the first kind with a weakly singular kernel.

Theorem 7.5 Let f E H-1(S2-)m and g E H1/2(f')"'. (i) If U E H '(Q-)' is a solution of the interior Dirichlet problem

Pu = f y-u = g

on St-,

(7.14)

on 1',

then the conormal derivative * = BV _U E H-1/2(F)m is a solution of the boundary integral equation

(g + Tg) - y9 f on r,

Sl/r =

(7.15)

2

and u has the integral representation

u=Gf -DLg+SLi/r on Q-.

(7.16)

(ii) Conversely, if ilr E H-112(1F)m is a solution of the boundary integral equation (7.15), then the formula (7.16) defines a solution u E Hi (l-)"' of the interior Dirichlet problem (7.14).

Proof As in Theorem 6.10, we view f as a distribution in H-'(R)' with supp f C 52--; cf. Theorem 3.29 (ii). Suppose that u E H1(Q-) satisfies (7.14), and define u = 0 on the exterior domain Q+. Applying Theorem 6.10, we obtain the representation formula,

u=Gf -DLy-u +SLB.u on Q-,

(7.17)

and then by (7.5),

y-u = y9 f - (-y-u + Ty-u) + SB- u i

on F.

Part (i) now follows from the boundary condition y-u = g. To prove (ii), suppose that i/i E H-112(I')m satisfies (7.15), and define u by (7.16). The mapping property (6.10) of the volume potential, together with those of the surface potentials given in Theorem 6.11, imply that G f , DL g and

SL i/r all belong to H1(Q-), so u E H1(SZ-)m. By (6.2), we have PG f = f on lR", and by (6.19), we have P DL g = P SL 0 on SZ-, so Pu = f on Q-. Finally, y-u = g by (7.5). The next theorem shows that the boundary integral equation (7.15) satisfies

the Fredholm alternative; cf. Theorem 2.33. The method of proof was first

The Dirichlet Problem

227

used by Nedelec and Planchard [76], [74], Le Roux [56], [57], and Hsiao and

Wendland [42], for the case when P is the Laplacian. These authors were all concerned with error estimates for Galerkin boundary element methods, in which context positivity up to a compact perturbation is of fundamental importance for establishing stability.

Theorem 7.6 The boundary operator S = y SL admits a decomposition

S=So+L, in which So : H-1/2 (r)m - H1/2(r')m is positive and bounded below, i.e.,

Re(So*, Or ? CII IIH-1n(r)for* E H-1/2(r)m, and in which L : H-1/2 (r')m -+ H 1/2 (r)m is a compact linear operator. Hence,

S : H-1/2(r)m -) H1/2(r')m is a Fredholm operator with index zero.

Proof. Put u = X SL i/r and v = X SL 4), where 0 E H-1/2(r)" and X E C mp(R") is a cutoff function satisfying X= 1 on a neighbourhood of S2-. Since Si/r = yu and 4 _ -[Bp,v]r, and since Pv = 0 on Q-, the first Green identity implies that

(SQL, fi)r = (yu, By v - By v)r = 'Do- (u, v) + Dn+(u, v) + (L1', 4))r, where

(L1l, 4))r = -(u, Pv)o+.

(7.18)

We have [u]r = 0 so u E H 1(R")m, and hence the strong ellipticity of P implies that Re (Do- (u, u) + Re (Dsy+ (u, u) = Re OR,. (u, u) ? C II U II h l (R,,),,, + (L2i, Or,

(7.19)

where

(L2l,10)r = -C(u, v)R,,. Furthermore, II

IIH-,ncr)y = IIBV u - By uIIH-"n(r)'" < CIIuIIHI(R),-,

(7.20)

Boundary Integral Equations

228

so if L = L 1 + L2 and So = S - L, then So is positive and bounded below, as required. By Theorem 3.27, to show that L : H-1/2(r')"' -+ H112(r')'" is compact, it suffices to show that L:

HE-1(r')"'

is bounded for 0 < E < 1. In fact,

-* H1-E (F)"'

1 has the form

L

L1ifr(x) = f K1(x, y)*(y)dory, r where K1 is C°° on a neighbourhood of r x F, because G(x, y) is C°O forx # y, and Pv has compact support in SZ+. To deal with L2, we apply the CauchySchwarz inequality and obtain I(L2f,' )rl < CIIuIILZ(R"")"IIVIILZ(R")"'

By the mapping property of the single-layer potential in Theorem 6.12, Ilu1ILZ(R")nr < CllullH'+112(Rn)", < CIIfIIH'-I(r)", so

I(L2i,')rl <- CII1IIHI-1(ry"

0

and hence IIL21IIH1-'(r)'" < C11*11HE-1(r)"'

Applying the Fredholm alternative to the boundary integral equation (7.15), we see that a solution exists if and only if

(i(g + Tg) - Y9 f, Or = 0

(7.21)

for every solution 0 E H-1/2(F)of the homogeneous adjoint equation S*q =0. Every such 0 has the form 0 = 9,v where v E HI (Q-)' satisfies

P*v=0 on Q-,

y-v=0 onF, and since (g + Tg) = g + y- DL g, the condition (7.21) is equivalent to 2

(g, B,,v)r = (y [Gf - DLg],gv v)r = O (G f - DLg, v)

by (6.26), since P*v = 0,

= (P[c f - DLg), v)Q_

since y-v = 0,

= (f, On-,

The Neumann Problem

229

which is the same as the condition obtained in Theorem 4.10 for solvability of the (pure) Dirichlet problem.

The Neumann Problem The pure Neumann problem can also be reformulated as a boundary integral equation of the first kind, but this time the kernel is hypersingular.

Theorem 7.7 Let f E H-1 ($Z-)"' and g E H-1 /2(F)'". (i) If U E H 1(Q-)'" is a solution of the interior Neumann problem

Pu = f on Q-,

(7.22)

B.u =g on r,

then the trace i/r = y-u E H 1/2 (F)"' is a solution of the boundary integral equation R,/r

2(g-T*g)-B-9f on l',

(7.23)

and u has the integral representation

u = G f - DL i/r +- SL g

on St-.

(7.24)

(ii) Conversely, if* E H1/2(F)' is a solution of the boundary integral equation (7.23), then the formula (7.24) defines a solution u E HI (Q-)"' of the interior Neumann problem (7.22). Proof. Essentially, one repeats the proof of Theorem 7.5, interchanging g and*, and taking the conormal derivative of the Green representation formula (7.17), instead of its trace. In fact, by (7.5),

B-u =B-9f +Ry-u+2(B-u+T*B-u) on F, 0

giving (7.23).

Next we show that the Fredholm alternative is valid for the boundary integral equation (7.23). As in the proof of Theorem 6.12, we use the notation SZP = {x E Q+ : lxi < p} = n+ n BP,

(7.25)

where the number p is large enough so that IxI < p/2 for all x E 0-. The argument below follows a similar pattern to the one for the Dirichlet problem (Theorem 7.6).

Boundary Integral Equations

230

Theorem 7.8 If P is coercive on H 1(S2-)' and on H' (Q+)"', then the boundary

operator R = -B DL is coercive on H1/2(I')"', i.e., for 1/1 E H1/2(r)m.

Re(R*, O r ? cII*IIHI/2(r)Hence,

R : H1/2(r)'" --* H-1/2(r)m

is a Fredholm operator with index zero.

Proof Let * and 0 belong to H 1/2 (r)' and put u = X DL Vr and v = X DLO, where X E C o ,P(R") is a cutoff function satisfying X= I on a neighbourhood of S2-, with supp X Cc B,,. Since R1/r = and 4) _ [yv]r, and since Pu = 0 on n-, the first Green identity implies that

(Ri,r, 4))r = (-Bu, y+v - Y_Or = (Du-(u, v) + c0P (u, v) + (L,*, 4)r, where (L1*, 0) r =

-(Pu,

By hypothesis,

Re On-(u, u) + Re Z +(u, u) ? c(IIu1IHI(Q-),,, +

(L2'cr, Or,

where (L2*, Or = -C[(u, v)Q- + (u, v)QP ], and we have II

IIY+u - Y-uIIH112(r)< C(IIuIIHl(n-),,, + IIuIIH(9 ),,,).

Hence, if we put L = L, + L2 and Ro = R - L, then R = Ro + L and Re(Ro'1G', Or ? cII IrII

for ir E H1/2(1')"'.

To complete the proof, we will show that

L : H-1/2(r )m --* H1/2(r)m C11

H-l /2 (r),n < C II * II L2 (r),,, In fact, since 1G II L, is an integral operator on F whose kernel is C°° on a neighbourhood of r x r, it suffices to consider L2. By the Cauchy-Schwarz inequality,

is bounded, and so I (L iG', fir') r I S

I (L2'cr, fi)rI <

C(IIuttL2(Q-)H,IIvIIL,(sz-)'N + IIuIIL2(c1P)m IIVIIL2(oP)-n),

and by the mapping property of the double-layer potential in Exercise 6.4, II L2(Q+)m < CII *11 H--n(r)m,

Mixed Boundary Conditions

231

so

I(L2J, Orl < CIIiIIH-I12(r)m1IOIIH-w(rr,, and hence lIL2*IIHI/2(r)", < CII

Mixed Boundary Conditions Elliptic problems with mixed Dirichlet and Neumann boundary conditions can be reformulated as 2 x 2 sytems of boundary integral equations. As in Chapter 4, let

r=rDunurN be a Lipschitz dissection of the boundary. We write

when supp 1 c rD U n,

SDDI _ (S!)Iro and TN*D'k and

RNN* _ (Rf)IrN and TDNr _ (T')Iro

when supp'k

rN U II.

It follows from (7.3) that, at least for s = 0, SDD :

Hs-1/2(rD)m

Hs+112(rD)m,

RNN : Hs+1/2(FN)m

Hs-1/2(FN)"

,

TND

:

Hs-1/2(rD)n1

Hs-1/2(rN),n,

TDN Hs+1/2(rN)m -+ Hs+1/2(rD)m;

cf. Theorems 7.1 and 7.2.

Theorem 7.9 Let f E H-1(0-)'n, gD E H1/2 (I'D)' and gN E H-1/2(1 N)", and consider the mixed boundary value problem

Pu= f

on Q-'

Y _U = gD

on rD, on rN.

BV -U = gN

(7.26)

Extend the Dirichlet and Neumann data to the whole of r, in such a way that gD E H1/2(r)' and gN E H-112 (l'), and define hD E H 1/2 WD)... and hN E H-1/2(FN)m by

on rD, hD = (gD + TgD) - SgN - Y9f 2 hN = Z(gN-T*9N)-RgD-,Q;9f onrN.

Boundary Integral Equations

232

(i) If U E H' (S2-)"' is a solution of (7.26), then the differences Y/D =By U - gN E H-1/2(rD)m

y'N = y U - gD E H1/2(rN)m

and

satisfy SDD

NND ['-i T

-'TDN

*D

hD

RNN

*N

hN

(7.27)

and u has the integral representation

-DL(+/rN'+'gD)+SL(>/rD+gN) on Q_-

(7.28)

E H-'/2(1'D)" and N E H1/2(FN)m satisfy the system (ii) Conversely, if of boundary integral equations (7.27), then the formula (7.28) defines a solution u E H' (S2-)"' of the mixed boundary value problem (7.26).

Proof. Let U E H' (r)"` be a solution of (7.26). Since B. u = 1'D + gN and

y-u =>/rN+gD,weseefrom (7.17)that u = 9f - DL( *N + gD) + SL( *D + gN)

on Q-,

=0

and since u satisfies the boundary conditions, *D = 0 on 1'N, and on 1'D. Hence, by (7.5),

gD = y u = yGf - 2 (-gr + TDN*N + TgD) + SDD7GD + SgN

on FD,

and

gN = BV u = B-9f + RNN*N + RgD + 2

(gN

+ TND 1rD + T*gN)

Of IN,

giving

SDDY'D - 2TDNYN = (gD +TgD) - SgN - yCf 2

on rD,

TND*D + RNN1N = 2 (gN - T*gN) - RgD - 5; g f on I'N,

which is just the 2 x 2 system (7.27). This argument proves part (i).

Conversely, suppose that V'D E H1/2(rD)"' and *N E H-'/2(I'N)m satisfy (7.27). By (6.10) and Theorem 6.11, the equation (7.28) defines a function u E H' 02-)'", and obviously Pu = f on S2-. Finally, by working backwards through the calculations above, we see that y-u = gD on I'D, and ;t3; u = gN on 1'N, proving part (ii).

Mixed Boundary Conditions

233

By putting SDD

A=

IT* 2

ND

1

-2TDN

nb

[*D]

Y

*N

h=

hD hN

RNN

we can write the system (7.27) as

AO =h, and by putting (0, O)rDxrN = (1kD, OD)r0 + (*N, ON)rN,

we have (A/, 0)roxrN = (SDD*D, OD) rD - I(TDNfN, IOD)rD + 2 (TNDtD, ON)rN + (RNN1N, ON)rD.

When P* = P, a simple argument shows that the Fredholm alternative is valid for (7.27). Theorem 7.10 Let H = H-1hI2(F D)"' X H1/2(rN)"'. If 2 isformallyself-adjoint, and if P is coercive on H' (S2-)"' and on H' (S2+)', then

A=Ao+L, where AO : H -* H* is positive and bounded below, i.e.,

Re(Ao,o,'tb)rOxrN ? cIIijIH for' E H, and where L : H -+ H* is a compact linear operator. Hence,

A : H -+ H* is a Fredholm operator with index zero. Proof Let So be as in Theorem 7.6, and let Robe as in the proof of Theorem 7.8.

Thus, S=So+LsandR=Ro+LR,where Ls: H-1/2(r)"

H1/2(r)m

and LR : H1/2(r),n _, H-112(F),n

Boundary Integral Equations

234

are compact linear operators. Noting that T = T because P is formally selfadjoint, we define

A0 _ [(S01rD)Ir.D - ITDN*N W

Lzb =

and

(Ls1D)Iro (LRl N)IrN

2TNDWD -r (R0 N)I rN

In this way, A = Ao + L, the operator L : H --> H* is compact, and

(Aoi, Y')rDxrN = ((So D)Irp,

D)ro

- I(TDNZG'N, *D)rp

fN)rN + ((RokN)IrN, *N)rN.

+ Since

(TN)*o, *N)rN = (*D, TDN*N)rN = (TDN*N,'D)rp, and since supp 1D c I'D U 11 and supp 1/'N c rN U 11, it follows that

Re(Aoi, tP)roxrN = (So1D, y'D)r +

V'N)r

+cDI1NIIH,/2(r),,, = cII

IIH,

as required.

Exterior Problems Integral equation methods are particularly suited to boundary value problems posed on the exterior domain 52+. It turns out that, in general, the solution will

not belong to H1(S2+)"', but only to HI (cZ)'" for each finite p, where 0v is defined as in (7.25). Furthermore, to make use of the third Green identity on S2+ we require a somewhat stronger result than Theorem 6.10, that incorporates a suitable radiation condition. In other words, some assumption about the behaviour of the solution at infinity is needed, and here we shall adopt the approach of Costabel and Dauge [16].

Lemma 7.11 Let u E D*(S2+)"`. If Pu has compact support in Q+, then there exists a unique function .Mu E C°°(R")"' such that

Mu(x) = f G(x,

dory

- j [Ev.yG(x, y)*]*u(y) dory

(7.29)

,

for x in any bounded Lipschitz domain S2 such that S2 U supp Pu C= S2 and where r 1 = 8 SZ I .

Proof. First note that, by Theorem 6.4, the distribution u is C°O on S2+ \ supp Pu. Given X E R11, we define .M u (x) to equal the right-hand side of (7.29)

Exterior Problems

235

with r, the boundary of any ball Q- = B. centred at the origin with radius p large enough to ensure that S2- U supp Pu C- Bp and x c Bp. By applying the second Green identity over an annular region of the form Bp, \ B,o, , one sees that the definition of Mu(x) is independent of the choice of p, because Pu = 0 = P*G(x, )* on Bp, \ Bp, . Similarly, to see that (7.29) holds for x in any bounded Lipschitz domain 01 with Q- U supp Pu C 0, , we apply the second Green identity over Bp \ S2- for any p such that Q7 C Bp. Notice that PMu = 0 on R". We now give the desired version of the third Green identity for Q+. Theorem 7.12 Suppose that f E H-i (9+)m has compact support, and choose po large enough so that

T UI'C=Bpo

and

supp f C-52+x.

If U E D* (52+)m satisfies

Pu = f

on SZ+,

and if the restriction of u to 52+A belongs to H l (S2+)"', then

u = 9f + DL y+u - SL B' u + Mu on 52+.

(7.30)

Proof By Theorem 6.10 with u- identically zero, the representation formula (7.30) holds on the bounded Lipschitz domain S2+ fl &2I, with Mu(x) given by (7.29) for x E SZ

.

(Keep in mind that v is the inward unit normal to S2+ fl

0, on r, but the outward unit normal on r I.) Before considering boundary value problems on 52+, we need to know how M acts on volume and surface potentials.

Lemma 7.13 Fix Z E R". If u(y) = G(y, z), then Mu = 0 on R". Proof Let z, x E R' with x # z. We choose a bounded Lipschitz domain S2such that z E S2- and X E 52+, and define

G(x, y)*

v(y)-{0

for y E Q-

foryE52+

Since P*v = 0 on SZ±, the third Green identity (6.29) gives

v(z) = SL B,, v(z) - DL y-v(z),

Boundary Integral Equations

236 or equivalently,

G(x, z)* =

fr

G(y, z)*B,,,yG(x, y)* day -

Jr

[B,,,,G(y, z)]*G(x, y)* dQy.

Thus,

G(x, z) = J [t3.,,yG(x, y)*]*G(y, z) day -

f

G(x, y)BV.yG(y, z) day,

or equivalently,

u(x) = DL yu(x) and therefore Mu(x) = 0 by Theorem 7.12, because Pu = 0 on SZ+.

Lemma 7.14 Let f E E* (R")'°. If U = 9f, then Mu = 0 on R". Proof. Obviously, Pu = 0 on R'1 \ supp f , and since G(x, y) is C°O for x # y, one sees from Lemma 7.13 that

Mu(x) _ (M.G(x, y), f (y)) = 0 for x E R" \ supp f . Since PMu = 0 on 1R", it follows from the third Green identity that Mu = 0

onR". To state the main result for this section, it is convenient to introduce the notation H11

(Q+),,,

= {u E D* (S2+)m U I Q+ E H 1(SZp)"` for each finite

p > 0 such that Q- C BPI.

We point out that Exercise 7.4 gives some simple sufficient conditions on u for

ensuring that .Mu = 0, in the case when P = Po. Theorem 7.15 Suppose that f E H-1 (SZ+)m has compact support. (i) Let g E H 1/2(I')"'. If U E H11 (Q+)'" is a solution of the exterior Dirichlet problem

Pu = f on St+,

y+u=g onr, Mu = 0

on lR",

(7.31)

Exterior Problems

237

then the conormal derivative Mfr = B+ U E H-112(r)'" is a solution of the boundary integral equation

Si/i = y9 f - (g - Tg) on r,

(7.32)

;

and u has the integral representation

u=Gf+DLg-SL,/i one

.

(7.33)

Conversely, if ili E H-112(I')ry` is a solution of the boundary integral equation (7.32), then the formula (7.33) defines a solution u E H11 (S2+)m of the exterior Dirichlet problem (7.31).

(ii) Let g E H-112(x)"'. If U E Hi, (S2+)'" is a solution of the exterior Neumann problem

Pu = f on 52+,

B+u=g on r, Mu = 0

(7.34)

on R",

then the trace* = y+u E H 112 (r ),n is a solution of the boundary integral equation

Ri/i = By G f - i (g + T*g) on r,

(7.35)

and u has the integral representation

u = G f + DL *- SL g on Q+.

(7.36)

Conversely, if ili E H1/2(I')'" is a solution of the boundary integral equation (7.35), then the formula (7.36) defines a solution u E HIOc, (Q+)... of the exterior Neumann problem (7.34). (iii) Let gD E H1/2(r)and gN E H-1/2(I')", and define hD E H1i2(rD)"' and hN E H-1/2(rN)m by

hD = Y9 f - SgN - (gD - TgD)

on FD,

2

hN = BV +9f - RgD - (gN + T *gN) 2

on FN.

Boundary Integral Equations

238

If u E H11 (S2+)"' is a solution of the exterior mixed problem

Pu = f

on SZ+,

Y+u=gD on I'D, l3+ u = gN

on FN,

Mu=0

on R",

(7.37)

then the differences

*D = l3+ u - gN E H-1/2(rD)n'

and *N = Y+u - gD E

H112(pN)'n

satisfy

-

SDD

RNN

TND

hD

1/JD

Z TDN

j[Nj=[hN]'

(7.38)

and u has the integral representation

u = 9f + DL(i/rN + 9D) - SL(*D +,N)

on Q+.

(7.39)

Conversely, if ilrD E H-1/2 (rD)"' and *N E H1/2(rN)' satisfy the system of boundary integral equations (7.38), then the formula (7.39) defines a solution u E H11 (S2+)"' of the exterior mixed problem (7.37).

Proof. Suppose that u E Hil (S2+) is a solution to the exterior Dirichlet problem (7.31). By Theorem 7.12,

u = 9f + DL y+u - SL l3+ u on 52+,

(7.40)

and then by (7.5),

Y+u = yG f + (y+u + T y+u)

- S13+ u

on F.

2

Using the boundary condition y+u = g, and putting /r = B+ u, we arrive at the boundary integral equation (7.32) and the integral representation (7.33). To complete the proof of (i), suppose conversely that * E H-1/2(F)m satisfies (7.32), and define u by (7.33). Together, (6.10) and Theorem 6.11 im-

ply that u E H11 (S2+)"', and it follows from (6.2) and (6.19) that Pu = f on 52+. Also, y+u = g by (7.5). Finally, Lemma 7.14 shows that M9 f = 0,

M DL g = MG9vg = 0 and M SL Vr = MGy"i/r = 0, so Mu = 0, and hence u is a solution of (7.31).

Regularity Theory

239

The proof of part (ii) proceeds in the same way, except that one takes the conormal derivative of both sides of (7.40), instead of the trace, to obtain

B'u=8'Gf -Ry+u-z(-l3vu+T*B-,) on F. The proof of part (iii) is similar to that of Theorem 7.9.

Regularity Theory In Theorem 4.18, we proved local regularity up to the boundary for solutions to elliptic partial differential equations. A simple argument based on this result yields the following local regularity estimates for the boundary integral equations. Recall the definition (7.25) of the set Q+ Theorem 7.16 Let G 1 and G2 be bounded open subsets of R" such that G 1 C= G2

and G 1 intersects r. Put

Sgt-= G; n c2} and r = Gl n S2+ and suppose, for some integer r > 0, that 1`2 is

for j = 1, 2, Cr+1,1

(i) If */r E H-1/2(I')'" and f E Hr+3/2(r2)"` satisfy

Si/r= f onF2, then t/r E Hr+l/2(rl)"' and IIkIIH1+'/2(r,)< GIIiIIH-"2(r)"

+CIIfIIHr+3/2(r2)m

(ii) If P is coercive on H1(Q-)"' and on H1(c2)"', and if i// E H1/2(I')' and f E Hr+1/2(x2)"' satisfy

R* = f

on I'2,

then i/r E Hr+3/2(F1)"' and II*IIHI+3/2(r,)

< CII

IIH'/2(r), + Cll f IIH1+i/2(r2)"-

Proof. Let G3/2 be a bounded open subset of R" such that G1 C= G3/2 C G3/2 C= G2,. and put 523/2 = G3/2 n Sgt.

Boundary Integral Equations

240

In case (i), the single-layer potential u = SL * E H 1(S22 )"' satisfies

Pu=O one , yu= f on r2, so using the jump relation for I31 SL * (Theorem 6.11), together with the trace estimates (Theorem 3.37) and elliptic regularity (Theorem 4.18), we find that JIB, u

- By uIIH'+1r-(r,)

CIIuIIHr'+2(n3/,)1" + CIIuIIH'+2(niZ)m

CIIuIIH'(sz2)", +CIIu1IH'(n )", +CIIf1IHr+3r_(r2),,,.

The estimate follows because II u II H' (s2±)m < C II *II H-'/2(r)m

In case (ii), the double-layer potential u = DL i E H' (S22 )"' satisfies

Pu=0 onc22, l3,u = f on r2, so

IIfilH'+sn(r1)", = IIY+u - y-UII

CIIu and finally IIuIIH'(12

)m

< C11

IIuII

H'(Q )", + CII f 1I

IIH'/2(r)m

D

We saw in Theorem 7.2 that the mapping properties of the boundary integral operators hold for an extended range of Sobolev spaces when F is smoother than just Lipschitz. The regularity result just proved allows us also to extend the Fredholm property for R and S.

Theorem 7.17 If I' is

C''+1.1 for

some integer r > 0, then

H5+1/2(r) is Fredholm with index zerofor -r < s (i) S : Hs-1/2 (r)"' r, and ker S does not depend on s in this range; (r)m HS-1/2 (r)"' is Fredholm with index zero for -r -1 < (ii) R : s < r + 1, and ker R does not depend on s in this range.

-

Proof We know from Theorem 7.6 that S is Fredholm with index zero when

s = 0. Thus, let 01, ..., ¢p be a basis for kerS in H-1/2(r)'". In fact, by Theorem 7.16 these basis functions belong to

Hr+1/2(r)",, and we can choose

Exercises

241

them to be orthonormal in L2(r')m. The same reasoning applied to S* yields an orthonormal basis 01, ... , BP for ker S*, with each 9 j E H''+1 j2 (r)"` . We can therefore define a compact linear operator

for -r < s < r,

K : HS-1/2(r)m by P

Ki/r = E(Oj, '1` j=1

and a bounded linear operator

A = S + K : HS-112(r)r -+ H:+1/2(f

)m

for -r < s < r.

The operator A is certainly Fredholm with index zero when s = 0, and since

(0j, Silr)r = 0 and (0j, K,lr) = (0j, Or

for all * E H-1/2(r)"',

it is easy to see that the homogeneous equation A* = 0 has only the trivial H-t/2(r)m. Thus, the inhomogeneous equation A*/r = f has a solution in unique solution * E H-112(1,)m for every f E H1j2(F)"`. Furthermore, if f E Hr+112(r)m, then Si/r E Hr+1/2(x)"1 because Kt/r E Hr+112(ryn, and so * E Hi-112(r)"' by Theorem 7.16. It follows that A has a bounded inverse for s = r, and the same is true of A*. Hence, by interpolation and duality, A is invertible for -r < s < r. Therefore, since K is compact, the operator S must be Fredholm with index zero for -r < s < r. Also, ker S does not depend on s, H-r-1/2(1,)"1 satisfies Si/r = 0, then A* = Kiln E Hr+i'2(r)m because if * E A-1 Kulr E Hr-1/2(x)m. The proof of (i) is now complete. and thus i/r = Part (ii) may be proved using the same approach. The allowed range of s is larger because the basis functions for ker R belong to Hr+3/2(r)m

0

Exercises 7.1 Suppose that S2 is a C°O hypograph x < (x'), and let K (x, y) be any one of the six kernels in (7.9). Show that

K(x,y)u(y)day

f.p. J E,o r\B,(f x)

= f.p. ElO

X,-y'I>E

K(x, y', (y'))i(y', (y')) 1 + I grad (y')I2 dy'

242

Boundary Integral Equations

for x = (x') and'* E D(1')'. [Hint: apply Theorems 5.15, 5.19 and 6.3.]

7.2 Suppose that S2- is a C2 hypograph given by yn < C(y'), and assume (without loss of generality) that

(0) = 0 and

grad (0) = 0.

Put 'T'E = {w E Si-1 : Ew E S2+},

and show the following. (i) There exists a = a(E, r7) such that rE+

= IN E Sn-1 co = (r7 cos 9, sin 9), 17 E S"-2, a (E, r7) < 0 < 7r/2).

(If n = 2, then 17ES0={+1,-1}.) (ii) The function a satisfies lima (6, r7) = 0

a=

and

E

o

as ac

1

2

` n-1 n-1

(E r7 cos a).]

(iii) With S+'-' = [Co E S"-1 : (0n > 0}, n/2

f

T,+

f(w)dw =

sin0)dOdr7 10E.0 f (i?(E,nf(r7cos0, Cos 0,

5'-2

=f X

n-1 n-1

f (w) dw - 46

a, a, (0) p=1 q=1

+

f (17, 0)r7p r7q d 77 + 0 (E2). J1-2

(iv) In part (iii), the term in E vanishes if f (-w) = - f (w) for all co E Sn -1.

7.3 Show that the right-hand side of the boundary integral equation (7.23) satisfies

z (8 - T"8) - Ci- Gf, dr)r = 0

for every solution 0 E H1/2(1')'" of the homogeneous adjoint problem

Exercises

243

R*4 = 0 if and only if f and g satisfy

(g, y v)r + (f, v),- - = 0 for every solution v E H 1(Q-)"' of

P*v=0 onQ

,

onl'. [Hint: see the discussion following Theorem 7.6.] 7.4 Assume that P has no lower-order terms (i.e., P = PO), and that G (x, y) _ G(x - y) is as in Theorem 6.8. Show that if u satisfies the hypotheses of Lemma 7.11 and if, as Ix I -+ oo,

u(x) = o(l) and 13,u(x)

o([Ixl log IxI]-1)

when n = 2,

o(IxI-1)

when n > 3,

then Mu = 0 on R". Here, v is the outward unit normal to the ball Bp.

7.5 Show that if Pu = 0 on R, then Mu = u on R. [Hint: apply the third Green identity over the ball BP.] 7.6 The Calderon projection is the linear operator PC defined by

PCO =

y-(SL*2 -DL*I)

,

where

13v (SL *2 - DL *1)

_

*1 *2

Theorem 6.11 implies the mapping property

Pc : H1/2(r)n' X H-1/2(r)m -+ H1/2(r)m

X

H-I/2(r)m

and if 0 = Pct/i, then the function u = SL *2 - DL *1 satisfies

Pu = 0

on Q-,

y-u=01 on I',

B u=42 onr, so u = SL 4)2 - DL 01 by Theorem 6.10. Hence, Pc4) = 45, or in other words PC20 = Pct', demonstrating that Pc really is a projection. (i) Show that

PC=

2(I - T)

S

ER

2

(I + T'*)

Boundary Integral Equations

244

(ii) Deduce that

SR = 4(I - T2), ST* = TS, RT = T*R, RS = 4[I - (T*)2].. 7.7 Recall the definition of the Steklov-Poincare operators 13 V from (4.38). Show that if S : H-'t2(I')'" -+ H1/2(P)"' is invertible, then we have the representations

B,U = R+ 4(I +T*)S-'(1 +T) = 2(I +T*)S-1 and

B,,V = R* + (1 + T *)(S*)-1(1 + T) = (I + T *)(S*)-' 2

4

7.8 Let S2± = R1, and think of r as R"-'. Also, assume P = Pa with constant coefficients, so that is a homogeneous quadratic polynomial, and let G(x, y) = G(x - y) be the fundamental solution given by Theorem 6.8. (i) By applying Lemma 5.21, show that if n > 3, then

S*(x') = J

dal

ms(

for x' E R"-',

where, with the notation (5.28),

The function ms is called the symbol of S. (ii) In the same fashion, show that for n > 2,

R*(x') = J

mR( ')

(')e12ngxd",

where n

MR( O =

J

it

E1: j=1 k=1 n

n

_ -(2X)2 E E Anj (J

ff

SjSkP(S', n)-'

j=1 k=1

(iii) From the homogeneity properties

ms(t') =

and mR(t:;') = tms(1;')

fort > 0,

Exercises

245

deduce that S:

Hs-1/2(RR-1)m

Hs+1/2(R"-I)m

Hs+1/2(wn-1)m

Hs-1/2(Rn-1)m

and

R:

for all s E R. (iv) Let X E C mP(lR") satisfy X = I on a neighbourhood of zero, and consider

u(x) = Ti-1s1l1 - X{OJv( )). where v is rational and homogeneous of degree j - 1, as in Assump-

tion 5.20, but with j < -1 + n. (Thus, v is not locally integrable on RI.) Modify Lemma 5.21 accordingly, and hence show that the mapping property of S in part (iii) holds also when n = 2.

The Laplace Equation

Our development of the general theory of elliptic systems and boundary integral equations is now complete. In this and the remaining two chapters, we concentrate on three specific examples of elliptic operators that are important in applications. This chapter deals with the Laplace operator in R", denoted by If

A

a2 J=1

The Laplacian constitutes the simplest example of an elliptic partial differential operator, and its historical role was discussed already in Chapter 1. After deriving the fundamental solution for the Laplacian, we shall introduce a classical tool from potential theory: spherical harmonics. These functions turn out to be eigenfunctions of the boundary integral operators associated with the Laplace

equation on the unit ball. They are also useful for studying the behaviour of harmonic functions at infinity, leading to simple radiation conditions. The final section of the chapter investigates ker S and ker R, and the sense in which S and R are positive-definite. The operator P = -A has the form (4.1) with constant, scalar coefficients

Ajk = Sjk,

Aj = 0,

A = 0.

Associated with -A is the Dirichlet form (Pn (u, v) =

f grad u grad v dx,

and the conormal derivative (4.4) is simply the normal derivative,

=

au a

. V

Obviously, -A is formally self-adjoint and strongly elliptic; see (4.6) and (4.7).

246

Fundamental Solutions

247

Fundamental Solutions The Fourier transform of -Du is P(4)u(4) where P(l;) = (27r )2 1 1; 12, so by Theorem 6.8 a fundamental solution for -A is

G(x,y)=G(x-y),

where G(x)=4

1

whenn=3.

Exercise 8.1 is the corresponding calculation for n = 2. To give a fundamental

solution for a general n, we denote the surface area of S"-', the unit sphere in W, by

r

r

cia-

7rn/2

dcv=2

Iwl=1

r(n/2)

;

(8.1)

see Exercise 8.2.

Theorem 8.1 A fundamental solution for the operator -A is given by

G(x) =

when n > 3,

1

1

(n - 2)T

IxIn-2

and, for any constant r > 0, by

G(x) = Zn log Ixl

when n = 2.

Proof The Laplacian is radially symmetric (see Exercise 8.3), so it is natural to seek G in the form G(x) = w(p) where p = Ix 1. Since AG = 0 on R" \ (0), Exercise 8.4 shows that w must satisfy

Ld

PIT-t dp p

-l dw

dp = 0

for p > 0,

so

w(p) =

an

1

+ bn

when n > 3,

n - 2 pn-2

or 1

w(p) = a2 109 - + b2 p

when n = 2,

for some constants an and bn. The choice of b is arbitrary, but an is fixed by the requirement that G satisfy (6.12), i.e., by the requirement that -AG = 8

248

The Laplace Equation

on R", or in other words

-(G, AO) _ O(0) for O E D(1R").

(8.2)

Any test function 0 E D(R") has compact support, so we can apply the second Green identity (1.9) over the unbounded domain {x :IxI > c), and arrive at the formula

-

f

G(x)Oq(x) dx =

f

0(x)a,G(x) da,r - J

(x) do-,

X I=E

X I>E

(8.3)

where yr = -x/E. Since grad G(x) = dp IXI = - IXI"

for n > 2,

(8.4)

we have 8,G(x) = -(x/E) grad G(x) = a,, -0` for IxI = E. Thus, by the mean-value theorem for integrals,

f

Ej J

fi(x) dax =

(x)8vG(x) dox = a"

IxI=E

xI=E

for some xE satisfying IxE I = E, whereas

O(E)

JIxI=E

G(x)8vO(x) da,, = 10(cllog,-I)

if n > 3, if n = 2.

Thus, if a" = 1/Ta, then (8.2) follows from (8.3) after sending f 0. An alternative method of determining a" is to apply the third Green identity

to the constant function u = I over the unit ball. One obtains the formula DL 1(0) = -1, from which it again follows that a" = 1 / T . 0 Throughout the remainder of this chapter, G(x, y) = G(x - y) will always denote the fundamental solution from Theorem 8.1. Recalling the definitions of the boundary integral operators S, R and T given in (7.3), we see first that by (7.8), Si/r(x) =

*(Y)

1

(n - 2)Tn Jr Ix

-

yI"-2

d6y

when n > 3,

and

S* (x) =

1* 2,

r

(y) log Ix

day YI

when n = 2,

249

Fundamental Solutions for x E I". By (7.9) and (8.4), the kernel of T is

2a,,,yc(x, y) -

2 v,, (x - y)

T.

IX - Y111

and the kernel of R is 1

.yG(x,y)=

Ix-yln+2

'

then

for n > 2. Notice that if r is


for x, y E r,

so T has an integrable kernel, allowing us to write

T*(x)

=

forxEr;

Y)

2

- An

see Theorem 7.4, and cf. Exercise 8.6. If r is C2, then

R1/r(x) = vl f.p. 6g0

n I

J

f

r

vx . UY'n

\B,(.,,) IX - Y1 yx

V/(y) day

(y - x) vy (x - y) Ix - y1

daY

for x E r; see (7.9). For later use, we conclude this section by considering the eigenvalues of -A.

Theorem 8.2 Let S2 be a bounded Lipschitz domain and let r = rD U 1Z U rN be a Lipschitz dissection of r = 8 Sl. If U E H 1(S2) is a non-trivial solution of

-Au = Au on 7, yu = 0 on rD, 8u=0 onrN, then A > 0. If, in addition, rD intersects every component of r, then A > 0.

Proof Applying the first Green identity, we have 4> (u, u) = (Au, On + (8 u, Yu)r = AIIulI .2(n) I

and obviously 4 (u, u) = II grad u 112,(Q) > 0 and IIU II L2(n) > 0, so A > 0.

Moreover, if A = 0 then OQ(u, u) = 0, implying that gradu = 0 on n, and hence u is constant on each component of 0.

0

250

The Laplace Equation

The same argument yields a uniqueness theorem. Corollary 8.3 Let 0 be a bounded Lipschitz domain. If U E H I (Q) is a solution of the homogeneous mixed problem

-Au=0 one, y u = 0 on I'D,

a,u = 0 on FN, then u is constant on each component of 92. If, in addition, rD intersects every component of r, then u is identically zero on 0.

We remark that, for the first part of each of the preceding two results, the homogeneous boundary conditions could be replaced by the weaker assumption yu)r < 0. that

Spherical Harmonics For each integer m > 0, let P,,, (]R") denote the set of homogeneous polynomials of degree m in n variables, i.e., the set of functions u of the form

u(x) = E aaxa for x E R,

(8.5)

IaI=m

with coefficients as E C. A solid spherical harmonic of degree m is an element of the subspace

xm(R")= (uEPm(1R"):Au =0on W). Apart from the results involving the boundary integral operators, our general approach to the study of spherical harmonics is essentially that of Miiller [70]. Let

M(n, m) = dim Pm(R") and N(n, m) = dimf,"(IR") for n > I and m > 0. (8.6) By a standard combinatorial argument, the number of non-negative integer + a" = m is solutions al, . . . , a" to the equation al +

M(n, m) _

1

1

(m+n- ), n

(8.7)

Spherical Harmonics

251

and since each u E P," (R") has a unique representation m

u(x) _

>2Vk(xI)Xn -k

E Pk(R"-'),

(8.8)

forn > 2 and m > 0.

(8.9)

with Uk

k=0

we see at once that

M(n, m) _ >2 M(n - 1, k) k=0

Also, Po = 71o is just the space of constant functions, and P1 = WI is just the space of homogeneous linear functions, so

M(n, 0) = N(n, 0) = 1 and M(n,1)=N(n,l)=n

forn> 1.

Taking the Laplacian of (8.8), we find after some simple manipulations that m

Au (x) =

[A'vk(x') + (m - k + 2) (m - k + 1)uk_2(x')]Xnl-k k=2

forn>2 and m>2, where A' is the Laplacian on IRn-1. Thus, U E 7-(R") if and only if vk-2(X')

-A'vk (x')

(m-k+2) (m-k+1) fort
with the choice Of V,,,-l EP,,-I(

n

) and vn, E Pm (R

(8.10)

1) being arbitrary.

Hence,

N(n, m) = M(n - 1, m - 1) + M(n - 1, m)

forn>2 and m> 1, ( 8.

11 )

and so it follows from (8.9) that m

N(n,m)=>2N(n-1,k)

forn> 1 and m> 1.

(8.12)

k=0

Furthermore, since (

ifm=Oorl,

1

N(1, m) = t 0 ifm > 2, we have

N(2, m) _

1

2

ifm = 0, if m> 1,

(8.13)

The Laplace Equation

252

and in view of (8.7) and (8.11),

N(n , m) _

2m + n2 2

n-

forn > 3 and m > 0.

(m n+ n 3 3l

(8.14)

In particular, N(3, m) = 2m + 1. Put

7-l," (&'-') = {

: * = u lso-t for some u E H. (R")I.

Corollary 8.3 implies that the restriction map u H u Is- i is one-one, and hence is an isomorphism from 7I,,, (R") onto 7l", (S"- ), so

dimfl,,,(S"-') = N(n, m) forn > 2 and m > O. An element of 7-1,,, (S' ') is called a surface spherical harmonic of degree m.

We now show that 7-l": (S'-') is an eigenspace of each of the four boundary integral operators on S". Later, in Theorem 8.17, we shall see that the spherical harmonics account for all of the eigenfunctions of these operators.

Theorem 8.4 If T = S"-i forn > 3, then T = T * _ - (n - 2) S, Ri/r =

m(m+n-2) /r and SiJr =

2m+n-2

1

2m+n-2

fori/r E 7L (8.15)

Proof. Observe that

forx,yEF,

vy.=y and

(8.16)

so the kernel of T is

2 vy (x-y) =-(n-2)G(x,y), r" Ix - yl" and therefore T = T * = - (n - 2) S. Now suppose that Jr = y u E 71,,, ; with u E 7-l, (Rn). Euler's relation for homogeneous functions, u(y) = mu(y), implies that au

av

=mi/r on IF,

-1) y; a;

(8.17)

and therefore, applying Theorems 7.5 and 7.7,

S(mi/r) =

Ti/r) 2

and

R1* r = 2

T*(mi/r)}.

(8.18)

Spherical Harmonics

253

Since T = T* = -(n - 2) S, it follows that mSi/r = [i/r - (n - 2)Si/r]

Rir = 2m[i/r + (n - 2)S*],

and

Z

0

giving (8.15).

The same method of proof yields the following result in two dimensions.

Theorem 8.5 If F = S', then

T* = T** =

27r

fr k(y) dcr for*

E

L2(F),

(8.19)

and when'i/r E R,, (S'), Ri/r = 0,

Ri/r= 2ir,

Si/r = (log r)i t,

Si/r= 2ir, 1

T ilr = T *ifr = -,lr for m = 0;

Ti/r=T*1/r=0 form> 1.

Proof The relations (8.16) remain valid for x, y E S" kernel of T is now I

1

it Ix-y12

27r

(8.20)

(8.21)

when n = 2, but the

forx,yEF,

implying (8.19). To prove (8.20), suppose that m = 0. We see at once from (8.18) that R +' L= 0. Furthermore, i/r is constant, so by symmetry Si/r is also constant,

and then uniqueness for the solution of the interior Dirichlet problem shows that SL * is constant on the disc Q-. At the origin, we have

SL*(0) =

27r

Ivl=i

log

IYI*(Y)day = (logy)

.

so SL i/r = (log r)ilr on SZ-, and hence Sii = y- SL a/r = (log r)i/ on r. If m > 1, then using (8.17) and the divergence theorem,

T*

T*v/r

27rm, r

8vdc

2rrmfst-Dudx=O.

Thus, (8.21) follows at once from (8.18). We now consider spherical harmonics that are invariant under rotation about the nth coordinate axis.

254

The Laplace Equation

Lemma 8.6 Given m > 0, there exists a unique function u satisfying (i) U E H. (R"); (ii) if A E R"" is an orthogonal matrix satisfying Ae = e, then

u(Ax) = u(x) forx E R"; (iii) U(en) = 1. In fact,

u(x) =

1

ri,-I

(x + ix'

j7)... drl.

(8.22)

fs"-2

Proof. One easily verifies that (8.22) defines a function u satisfying (i), (ii) and (iii). To show uniqueness, suppose that A E IR""" satisfies the assumptions of (ii). It follows that A has the block structure

A= where A' E

1[l;("-l) "t"-ti is orthogonal. Thus, with uk as in (8.8),

u(Ax) _ E vk(A'x')x, -k, k=0

and so the conclusion of (ii) means that vk (A'x') = vk (x') for all x' E IEI;n-1 which in turn means that vk (x') depends only on Ix'j. Hence, every it E P (R")

satisfying (ii) has the form (8.8) with vk(x') = dklxIk, where dk = 0 if k is odd. Exercise 8.4 shows that

O'Ix'Ir = r(n - r

- 3)Ix'jr-2,

so the condition (8.10) for u E T(m (R") holds if and only if the coefficients satisfy

-k(n + k - 3) dk-2 = (m - k + 2)(m, - k + 1) dk

for2
(8.23)

If m is even, then dm is arbitrary and d,,,_ i = 0, whereas if m is odd, then dm_I

is arbitrary and d", = 0. Since u(e") = do, the normalisation condition (iii) fixes u with the requirement that do = 1.

0

Spherical Harmonics

255

With the notation of Lemma 8.6, we define Pm (t) = Pn, (n, t), the Legendre polynomial of degree m for the dimension n > 2, by

1 - t2 + ten, for -1 < t < 1 and r?E Sii-2,

where to =

Pm(t) = u(w),

1 and u (-x) _

noting that u (w) is independent of q. Observe that since u

(-1)nlu (x), the Legendre polynomials satisfy

form>0 and n>2.

Pm(1)=1 and P,n(-t)=(-1)mPm(t) Also, we have the explicit representation nl

Pm(n, t) = >dk(n, m)(1 _

t2)k/2tm-k,

k=O

where the coefficients dk = dk(n, m) are determined by the recurrence relation (8.23) with the starting values do = 1 and d1 = 0.

When n = 2, the integral (8.22) becomes just the sum over n E S° _ (-1, +1), with To = 2, so we find that

1 - t2)m + (t - i 1 - t2)m].

P. (2, t) = 2 [(t + i

(8.24)

If t = cos 0, then t ± i-,,/1 - t2 = e±'O, so P. (2, cos 0) = cos m46,

and therefore Pm (2, t) is the mth Chebyshev polynomial of the first kind. Exercise 8.8 shows that Pm(3, t) is the usual Legendre polynomial of degree m. The fundamental solution for the Laplacian can be expanded in terms of these polynomials, as follows. Theorem 8.7 Let bm = bm (n) be the coefficients in the Taylor expansion 00

(1 _ 1z)n-2

=

bnzm for I z I < 1.

(8.25)

m=O

If 0 < IxI < IYI and x y = Ix IIyI cos0, then 1

IX

00

> bm Pm (n, cos 0)

- yln-2 = n1=0

Ix lIn lyln-2+n1

for n > 3,

(8.26)

The Laplace Equation

256

and m

00

log Ix

= log

1

A

IYI

E

+ in=1

M

Pm(2, cos 0)

.

IYI-

Proof. By Taylor expansion about x = 0, we have 00 1

Ix - y In-2

_

Fm(x, y)

(8.27)

for IxI < IYI,

M=O

where

F.(x,Y) = > a, (y)x"

and

a. (y) =

1

IaI

1

lal=m

Note that F. (x, y) is homogeneous of degree m in x, and of degree - (n -2) -m in y. Taking the Laplacian of (8.27) with respect to x, we see that 00

EOxFm(x,Y)=0 for IxI < IYI, ,n=0

so by uniqueness of the coefficients in a Taylor expansion, Fm

y) E 7-1m (ill;")

for each integer in > 0. Moreover, if A E R" ,n is an orthogonal matrix, then

jAx - Ayl=Ix - Yl,and so Fm (Ax, Ay) = F,,, (x, y).

In particular, Fn, (Ax, y) = Fm (x, y) if Ay = y, and therefore by Lemma 8.6,

Fm (w, C) = b,n P,,, (co ) for co,

E S" -1,

and for some constant b,,,. Thus, Fm (x, Y) = Ixln

IYI-(,r-2)-m

Fm (ti' IyI l

brPm(COS0)

In-2+m '

(8.28)

and by choosing x and y so that I y I = 1 and cos 0 = 1, we have Ix - yI = (Ix12 - 2IxI + 1)1h/2 = 1 - IxI, so the b,n are as in (8.25). The proof of (8.26) is now complete. When n = 2, we proceed in the same way, except that now Ial

a,(Y)_ (ai

8y logIYI'

Spherical Harmonics

257

so if m > 1, then F,n (x, y) is homogeneous of degree m in x, and of degree -m in y. It follows that for some constants bn m

1

Fo(x, y) = log

and F. (x, y) = b,n Pm (2, Cos 0) Ix

lYl

l

form > 1,

iyitm

and by choosing lyl = 1 and cos0 = 1, we see that b,n = 1/m because log

I

lxl = -log(l - lxl)

m 00 m=1

m

for lxl < 1.

The next theorem gives some expansions of general harmonic functions in terms of spherical harmonics. Recall the definition of Mu given in Lemma 7.11.

Theorem 8.8 Write x = pco, where p = Ixl and w = x/p. (i) If /u(x) = O for p < po, then there exist

u(x) = EP "'

(w)

E fn,(Sa-1) such that

for p < P0.

m=0

(ii) If Du (x) = 0 for p > P0, and if M u = 0 on R", then there exist

E

such that

U(X) = EP 00 2

(w)

for p > Po,

when n > 3,

,n=0

and 00

U (X) = (log P)1o(w) +

p-I"Yin. (w)

for p > Po,

when n = 2.

m=1

Proof Let S2- = Bp,,, the open ball of radius po and centre 0, and consider the special case when u = SL 0 for some 0 E L 1(I'). By (8.27), we get the desired expansion for p < po, with ,n (w) _

(n - 2)Tn

Fm(we Y)O(Y) day.

If n > 3, then by interchanging x and y in (8.27) we see that 00

Ix - yin-2

= L F,n(y, x) m=0

for Ixi > IYI,

The Laplace Equation

258

and by (8.28),

F

X)

2+2,,

yl

(XI)

so u has the desired expansion for p > po, with

f

IYIn-2+2mFm(w, y).0 (Y)day. 1 ..(w) = (n - 2)Tn r When n = 2, the only essential change is to the terms with m = 0, which are

Jr

Fo(x, y)o (Y) day = - J (log IYI)O(Y) dcry

if p < po,

Fo(y, x)o (Y) day = -(log p) J 0 (Y) day r

if p > po.

r

and

Jr

Likewise, any double-layer potential u = DL 0 has expansions of the desired form, with *o = 0 in part (ii), because if n > 3, then a

=0 E ava F(x,y)

1

avy IX

M=0

forlxl
Y

and 8

1

°°

1

avy Ix - An' =

a n 2+2,n F. (x, Y)] avy IYI -

for IXI > IYI

In the general case, if Au(x) = 0 for lxl < po, then by applying the third Green identity over SZ- = Ba, , where p, < po, we see that an expansion of the desired form holds for p < pl. In fact, this expansion is valid for p < po, because the ikm cannot depend on the choice of p I. This completes the proof of part (i), and part (ii) follows in a similar fashion with the help of Theorem 7.12.

Behaviour at Infinity Fix po > 0, and define z

xa

_ \Izll

x

for x 0 0.

(8.29)

259

Behaviour at Infinity We call xu the inverse point of x with respect to the sphere aB,,,,. Notice (xa)O = x

and

> po if and only if lx I < po, xO = x if and only if lx I = po, and IxO I < po if and only if Ix I > po. For any subset E C_ III" \ {0}, we write EO _ {xa : x E E}, I

and for any function u defined on E, we define uO, the Kelvin transform of u, by uO(x4)

(?i)i_2u(x) .

(8.30)

Exercise 8.9 shows that

Lu3(xo) _

n+2 xllAu(x),

IPoll

a fact that yields a simple characterisation for the radiation condition Mu = 0; see (7.29) for the definition of Mu.

Theorem 8.9 Suppose that Au(x) = O for Ix I > Po. (i)

When n > 3, the function u satisfies Mu = O on R" if and only if

u(x) = O(Ix12-")

as Ixl

oo.

(ii) When n = 2, the function u satisfies Mu = 0 on R'1 if and only if there is

a constant b such that

u(x) = blog lxl + O(Ixl-') as lxl -* oo. (iii) When n = 2, the function u satisfies u (x) = O (1) as Ix I -a oo if and only if there is a constant b such that

u(x) = b + O(Ixl-') as 1x1 - oo. In this case, Mu = b. Proof The Kelvin transform ul is harmonic on the punctured ball Bp, \ (0), so by applying the third Green identity over an annular domain Bp, \ Bp,, with 0 < pi < p2 < po, we see that uO = v° + v°°, where vO(xa) is harmonic for Ixui < po, and v°O(xa) is harmonic for IxV I > 0, with Mv°° =0 on R".

The Laplace Equation

260

To prove part (i), let n > 3 and write w = x/Ixl = xd/I xd I. By Theorem 8.8, there are surface spherical harmonics *,0, and of degree m, such that 00

v°(xd)

= Y Ixd Im *° ((O)

for Ixd I < P0,

,n=0

and 00

v°O(xd) _

(w)

Ix0

for Ixal > 0.

,n=0

Suppose that u(x) = as I x I -+ oo. This assumption means that ud is bounded at zero, and thus r10 must be identically zero for all m > 0. Hence, O(Ixi2-n)

ud=v° and u(x)

(A) n-2 ud(xa) _ E Po-2+2,n 00

x

(w)

for IxI > p0.

,n=0

We conclude that 8"u(x) = O(Ixl2-"-1,I) for all a, and so Mu = 0 on R" by Exercise 7.4. Conversely, if Mu = 0 on R" then u(x) = O(Ixi2-") by Theorem 7.12.

Now suppose that n = 2. By arguing as above, it is easy to see that if u(x) =bi log lxi +b2 + O(Ixl-1) as lxl -+ oo, then the function 5(x)= u (x) - b1 log Ix I - b2 satisfies Mu = 0, and therefore Mu = b2M 1= b2 by Lemma 7.13 and Exercise 7.5. The converse again follows by Theorem 7.12.

0 Solvability for the Dirichlet Problem

We know from Theorems 7.6 and 7.8 that, for any bounded Lipschitz domain Q-, the boundary integral operators

S : H-1/2(F) - H1/2(1') and R : H'/2(f') -+

H-1/2(1.)

are Fredholm with index zero. The following uniqueness theorem for the exterior Dirichlet problem will help us to investigate ker S. We shall see that complications arise when n = 2. Theorem 8.10 A function u E H11 (Q+) satisfies

Au = 0

on Q+,

y+u = 0 u(x) = if and only if u = 0 on Q+.

on r, O(Ix12-")

as IxI -* 00

(8.31)

Solvability for the Diriehlet Problem

261

Proof. Suppose that (8.31) holds. Applying the first Green identity over S2p = 7+ fl Bp for p sufficiently large, we have (DS2P (u, u) _ -(av u, Y+u)r

=

- fa

da B,,

(-f'_-u(Pw))u(Pw)P"_' dw. dp

Theorems 8.8 and 8.9 imply that

u(pw) = O(p2-n) and

-d u(pw) _ dp

0(p")

if n > 3,

O(p-2)

if n = 2,

so

fzP0(p-')

Igrad ul2dx=fiS2+(u,u)

O(p2-n)

if n > 3,

ifn = 2. (

Sending p -+ oo, we deduce that grad u = 0 on Q+, and thus u is constant on each component of 52+. Since y+u = 0, it follows that u = 0 on 52+. The converse is obvious. 0

Corollary 8.11 Let* E H-1"2(F) satisfy S* = 0 on r. (i) Ifn > 3, then i/i = 0.

(ii) Ifn=2and(l,+/i)r=0,then*/r=0. Proof. The single-layer potential u = SL * satisfies

Au=0 on Q-'-, y±u = 0 on l', and as IxI -+ oo, we have u(x) = O(Ixl2-") when n > 3, but

it(x)=-- (1,OrlogIxl+O(Ixl ') whenn=2. Thus, provided we assume that (1, Or = 0 when n = 2, it follows from Theorem 8.10 that it is identically zero, and hence . =

0.

For the Laplacian, we can prove a stronger version of Theorem 7.6.

Theorem 8.12 Let

V = H-'/2(F)

ifn > 3,

262

The Laplace Equation

and

V =[ * E H-112(1') : (1, lr')r = 0 } if n = 2. The boundary operator S satisfies

(Si,r, Or = J grad SL 1k grad SL 4, dx for r1i E V and O E H-1/2(r), (8.32)'

and is strictly positive-definite on V, i.e.,

(S*, *) r > 0 for all * E V \ (0). Proof. Let 1lr E V and 0 E H-112(r). If p is sufficiently large, and if we put

u = SL * and v = SL 0, then (as in the proof of Theorem 7.6) the jump relations and the first Green identity imply that

(SL, 4,)r = (yu, av v - av v)r = n-(u, v) + ('n+ (u, v) + I Bp BP

The integral over aBp is O(p2-") if n > 3, and is O(p-1) if n = 2. Thus, in either case, we obtain (8.32) after sending p -+ oo.

It is obvious from (8.32) that (S*, Or > 0. Moreover, if (S*, Or = 0,

0

then grad

Corollary 8.13 If n > 3, then S is positive and bounded below on H-1/2(r), i.e.,

(Si, Or ? CII

IIH-iIa(r)

for all',/r E H-112(x).

(8.33)

Proof. By Theorem7.6,S:H-1/2(I') -* H"2 (F) is Fredhoim with zero index, and since S is strictly positive-definite, ker S = (0}. Hence, S has a bounded inverse. Since S-1 is self-adjoint, and since the inclusion H1/2(r) c_ L2(r) is compact by Theorem 3.27, the result follows from Corollary 2.38 with A = S-1.

0 By modifying the boundary integral equation Silr = f and adding a side condition, we obtain a system that is always uniquely solvable, even when n = 2.

Lemma 8.14 Given any f E H1/2(r) and b E C, the system of equations

S*+a= f and (1,*)r=b, has a unique solution ,/r E H-1i2(r) and a E C.

Solvability for the Dirichlet Problem

263

Proof Introduce the Hilbert space H = H-1/2(1') x C, identify the dual space H* with H1"2(I') x C by writing ((i/r, a), (0, b))

0)r + ab,

and define a bounded linear operator A : H --* H* by

A(*, a) = (S* + a, (1, if) r). In this way, A is self-adjoint, and we now show that A has a bounded inverse.

Let So and L be as in Theorem 7.6, so that S = So + L with So invertible and L compact as operators from H-112(f) to H1/2(I'). We define Ao(,b, a) = (So,/r, a)

and

K(,f, a) = (a + L+/r, (l, i/r)r

- a),

H* comso that A = AO + K, with AO : H H* invertible, and K : H pact. By Theorem 2.26, A is invertible if the homogeneous system A (*, a) _ (0, 0) has only the trivial solution. In fact, if

S* + a =0 and

(1,

')r = 0,

then (Si/r, Or = (-a, *)r = -a(1, *)r = 0, so (r = 0 by Theorem 8.12,

and inturna= -S* = 0. Theorem 8.15 There exists a unique distribution,/req E

H-1/2

(F) such that S*eq

is constant on r, and (1, t/req)r = 1. If n > 3, then S*eq > 0.

Proof Let

9'eq be the solution of the system in Lemma 8.14 when f = 0 and b = 1. Thus, Slfeq = -a is constant on r, and by Theorem 8.12, if n > 3, then

-a = -a(1, ifeq)r = (S*eq, lkeq)r > 0. The distribution *eq is real-valued, and is called the equilibrium density for F. If n > 3, then the reciprocal of the positive constant S*eq is called the capacity of r, a quantity we denote by Capr, so that 1

Capr

= Sz/req

when n > 3.

This terminology has its origins in electrostatics: if an isolated conductor carries

a charge Q in equilibrium, so that the potential V is constant throughout the conductor, then the ratio Q/ V does not depend on Q, and is called the capacitance. Mutual repulsion causes all of the charge to lie on the boundary of the conductor, so (with appropriately normalised units) the electrostatic potential is

The Laplace Equation

264

SL 1/r, where i/r is the surface charge density. Thus, Q = ,fr l/r da and V = Si,

and in the case of a unit charge Q = 1, we have /r = *eq, so the capacitance is the reciprocal of S*eq. Now consider the case n = 2, and write S = S, to indicate the dependence on the choice of the parameter r in the fundamental solution from Theorem 8.1. The equilibrium density 1/req is the same for all r, but not so the constant Sr1/req. Since Srl/eq is not always positive, one introduces the logarithmic capacity,

Capr = e2'', so that 1

2n

1

log Capr

_

S1 *,q

when n = 2.

Notice that Sri//

Si* +

(127r, Or

log.1,r,

and hence S,.1/req = 2I log

r CaPr

In particular, Sr1leq = 0 if and only if r = Capr.

Theorem 8.16 Consider S,.: H-1/2(I') -3 H1/2(F) when n = 2. (i) The operator S,. is positive and bounded below on the whole of H-1/2(F)

if and only if r > Capr. (ii) The operator S,. has a bounded inverse if and only if r 0 Capr. Proof. For brevity, put ar = Sr1/req = (27r)-l log(r/Capr). Let Vr E H-1/2(F),

define *0 = * - (1, *)r*eq, and observe that

i/I = *o + (1,1)rieq,

(1, *o)r = 0

and Sr.

/ = Sr'Yo + a,.(1, ifr)r

Also, since (Sri/ro, *eq) _ (*o, Srl, eq)r = 0, we have

(Sri, *)r = (Sr*o, *o) r +a,(1/r. 1)r(1, if)r.

(8.34)

If r < Capr, then (Sr 1/req, +feq) r = ar < 0. To complete the proof of (i), suppose

that r > Capr, or equivalently, ar > 0. By Theorem 8.12, both terms on the right-hand side of (8.34) are non-negative, and the first is zero if and only if *o = 0. Thus, (Sr*, Or 0, with equality if and only if *o = 0 and (1, Or = 0, i.e., if and only if /r = 0. Hence, Sr is strictly positive-definite on

Solvability for the Dirichlet Problem

265

the whole of H-112(F). Arguing as in the proof of Corollary 8.13, we conclude that Sr is positive and bounded below on H-1/2(r).

Turning to part (ii), we note that if r = Capr, then Sr cannot be invertible because Sr lyeq = 0. Thus, suppose that r

Capr and S,. ly = 0. We have Sr ly0 = -ar(l, *)r, hence (S,.1/ro, fo)r = 0, and therefore ly0 = 0 by Theorem 8.12.

In turn, (1,1/r)r = 0 because ar 0 0, giving 1/r = 0. Thus, the homogeneous equation has only the trivial solution, and Sr is invertible.

In the case of the unit sphere r = Sn-1, it is clear from symmetry that 1/req takes the constant value I/ T,,, and in view of Theorems 8.4 and 8.5,

ifn = 2,

1

{(n-2)T,, ifn>3. Further properties of Capr are given in Exercises 8.10 and 8.11, and in the books of Hille [40, pp. 280-289] and Landkof [52]. We conclude this section with an interesting application of Theorem 2.36.

Theorem 8.17 If m 0 1, then 11,,, (Si -1) and f-l1 (Sn-1) are orthogonal to L2(Sn-1). Furthermore, the orthogonal direct sum each other as subspaces of ®O0 (Si-1) is dense in 7-f m=0 m L2(S"-1)

Proof. Recall from Theorems 8.4 and 8.5 that l,n (Sn-1) is an eigenspace of S. Hence, the orthogonality of 7-l n, (Sn-1) and Iii (Sn-1) follows at once from the

fact that S is self-adjoint. We may assume, by choosing r > 1 if n = 2, that S is strictly positive-definite on

H-112(Sn-1).

Since the inclusion

L2(Sn-1) c

L2(Sn-1) is compact H-1/2(Sn-1) is compact, the operator S: L2(Si-1) -+ with ker S = (0). Hence, the eigenfunctions of S span a dense subspace of L2(Si_1),

and to complete the proof it suffices to show that every eigenfunction of S is a spherical harmonic. Suppose for a contradiction that ly E L2(r) is a non-trivial solution of Sly =

µ1y on Si-1 for some (necessarily positive) µ, and that * 1 7-l,n(Si-1) for every m > 0. It follows from Theorem 7.2 that * E C°°(Si-1), so by Theorem 6.13 the single-layer potential u = SL * is C°O up to the boundary of the unit ball. If ly,,, E 7-1,,, (S-1) is as in part (i) of Theorem 8.8, then for 0 < p < 1,

f

- 1=1

00

SL*(pw)1/r(w)dw = 11 p,n m=1

and so, sending p f 1, we see that (S*, l tradiction.

f

,n(W)ly(co)do) = 0,

fJwI=1

0, implying, ly = 0, a con-

The Laplace Equation

266

Solvability for the Neumann Problem Solutions of the Neumann problem for the Laplacian are unique only modulo constants; more precisely, the following holds.

Theorem 8.18 A function u E H' (Q-) satisfies

Au = 0 on cZ-,

(8.35)

a-u=0 onr

if and only if u is constant on each component of 12-. Likewise, u e Hloc(S2+) satisfies

Au=0 avu=0 u(x) = if and only if u is constant on each component of S2+ and, when n > 3, is zero on the unbounded component of 52+.

Proof The first part of the theorem is a special case of Corollary 8.3. The exterior problem is handled in a similar fashion, by applying the first Green identity over S2p , and arguing as in the proof of Theorem 8.10.

Let Q, , ... , Op be the components (i.e., the maximal connected subsets) of S2-, and define

of =

1

on S2 ,

0

on S2- \ S2i ,

for 1 < j < p. Thus, the functions v1, ..., vi,, form a basis for the solution space of the homogeneous interior Neumann problem (8.35).

Theorem 8.19 Let f E H(S2-) and g E H-1/2(p). The interior Neumann problem

-Au = f

a,u=g

on Q-,

(8.36)

onF,

has a solution u E H1(S2-) if and only if the data f and g satisfy

Jsz,

f dx +

f

asp,

gda=0 for t<j
-

in which case u is unique modulo the subspace span {ul, ... , vP}.

(8.37)

Solvability for the Neumann Problem

267

Proof In the present case, the conditions in part (ii) of Theorem 4.10 reduce to

(vi, f)n- + (y vi, 8)r = 0 for 1 < j < p. Let

r denote the components of r, and define the function Xi on r

by

on I'i,

onF\ri, for 1 < j < q. The lack of uniqueness for the Neumann problem gives rise to a lack of uniqueness for the corresponding boundary integral equation; cf. Exercise 8.17.

Theorem 8.20 A function i E H112(r) satisfies R,lr = 0 on r if and only if 1/r is constant on each component of r. Thus, the functions X I, ... , Xy form a basis for ker R.

Proof. If Rill = 0, then the double-layer potential u = DL i/r satisfies

Au = 0

eau=0 u(x) = O(Ix12-") so u is constant on each component of R" \ F, and thus f = [u]r is constant on each component of r. To prove the converse, it suffices to observe that, by the third Green identity, 1

DL Xi

0

inside I'i, outside I 'j,

(8.38)

so RXi = 8 DL Xi = 0 on F. Corresponding to Theorem 8.12 for the operator S, we have the following result on the positivity of R; see also Exercise 8.17.

Theorem 8.21 The operator R : H112(r) -- H-1"2(I') satisfies,

(R*,O)r =

f `r grad DLi grad DL0dx for ,/r, 0 E H1/2(I')

(8.39)

The Laplace Equation

268 and

(Ri, Or ? cll*IIH'r(r) for* E H1/2(P) such that (Xi, Or = 0 for 1 < j < q. Proof. Let i/i, 0 E H'12(1'), and put u = DL i/i and v = DL ¢. As in the proof of Theorem 7.8, we find that for p sufficiently large,

(Ri, Or =

y+v

- y v)r

= (Dn+ (u, v) + fin- (u, v) +

f

da.

aB,,

Since gradu(x) = O(Ixl-") and v(x) = O(Ixi1-11) as IxI - oo, the integral over 8BP is 0(p-"), and we obtain (8.39) by sending p -+ oo. It follows at once from (8.39) that (R 4r, 0r > 0. Moreover, if(Ri/i, r =0, then grad u = 0 on R' \ T, so u is constant on each component of R" \ r, implying that * = [ulr is constant on each component of F. Hence, by Theorem 8.20, (Rill, ill) r = 0 implies Ri/i = 0. Therefore, the coercive, self-adjoint operator R is strictly positive-definite on the orthogonal complement of ker R, and we may appeal to part (iii) of Exercise 2.17.

Exercises 8.1

Let G (x, y) = G (x -y) be the fundamental solution given by Theorem 6.8

when n = 2 and P(4) = (2ir)21'I2. (i) Show that

G(x) =

1

2ir

1

log lxI -F

I"(1) -log27r 27r

- (2,r)2 J 1

2ir

log I sin BI dB.

(ii) Use the substitution 0 = 20 to show that 2n

I 8.2

Deduce (8.1) from

(L: 8.3

log I sin 0 I d9 = -27r log 2.

= Tf

re`dt) ePep"dp = 0

Show that if A E Rnxn is an orthogonal matrix, and if v(x) = u(Ax), then Lv(x) = (Du)(Ax). In particular, when u is harmonic, so is v.

Exercises 8.4

269

Show that if u(x) = w(p), where p = IxI, then

Au(x)dew+n-ldwp

dpe 8.5 8.6

dp \

dp /

T. Jr

(x yl1y) [.

(y)

- *(x)] da,.

Deduce from (8.12) that the numbers N(n, m) have the generating function 00

E N(n,

1+z

m)z,,,

Z)11-1

,,,=o

8.8

p'

dp

d

Show that T1 = -1 and T*+//eq = -*eq. Assume the hypotheses of Theorem 7.3, take P =-A, and let X E r. (i) Show that a:: (x) = -a [T+(x)]/T,,. (ii) Show that limEl.o TE 1(x) _ -1 - [a+ (x) - a-(x)] = -2a+ (x). (iii) Deduce that

T,l/(x) = -*(x) + 8.7

1

for IzI < 1.

Let b,,, = b,,, (n) be as in Theorem 8.7. Show that when n > 3, the Legendre polynomials have the generating function 00

Ebm(n)P.(n,t)zm = m =0

1,

1

(1 - 2tz + Z2)(n-2)/2

and by differentiating both sides with respect to z, derive the three-term recurrence

Po(t) = 1,

b1 P1(t) = (n - 2)t,

(m + 1)b,,,+1 P,n+1(t) - (2m + n - 2)t b,,, P,,, (t)

+(m + n - 3)b,,,-1'n-1 (t)=0 form > 1. Show likewise that when n = 2, 00

,,,=1

1m P»,(2, t)zm = log

1

1 - 2tz + ze

for IzI < 1

and

Po(2, t) = 1 ,

P1(2, t) = t,

Pm+1(2, t) - 2t P,,, (2, t) + Pm-1(2, t) = 0

form > 1.

The Laplace Equation

270

8.9

Recall the definition (8.29) of the inverse point xd with respect to the sphere a Ba, .

(i) Show that

_

axk

po) l2

axk

x;xk (s;k - 2IX11

CIXI

and

" axi ax;

E

4

=

PO

aXJ axk

1=1

Ixl

8jk'

(ii) Consider two curves x =x(t) and y = y(t) that intersect at a point a E II8n when t = 0. Show that

4dx dy

dxO

dy=

PO

dt

dt

(Ia)

dt

dt

when t = 0,

and deduce that the mapping x i--> xI is conformal, i.e., anglepreserving. (iii) Show that if E is a plane or sphere, then so is Ed. [Hint: consider the

equation a Ix 12 + b x + c = 0, where the coefficients a and c are scalars, but b is a vector.] (iv) Think of = xx as a system of orthogonal curvilinear coordinates for x = , and deduce that -2,q

Au =

ICI)

[(PO)2j,-4 au

n

j=j

Next, establish the identity

P, 2-n a

2n-4 au

a; (ICI)

(ICI)

(po) n 2

au a

-2a; a;

a2

+ a; (ICI)

ICI n-2

a2

ICI) PO

n-2

uA

n-2

a2

u

(Iii) PO

and finally conclude that

aupo)

n+2 n

ICI

1

n-2

a2

n+2

n

po

a; (ICI) u =(IXI)

where u° is the Kelvin transform (8.30).

1

a2ud

a;'

Exercises

271

8.10 Let n > 3, and consider the exterior Dirichlet problem

Au = 0

on T2+,

y+u=1

on I', u(x)=O(Ix12-n)

aslxl -+ oo.

Show that the unique solution is u = Capr SL *eq, and deduce that

Capr = -

f

8+ u dcr.

This result can sometimes be used to compute Capr; see Landkof [52, p. 165]. 8.11 Suppose that I' is a simple, closed curve in the complex z-plane, and let w = f (z) define a conformal mapping of S2+ U r onto I w I > 1. Since f is one-one on cZ+, it must have a simple pole at oo; see Markushevich [63, pp. 90-91]. Thus, there is a constant pr such that

f(z)= Z +O(1) asz -* oo. Pr

Moreover, we can assume that pr is real, because the domain I w I ? 1 is invariant under rotation, i.e., under multiplication by e`9 for any angle 0. The constant pr, is then known as the external conformal radius. (i) Show that the real-valued function u defined by f = eh'+", satisfies

Au =0

on Q+,

y+u = 0 u(z) = log

on I', IZI

Pr

+0(l) as z - oo.

(ii) Hence show that

u = log

r

Capr

- 2n SL *eq,

and deduce that pr = Capr. (iii) Suppose that a > b > 0, and let r be the ellipse

Iz-cl+lz+cl=2a, where c= a2-b2. Thus, a and b are the semimajor and semiminor axes, respectively,

The Laplace Equation

272

and c/a is the eccentricity. Verify that the formula

z=

a+b 2

w+

a-b 2w

defines a conformal mapping w l-4 z of the region I w > 1 onto 52+, and deduce that Capr = 1(a + b). For further examples, see Landkof [52, p. 172]. 8.12 Prove the (crude) bound

Capr

ifn = 2,

diam(1') (n - 2)T,,

_-

diam(I')"-2

if n > 3.

8.13 For any a > 0, we write ar = {ax : x E 17). By expressing the equilibrium density for al' in terms of the equilibrium density for r, show that

ifn = 2,

a Capr Caper = t&3_2Capr

if n > 3.

8.14 Derive the following variational characterisation of the capacity: min (Si, ,/,EH-'12(r). (l.*)r=l

Or = (Sieq, *eq)r

12n

log

Cap,

r

Capr

ifn = 2,

ifn>3.

LI

[Hint: if (1, *)r = 1, then fr = *o + *eq with (1, fo)r = 0.] 8.15 Let Q+ = C \ [-1, 1]. The formula

- 1Iw+w Z-2 1

defines a conformal mapping w H z of the region I w I> 1 onto Q+. [This mapping is a degenerate case of the one in Exercise 8.11 (iii) above.] Define

fo(z) = log

wr

and f,n(Z) =

2m w'"

form > 1,

and let un, (x, y) = Re fm (z),

where z = x + iy.

Exercises

(i) Show that w = z + ru

273

z2 - 1, and that

z2 - 1 = ::+-i

fl - x2

for-1 <x < 1.

(ii) Hence show that if -1 < x < 1, then 8:':U",

(x, 0) =

vlimp ifmz) T1

=

1 -x2

x

1

when in = 0,

2(x±i 1 -x2 -'n

when m > 1.

(iii) Let r = (-1, 1), and show that u,,, = SL 1/r,,,, where Vr,,, = -[8vu,,, Jr is given by

fo()

2

and d *,,,(x) =

1 - xz

P. (2-, x) 1

form > 1.

xz

Here, P(2, x) is the Chebyshev polynomial (8.24). (iv) Deduce that for x E r,

r

1

2rrlog\ Ix-YI/ (v) Assume r

if m = 0,

2 log 2r

Pm (2, y)

1-y2 dy

1

l)m(2,X)

if m > 1.

Z, and express the solution of Si/ = f as a series

involving the Fourier-Chebyshev coefficients of f . 8.16 Let c2+, r and w H z be as in Exercise 8.15, but now put

um(x, y) = Re(2iwm+i

)

form > 1.

(i) Show that um = DLi/r,,,, where 1/r,,, = [u,,,Jr is given by *.(x) = Q,,, (x) VI-1- -

x2 and Qm (cos 8) =

sin(m + 1)0' sin 8

(The function Q,,, is the mth Chebyshev polynomial of the second kind.) (ii) Deduce that f.p.

27r EyO

Jc-,,l)\B,(x) (x - y)

2

Qm(Y)

1 -y2dy =

m-

Q,n(x)

2

for-1<x<1. (iii) Hence obtain an explicit series solution for the equation RI/r = f .

The Laplace Equation

274

8.17 Let f E

and g E H-1/2(1'), and put

h=Z(g-T"g)-a1gf, so that Ri/r = h ig the boundary integral equation corresponding to the interior Neumann problem (8.36) for the Laplacian; see Theorem 7.7. Define an operator

R, : H1/2(F) - H-1'2(r) by q

R1i/r = Ri/i +>2(X,, *)rXj, i=1

are as in Theorem 8.20. (i) Show that R, is self-adjoint, and that

where X1,

, Xq

(R1r, i)r ? cIII/FI12hIp()

for all *E H1/2(1').

(ii) Show that TXJ = -Xj, and deduce that

(Xi,h)r=±

f

fdx+J gdQ fort < j
si; nsz-

where S2j is the bounded, simply connected domain enclosed by l',, with the + (-) case occurring when v points out of (into) S2j. (iii) Explain why 0+ has q - p bounded components (and one unbounded component).

(iv) Suppose q = p = 1. Show that the unique solution * of R I* = h satisfies Ri/r = h if and only if the data f and g satisfy

fn -

fdx+

r

gdQ=0,

the necessary and sufficient condition for the existence of a solution to (8.36).

(v) Now suppose q = 2 and p = 1, with r1 and f'2 labelled so that they are the boundaries of the unbounded and bounded componenents of Q+, respectively. Show that the result in (iv) is still valid provided either f = 0 and g I r, = 0, or g 1 r2 = 0. How can we proceed for general f and g? 8.18 Let S2- be the lower half space {x E R" : x" < 0) so that I' = R't-1, and let t/r, -0 E

D(Rn-1)

Exercises

275

(i) Show that the double-layer potential for the Laplacian maybe written as DL X/r

= -(a,, G) * (* 0 8).

(ii) Deduce that

a,DL1/r=1/r®S-}-G*(,L'Vr®S), where A' _ E"-, 8? is the Laplacian in

IR

-1

(iii) Hence derive the identities n-1

R* = -SD'*

and

(Ri, Or = >(Saj*, ajo)r. i=1

8.19 Show that in the case of the Laplacian, the functions ms and mR of Exercise 7.8 are given by

ms(')=

1

4n 1t'I

and mR(')=irI'I

8.20 Let r = r0 U 11 U r1 be a Lipschitz dissection of r, so that F0 is an (oriented) open surface, and define So ' = (S*)Iro and R0i/r = (R*)Iro if supp c/r c r0. (i) Show So : H-1J2(F0) - H1/2(ro) and R0 : H112(ro) -+ H-1/2(ro) are Fredholm operators with index zero. H-1/2(ro) (ii) Show that there exists a unique distribution /r q E such is constant on ro, and (1, *q) ro = 1. We use *,,0 to define that Capro, the capacity of r0, in the same way as for a closed surface. (iii) Prove for n > 3 that So is positive and bounded below on H1/2 (2r0). 1/ (F) (iv) Let n = 2. Prove that S0 is positive and bounded below on H if and only if r > Capro, and that So : H-1/2(r0) --* H1/2(Fo) is invertible if and only if r 54 Capro. -1/2 (v) Prove that R0 is positive and bounded below on H(F0). 8.21 Show that the logarithmic capacity of a line segment equals one-quarter of its length. [Hint: use Exercises 8.13 and 8.15.] 8.22 As in Theorem 7.10, the interior, mixed problem for the Laplacian leads to a 2 x 2 system of boundary integral equations of the form Aib = h, where _ ( SDD -2TDN A

-

L 2 TND

RNN

Show that if S2- is connected, and if r > Caprp in case n = 2, then A : H - H* is positive and bounded below on the space

H = H-1/2(FD) x H1/2(rN)

9

The Helmholtz Equation

Consider the scalar wave equation, 82U 8t2

-c2LU=0.

(9.1)

We obtain a time-harmonic solution U(x, t) = Re[e-'aru(x)] if the spacedependent part u satisfies the Helmholtz equation,

-Du - k2u = 0,

(9.2)

with k = A/c. In this setting, the wave number k is real, but in the theory that follows we shall allow the coefficient k2 to be any non-zero complex number. It is convenient to assume, without loss of generality, that

0 < arg k «.

(9.3)

This chapter begins by showing how separation of variables leads to Bessel's equation, and by deriving a fundamental solution G(x, y) = G(x - y). (The presence of the lower-order term in the Helmholtz equation means that we cannot apply Theorem 6.8 to obtain G.) Next, we discuss the well-known Sommerfeld radiation condition, and proceed to establish an existence and uniqueness theorem for the exterior problem. The final section of the chapter derives an integral identity that connects the sesquilinear forms associated with the boundary operators S and R. The books of Colton and Kress [12], [13] give more detailed treatments of the Helmholtz equation, emphasising integral equations of the second kind. The sesquilinear form associated with the Helmholtz operator P = -A - k2 is

(Dn(u,v)=J

J

n 276

Separation of Variables

277

and since P* = -,L - k2,

au.

13"u = B"u = a"u =

av

Obviously, P is strongly elliptic. Also, P is self-adjoint if and only if k is real.

Separation of Variables We begin our investigation of the Helmholtz equation (9.2) by seeking solutions of the form

u(x) = f (kp)i/r(co) where x = pw and p = Ix1.

(9.4)

It will be convenient to introduce the Beltrami operator, As -i, a differential operator on the unit sphere defined by

where j (x) = i/r (co) for x 0 0.

As,,-,* = (ai)IS-

Thus, i%r is the extension of i/r to a homogeneous function of degree 0.

Lemma 9.1 If u has the form (9.4), and if z = kp, then

Du(x) = k2( f"(z)i(w) +

1

f

f,(z)i(w) + 1 (z)As-(w)). Z2

Z

Proof Since ap/axe = x3/p, we find that XJ2

p)2f"(z)+kp2

a,u(x) =

p

+ 2kpr

f'(z) I(x)

f(z)a; (x).

Being homogeneous of degree 0, the function j satisfies Ej=1 xj aj >%r (x) = 0, so

Du(x) = (k2f"(z) + k Finally, because A

n

p

1 f'(z))i(x) + f (z)Oi(x)

is homogeneous of degree -2,

fi(x) = p-2A(w) = giving the desired formula for Au(x).

k2 z2

278

The Helmholtz Equation

We now restrict our attention to the case when * is a surface spherical harmonic, because * is then an eigenfunction of the Beltrami operator. Lemma 9.2 If 1/r E Nm (Sn-1), then - As,,-i * = m (m + n - 2) *. Proof Let v/r = u is., for a solid spherical harmonic u E 7-lm (RI). Since u (x) = p'"* (co), we see that u has the form (9.4) with k = 1 and f (z) = z"'. Applying Lemma 9.1, it follows that Au (x) = pm-2 [m (m + n - 2) * (to) + As,-, * (co)J, which is identically zero.

Lemmas 9.1 and 9.2 show that when * E 7-1m(Sn-1), the function (9.4) is a solution of the Helmholtz equation (9.2) if and only if f is a solution of

f"(z)+n

lf'(z)+I1-m(m Z2 -2)) f(z)=0.

z

(9.5)

This ordinary differential equation can be transformed, by putting

g(z) =

zQhi2,-1 f(z),

into Bessel's equation of order µ,

g"(z) + z g'(z) +

C1 -

)(z) = 0,

(9.6)

with n µ=m+2-1.

Let J, denote the usual Bessel function of the first kind of order µ, which has the series representation (-1)P(z/2)µ+2P

J (z) _ P=O

P ! F (µ + p + 1)

for I arg z l «

(9.7)

The Bessel function of the second kind, Yµ, is defined by YN, (z) =

J,, (z) cos rr µ - J-4 (z) sin rrµ

for I arg i l < 7r,

if µ 0 7L,

and by Y,,, (z) = 4lim Y. (z)

for I arg z I < 7r,

if m E Z.

The functions J. and YN, form a basis for the solution space of Bessel's

Separation of Variables

279

equation (9.6), so the functions

j. (z) =j m (n, Z) =

rr Jm+(n/2)-1 (z) 2

Z(n/2)-1

and

Ym (Z) = Ym (n+ z)

= Vf7r2 Y,n+(n/2)-1(z) Z(n/2)-1

form a basis for the solution space of the original differential equation (9.5). If n = 3, then j,,, and y,,, are known as spherical Bessel functions.

Lemma 9.3 Let u have the form (9.4), where 1 E Hn,

(S"-1)

(i) If f (z) = j," (n, z), then -Au - k2u = 0 on R". (ii) If f (z) = y,,, (n, z), then -Au - k2u = 0 on Ilk" \ 10). Proof The preceding argument shows that in each case, u is a solution of the Helmholtz equation on R" \ 101. The series (9.7) shows that J.(z)/z"` is an entire function of z2, and therefore the same is true for jm(n, z)/z"'. Since pm*(w) is a homogeneous polynomial of degree m in x, it follows that if f = j,,,, then u is CO° on W, proving (i).

0 As z -* 0, the singular behaviour of the non-negative integer- and halfinteger-order Bessel functions of the second kind is given by

?n [-r'(l) + log(z/2)][1

Yo(z) _

O(z2)] + O(z2),

and, for any integer m > 1, Yµ (z) =

-r(µ) 7r(z/2)

[1 + O(Z2)

11

-2 ( m

/2)'7

z

1

1

og(z/2) [ + O (z2)l 1

i f /.c = m,

if.t=m-2,

to

where each O(z2) term is an entire function of z2; see [1, p. 360]. We are therefore able to show the following.

Theorem 9.4 For any constant a E C, a fundamental solution G(x, y) _ G(x - y) for the Helmholtz operator -A - k2 on R" is given by G(x) =

2(2.,7r)("-1)/2

[-Yo(n, klxI) + ajo(n, klxl)].

(9.8)

The Helmholtz Equation

280

If n = 3, then this expression reduces to

cos(klxl) +a sin(klxl)

G(x)

(9.9)

47rIx1

Proof. By (8.1), if n > 3 and µ = (n/2) - 1, then

I'(µ) _ F(1 + p)//1 _ 7r2-u

7r2-9

1'(n/2) (n - 2)7r2-n/2

27rn12/Tn

2(27r)(n-I)/2

(n - 2)Tn

(n - 2)7r2-n/2

2 7r

Thus, if Go(x - y) denotes the fundamental solution for the Laplacian given in Theorem 8.1, then for n > 2, kn-2 2(2n)(n-l)/2Yo(n,

kl xl) = Go(x)[1 + f (x)] + g(x) as Ixl -+ 0,

where f (x) = O (Ix 12) and

const + O(Ixl2)

g(x) =

0

const x log(klxl/2) [1 + O(Ix12)]

for n = 2, for odd n > 2, for even n > 2;

again, the O (IX 12) terms are analytic functions of Ix 12. To prove that G is a fundamental solution, we let w = S + (A + k2)G and show that w = 0 on Rn. In fact, since Ho(S"-I) consists of the constant functions, Theorem 9.3 implies that w is independent of the coefficient a, and that w = 0 on Rn \ {0}. Thus,

it suffices to show that w is locally integrable on R. We know already that -OGA = S, so w = k2GA + (A + k2)(GA f + g), therefore, as lxI -* 0, O(log Ixl)

w(x) =

{

O(Ixl2-n)

if n = 2, if n > 3,

and the result for a general n follows. In the particular case n = 3, we can use Exercise 9.1.

The Sommerfeld Radiation Condition When dealing with exterior problems for the Helmholtz equation, it is convenient to introduce the Hankel functions of the first and second kind, Hu1)(z) = JN,(z) +iYN,(z)

and

Hµ)(z) = Jµ(z) - iY,.(z),

The Sommerfeld Radiation Condition

281

which form an alternative basis for the solution space of Bessel's equation. We also put h

(z) = Jm (z) + 1Ym (z)

and

(Z) = Jm (Z) - lYm (Z),

writing h(1) (n, z) and h(2) (n, z) when it is desirable to indicate the dimension n explicitly. If n = 3, then and h,(nt) and h,(n2) are known as spherical Hankel

functions.

From the standard asymptotic expansions for the Bessel functions - see Abramowitz and Stegun [1, p. 364] or Gradshteyn and Ryzhik [29, pp. 961962] - we find that [e'tz-(2'+"- 1).,/4)] +

1

h,(11) (Z) =

z

OC

(n-1)/2

1)],

{\

Z1

(9.10) Z

(n-1)/2 Ce-i[z-(2m+n-1)n/4)] + O Z

hm2) (z) =

L

1\\

J,

J

as z - oo with -rr < arg z < 7r. By Lemma 9.3, the function u(x) = hI')(kp)i/r(w)

forx = pw, *

E'H.(Sn-1)

(9.11)

is a solution of the Helmholtz equation, and the corresponding time-harmonic solution of the wave equation (9.1) satisfies Re

[e-tar h(;) (kp)

* (w)}

= pcos[kp - At - (2m + n - 1)nr/4] + O(p-(n+1)/2) as p - * oo. Physically, this solution is an outgoing or radiating wave; if h ;2j is used in place of h;,;), then we obtain an incoming wave.

Definition 9.5 Write x = pcw with p = I x I and co E Sn', and let u(x) be a solution of the Helmholtz equation for p sufficiently large. We call u a radiating solution if it satisfies the Sommerfeld radiation condition

um

au

p(n-1)/2

C

uniformly in co.

p

- iku) = 0,

The Helmholtz Equation

282

The derivatives of h;,;) and h(2) have the asymptotic behaviour

d l) dhn,z

=

_

1

z (n-1)/2

-i z(n-l)/2

dz

2nn-1),r/4)1

[e'

+

o\(

i, (9.12)

[e_2m+n1)a/4)1 +

p(n-l)/2 (au ap

_ iku) = o 1 ),

\p

/

(9.13)

and is therefore a radiating solution. Also, by taking a = i in (9.8), we obtain a radiating fundamental solution, kn-2

klxl),

G(x) =

(9.14)

and, as a special case, eikI.t

G(x) =

47rIxI

when n = 3.

(9.15)

Recalling our assumption (9.3), we note that if Im k > 0 then G (x) has exponential decay at infinity. The following theorem reveals the connection between Definition 9.5 and our earlier treatment of radiation conditions for general elliptic equations; recall the definition of the operator M given in Lemma 7.11. Theorem 9.6 Let u be a solution of the exterior Helmholtz equation

-Au-k2u=0 onQ+, and suppose that M is defined using the radiating fundamental solution (9.14).

(i) If Mu = 0, then u satisfies (9.13). (ii) If u satisfies lim

P-'a% aBr,

then Mu = 0.

au

-ap- iku

2

dcr = 0,

(9.16)

The Sommerfeld Radiation Condition

283

Hence, the requirement Mu = 0 is equivalent to the Sommerfeld radiation condition.

Proof. By enlarging S2- if necessary, we can assume that u is C°O on SZ+. By

Theorem 7.12, if Mu = 0, then u = DL y+u - SL 8v u on Q+, so part (i) follows from Exercise 9.4. Assume now that u satisfies (9.16). We claim that

Iul2dcr=O(1) asp-+ oo.

(9.17)

LBp

In fact,

-au ap

2

2

8u

iku

I

ap

+ IkI2IU12 +2Im1

au

kavul,

and by applying the first Green identity over the bounded domain SZp = S2+ n Bp, we see that

f(gradu12-k21uI2)dx=fBpavuda- f a-vuda.

(9.18)

(In the first integral on the right, v is the outward unit normal to S2p+, but in the second integral v is the inward unit normal.) Multiplying (9.18) by k, and taking the imaginary part, we obtain

- f Im(kaa u) da = Im(k) -

Ik12Iu12) dx

JBPI

m(kavu) da

and so

'

2

Im(k) f12 (Igradu12 + Ik12Iu12) dx + j 2

- f Iml k a 4 uJ da

as p

\I aU I

+

Ik121u12 I dQ

(9.19)

oo.

The claim (9.17) now follows from our assumptions that k # 0 and Im k > 0. To complete the proof of (ii), we simply write

Mu(x) =

G(x,

Ja BPp

-JB

A

iku(y)] day

[a,,. G(x, y) - ikG(x, y)]u(y) day

284

The Helmholtz Equation

for p sufficiently large, and then apply the Cauchy-Schwarz inequality, noting that the radiating fundamental solution G (x, y) = G (x - y) satisfies

f IG(x, Y) 12 day < C sP

JaBP

Ix -

yl-(n-u day .5 C

and

f Ia,i,yG(x, y) - ikG(x, Y)I2 day < C J aP

Ix -

YI-(n+1) dory

< Cp-'-

aBP

0 We are now in a position to give an expansion of the fundamental solution in spherical harmonics or Legendre polynomials.

Theorem 9.7 For m > 0, let {*n,p : 1 < p < N(n, m)} be an orthonormal basis for The radiating fundamental solution G(x, y) = G(x - y) given by (9.14) has the expansion oo N(n,m)

G(x, y)

=ikn-2

hm)(klxl)srnep(xllxl)jm(k!Y!)/mp(Y/IYI) M=O p=1

ikn-2

T.

00

N (n, m) h(,) (k l x l)jm (kl y l) P, (n, cos 0) m=0

forlxI>IYI>0, where

cos 8 = IxIIYI

Proof Let

E 1-1,,, (Si-1), and put

u(y) = j,n(kp)i/r(co) and v(y) = h;;)(kp)*(w)

for y = pa.

By Lemma 9.3, we have -Au - k2u = 0 on W, and -Av - k2v = 0 on R' \ {0). Hence, Mu = u by Exercise 7.5, and therefore by Theorem 7.12,

f

[a",yG(x, y)u(y) - G(x,

day = 0 for IxI > p,

(9.20)

aP

whereas My = 0 by Theorem 9.6, so

f [a,,,yG(x y)v(y) - G(x, aP

day = v(x)

for lxl > p.

(9.21)

The Sommerfeld Radiation Condition

285

It follows from Exercise 9.3 that cu

m) = dzt m z

j,n(z)ddz

x (9.20) - j,,,(kp) x (9.21) gives the equation

so the combination

f

_

for lxl > p, P

or equivalently,

ik,=-2j».(kp)h;)(klxl)*(x/Ixl)

G(x, pW)/(w) da) =

for lxl > p.

By Theorem 8.17, we have 00 N(n.m)

G(x, y) = G(x, pw) = E E f m=o p=1

.

, G(x, prl)*,np(n) dri *,np(o)),

implying the first expansion, and the second then follows by Corollary C.2. However, so far we have proved only convergence in the sense of It is easy to see from the definition of the Legendre polynomial P," (n, t) immediately following Lemma 8.6 that

L2(S"-I).

I P. (n, t) I < 1

for -1 < t < 1,

so the mth term in the second expansion is bounded by N(n, m)Ih(;)(klxl)j,,, (k I y 1)1. Using the standard large-argument approximations [ 1, p. 365),

Jµ(z) = Yp (z)

(?-)[1+o1] µ \ ez

and

} [I + 0(1)] asµ -+ 00

(with fixed z), we find after some calculation that

iy,n(klxl)jm(klyl) [1 +o(1)]

-i

(k1

In 1)

2m+n-2(klxl)

[I + 0(1)]

asm -±oo.

Since (8.14) shows that N(n, m) = O(m"-2) as in -+ oo with n fixed, the expansions converge pointwise for Ix I > I y 1.

286

The Helmholtz Equation

Uniqueness and Existence of Solutions Theorems 4.12 and 8.2 imply that for each Lipschitz dissection r = I'D U 11 U rN there exist interior eigenvalues 0 < Al < A2 < , and corresponding interior eigenfunctions 01, -02, ... in H1 (S2-), satisfying

-L\/b1 =,,joj on S2-,

Y-0j = 0

on 1'D,

aOj=0

On PN,

with O j not identically zero. Therefore, by Theorem 4.10, the interior problem

-Du -k2u = f

on n-,

Y -U = gD

on FD,

au u = gN

on rN,

(9.22)

has a unique solution u E H1(S2-) for each f E H-1(S2-), gD E H1/2(rD) and gN E H-1/2(FN) if and only if k2 is not an interior eigenvalue. Otherwise, a solution exists if and only if the data satisfy

(4j, Do- + (Y-0j, gN)rN = (a, 4'j, gD)rp for all j such that Aj = k2. Notice that since X j > 0, if Im k > 0 then k2 cannot be an interior eigenvalue, and so (9.22) is uniquely solvable. The following result of Rellich [86] will help us to prove uniqueness for exterior problems.

Lemma 9.8 For any real wave number k > 0, if

-Au-k2u=0 on R"\BPo and if lim

P-+oo

f

I u (x) I2 do. = 0,

(9.23)

xI=P

then u = 0 on R" \ BPo. Proof. Let (1//mp : 1 < p < N(n, m)) be an orthonormal basis for Theorem 6.4 shows that u (x) is C°° for Ix I > po, so

7-lm(S"-1)

oo N(n,m)

u(x) = E E fmp(kP)hI/mp(co) M=O p=1

for x = pw, p > po and w E S)'-

Uniqueness and Existence of Solutions

287

where

fmp(t) = J u(k-1 tw)rmp(w) dw for t > kpp. n-I

The sum converges in L2(Sn-1), and 00 N(n,m)

Iu(x)I2 dax Ixl=p

=j

Iu(Aw)I2An-1

n -i

dw = E

An-1

Ifmp(kP)I2.

M=O P=1

Since u satisfies the Helmholtz equation, the function fmp is a solution of (9.5), and hence fmp(t) = amlphin)(t) + amphm)(t) for some constants amp and am2p. By (9.10),

A"-1I fmp(kP)I2 =

lan pe2i(kp-(2m+n-1)a/4] +amPl2

+ O(A-1),

so the assumption (9.23) implies that a npeie +am2p = 0 for all real 0. Therefore, amp = a, ;,p = 0, which means that fn p is identically zero. Lemma 9.9 Suppose that u E H1oc (S2+) is a radiating solution of the Helmholtz equation, i.e., suppose

-Au-k2u=0 on Q+ and

lim A(n-1)l2 au

- iku) = 0.

(9.24)

A

If

Im(k f (8v u)u de) > 0, r

then u = 0 on 0+. Proof If Im k > 0, then we see from (9.19) that fsi+ I u (x) 12 dx 0 as p oo, and thus u must be identically zero on 52+. If Im k = 0, then we can apply Lemma 9.8 because (9.19) shows that f xl=p I u (x) I2 d cx -* 0 as p oo, and k > 0 by our assumption (9.3). The desired uniqueness theorem follows at once.

288

The Helmholtz Equation

Theorem 9.10 I fu E H11 (S2+) is a solution of the homogeneous exterior mixed problem

-Au - k2u = 0 y+u = 0

on 52+,

on I'D,

a+u=0 onrN, and if u satisfies the Sommerfeld radiation condition (9.24), then u = 0 on

W.

It is now possible to deduce existence results for exterior problems using boundary integral equations. For brevity, we treat only the pure Dirichlet problem; but see also Exercise 9.5. Theorem 9.11 If f E H-' (S2+) has compact support, and if g E H 1/2 (I'), then the exterior Dirichlet problem for the Helmholtz equation,

-Au - k2u = f on 52+, y+u = g

on r,

has a unique radiating solution u E HioC(SZ+).

Proof. We have already proved uniqueness. By Theorems 7.15 and 9.6, a solution exists if and only if there exists i/r E H-1/2(r) satisfying

Si/r = y9 f - 2(g - Tg) on F.

(9.25)

(In the usual way, to define 9f we view f as a distribution on Rwith supp f c 52+.) Theorem 7.6 shows that the Fredholm alternative is valid for this boundary

integral equation, and by Theorem 7.5 the set ker S* consists of all functions of the form a. v where v E H' (S2-) is a solution of the interior homogeneous adjoint problem

-Lv-k2v=0 on Q-, y-v=0 on T. Using (7.5) and the second Green identity, we find that for all such v,

YGf - 2(g - Tg))r =

Y (Gf +DLg))r

= (y v, a. (9f +DLg))r _((_A_ k2)v, gf + DLg)o_ + (v, (-A - k2) (g f + DL g)) n_ .

A Boundary Integral Identity

289

Each of the three terms on the right vanishes, because y-v = 0 on F, (-A k2)v = O on S2-, and (-t - k2)(G f +DL g) = f = 0 on S2-. Thus, * exists, as required.

We remark that the solution fr of the boundary integral equation (9.25) is unique if and only if k2 is not an interior Dirichlet eigenvalue for -A.

A Boundary Integral Identity In this section, we derive a remarkable identity connecting the hypersingular boundary integral operator R with the weakly singular operator S, associated with the Helmholtz equation in 1[83. This identity, together with analogous ones for other elliptic equations, was introduced by Nedelec [75] as a way of avoiding the evaluation of hypersingular integrals in Galerkin boundary element methods

involving R. It will be convenient in what follows to work with the bilinear instead of the sesquilinear form form For any scalar test function w E D(I83) and any vector-valued test function W E D(I83)3, we have the identities

div(uW) = (grad u) W + u div W, div(wF) = F F. grad w + (div F)w,

div(F x W) _ (curl F) W - F curl W, if, say, u : JR3 -* C and F : R3 -± C3 are C'. Consequently, the divergence theorem implies that

(grad u, W) = -

J

u div W dx,

arty

(div F, w) = -

Ja3

F grad w dx,

(curl F, W) = f F curl W dx,

Jrt;

so for distributions u E D*(R3) and F E D* (R3)3,

(gradu, W) = -(u, divW), (div F, w) = - (F, grad w), (curl F, W) = (F, curl W). Given a scalar test function

E D(I83), we shall write Or = Ojr, and define

290

The Helmholtz Equation

yt and at by

(Or, fr)r and (8v0r,

(YtOr,

for * E D(R3);

(Or, 8v5v )r

cf. (6.14). The following identities hold in the sense of distributions.

Lemma 9.12 If 0, * E D(R3), then div y`(Orv)

-a'. Or and curl yt(Orv)

-y`(v x y grad 0)

on R3.

Proof We have (div YL(Orv), w) = -(Yt(Orv), grad w) = -(Orv, y grad w) r

_ -(Or, avw)r = (-8.'Or, w), which proves the first part of the lemma. Next,

(curl y`(4rv), W) = (ryt(Orv), curl W) = (Or v, y curl W)r

=

Jr

v y (0 curl W) da,

so by the divergence theorem,

(curl y`(Orv), W) = F

div(cb curl W) dx. JL

From the identities

div (0 curl W) = grad 0 curl W + 0 div curl W = grad

curl W + 0

and

div (grad 0 x W) = (curl grad ) W - grad

curl W = 0 - grad ¢ curl W,

we have div(O curl W) = -div(grad 0 x W). Thus,

(curl y`(Orv), W) = f

Jsrzt

_- J

div(grad 0 x W) dx

r

which proves the second part of the lemma.

fr

v

(grad o x W) da

A Boundary Integral Identity

291

Now fix a 0 E D(R3), and define

u = DL Or on R3

and Ft = grad u} on

using, in the double-layer potential, any fundamental solution of the form (9.9). We also construct a locally integrable vector field F : R3 _+ C3 by putting

F = I F+

F-

on 52+,

on S2-.

In this way, the support of the distribution F - grad u is a subset of 1'. Two further technical lemmas are required. Lemma 9.13 As distributions on R3,

u = -div SL(Or v),

div F = -k2u,

grad u = F + y`(Or v),

curl F = yt(v x y grad 0).

Proof. Using Lemma 9.12, we find that since 8j commutes with the convolution operator G,

u = DL Or = 9(8vOr) _ c(-div Y`(Or v))

= -divc(y`(Orv)) _ -divSL(Orv). Next, since

(F-grad u,W) =J3(F.W+udivW)dx and

f(F. W+udivW)dx =f } f div(u±W)dx = F zt

r

v y}(uW)da,

it follows by the jump relation for the double-layer potential, [u] r = [DL 'r ] r = Or, that

(F-gradu, W) =- fr v -(cbrYW)do = -(Orv,YW)r = (-Y`(Orv),W), so grad u = F + y`(tr v). Another application of Lemma 9.12 gives

div F = div[grad u - y`(Orv)] = Au + 8tbr,

292

The Helmholtz Equation

and since -Au - k2u = (-A - k2)GB,t,¢r = a,`,Or, we see that div F = -k2u. Finally, since curl grad u = 0, the second part of Lemma 9.12 implies that

curl F = curl[gradu - yt(Orv)] = yt(v x y grad 0). Lemma 9.14 The vector potential

A = g(curl F) = SL(v x y grad 0) satisfies

div A = 0 and curl A = F - k2 SL(Orv)

on R3.

Proof Since div curl F=O, we have div A = div g (curl F) = 9 (div curl F) 0, whereas since

curl curl F = grad div F - A F = grad(-k2u) -AF

= -k2[F + Yt(cbrv)] -AF = (-OF - k2F) - k2yt(Orv), we have

(curl A, W) = (curl g(curl F), W) = (9 (curl curl F), W)

= ((-A - k2) F - k2yt(Or v), G W) = (F, (-Lx - k2)gW) - (k2c(YtOrv), W)

= (F - k2 SL(4,rv), W), as claimed.

We can now prove the main result for this section; see also Exercises 8.18 and 9.6.

Theorem 9.15 Let G (x, y) = G (x - y) where G is given by (9.9). If 0, i/r E D(R3), then

(ROr, +/rr)r = (S(v x Y grad-0), v x y grad *) r - k2(S(Orv), frv)r Proof. Using the definition of R and the first Green identity, we see that

(Ror, fr)r = (-av u, fr)r = +

Jet

(grad u . grad * - k2ui/i) dx,

Exercises

293

and on 01 we have

grad u grad aJr - k2ui/r = [curl A + k2 SL(Orv)] grad * + k2 div SL(4rv)* = curl A grad * + k2 { SL(0r v) grad + [div SL(Or v)]i/r }

= div[A x grad 1/r + k2 SL(¢rv)*]. Hence, the divergence theorem gives

(Ror, *r)r = - J v y[A x grad

dQ

r _ (yA, v x y grad *)r - k2(S(Orv),1/r'rv)r,

0

and finally y A = S(v x y grad 0).

Exercises 9.1 Show from the series definitions of JI12 (z) and Y112 (z) that the zero-order spherical Bessel functions may be written as

Jo(3, z) _

sin z z

and

yo (3, z) _

-cos z z

9.2 Prove Theorem 9.4 by showing that as Ix I -+ 0,

a;G(x) = a;Go(x) + +

I O(Ixl log lxi) O(Ix13-n)

if n = 2, if n > 3,

and then arguing as in the proof of Theorem 8.1. 9.3 Show that if f and f2 are solutions of the differential equation (9.5), then their Wronskian

W = W (fl, f2) _

fi

f2

fl'

f2

is a solution of

dW +n-1W=0. dz

z

Deduce that W = const/z"-', and in particular W

(h(,'), (2)) n, h n?

= -2i

Z"-I

[Hint: use (9.10) and (9.12).]

and W Um, ym) _

294

The Helmholtz Equation

9.4 Let G(x, y) = G(x - y) be the radiating fundamental solution given by (9.14), and write x = pco with p = Ix I and w E

Sn-1

(i) Show that Ix - yI = IxI - w y + O(IxI-1) as IxI

oo, uniformly

foryEF. (ii) Use (9.10) and (9.12) to show that k(n-3)/2e-i(n-3)Yr/4

SL 1Jr(x) =

2(27r)(n-1)/2

x

eikp

p(n-1)/2

(f(f

e-ikmy*(y)day+O(p-I)

and

k(n-3)/2e-i(n-3)n/4 DL 11f (x) =

2(2.7r)(':-1)/2

xC

eikp

p(n-1)/2

f (a,,ve-ikw,y)i(y)

r

day + O(p-1)l

as Ix I -* oo, uniformly in w. (iii) Show that SL f and DL f satisfy the Sommerfeld radiation condition. (iv) Deduce that if u E Him (Q+) is a radiating solution of the -Au -k2 u = 0 on 52+, then there exists a unique function uc,. E CO°(Si-I) such that eikp

p(n-1)/2 [uoo(w) + O(p-1)]

as p -+ oo,

uniformly in w. The function u,,. is called the far field pattern of u. [Hint: use Theorem 7.12.] (v) Show that if u... = 0 on Sn-1, then u = 0 on Sa+. [Hint: use Lemma 9.8.]

9.5 Show that if f E H-I (S2+) has compact support, and if g E H-1/2(I'), then the exterior Neumann problem for the Helmholtz equation,

-Au - k2u = f on 52+, 8v u = g

on l',

has a unique radiating solution u E HIa, (S2+). [Hint: reformulate the

Exercises

295

problem as a boundary integral equation involving the hypersingular operator R, and apply the Fredholm alternative as in the proof of Theorem 9.11.] 9.6 Show that, in two dimensions, the identity of Theorem 9.15 takes the form

(ROr, *r)r = (Sai0, atf)r - k2(S(Orv), irrv)r for 0,' E D(R2) where r = (-V2, vi) is the tangent vector to I' satisfying v x r = e3, and

a,0 = r

grad 0 denotes the tangential derivative of 0.

10

Linear Elasticity

In the preceding two chapters, we considered the simplest and most important examples of scalar elliptic equations. Now we turn to the best-known example of an elliptic system, namely, the equilibrium equations of linear elasticity. For the history of these equations, we refer to the article by Cross in [30, pp. 10231033], the introduction of the textbook by Love [60], and the collection of essays by Truesdell [101]. Our aim in what follows is simply to show how the elasticity equations fit into the general theory developed in earlier chapters. Necas and Hlavd6ek [73] give a much more extensive but still accessible treatment of these equations, without, however, discussing boundary integral formulations. Let u denote the displacement field of an elastic medium. Mathematically, u : 7 -+ C', so m = n in our usual notation, and physically u is R"-valued and the dimension n equals 3. In Cartesian coordinates, the components of the (infinitesimal) strain tensor are given by

Ejk(u)=Z(ajuk+akuj) forj,kE(l,2,...,n), and we denote the components of the stress tensor by E jk. Thus, using the summation convention, the kth component of the traction over r is vi E jk. (The

traction is the force per unit area acting on S2 through the surface T.) If f is the body force density, then in equilibrium we have aJ Eik + fk = 0.

(10.1)

For a linear homogeneous and isotropic elastic medium, the stress-strain relation is E jk (u) = 2µE jk (u) + A(diV u)s jk,

where the Lame coefficients µ and X are real constants. We can write the 296

Korn's Inequality

297

equilibrium equations (10.1) in our standard form Pu = f by putting

Pu = -a3Bju

and

(13ju)k = Ejk(u).

Notice that the conormal derivative has a direct physical meaning:

B, u = traction on r, and since

aj Ejk =,1 aj(ajuk + akU j) + a.ak(div u) = µajajuk + (µ + ).)ak(diV U), the second-order partial differential operator P can be written in the form

Pu = -µ/u - (µ + A) grad(div u).

(10.2)

This chapter begins with a proof of Korn's inequality, thereby establishing that P is coercive on H 1(S2)" . After that, we derive the standard two- and three-dimensional fundamental solutions. The third and final section discusses uniqueness theorems and the positivity of the boundary integral operators, but only for the three-dimensional case.

Korn's Inequality We see from (10.2) that the Fourier transform of Pu is P u ( ), where P ( is the homogeneous, R"'-valued quadratic polynomial with jk-entry

)

Pjk( ) = (27r or, letting I, denote the n x n identity matrix,

(202[µI I21" + (µ + A)

(10.3)

Thus,

fori ElR' andnEV, and therefore P is strongly elliptic if and only if

µ > 0 and 2µ +.l > 0;

(10.4)

cf. (6.5). Landau and Lifshitz [54, p. 11] explain the physical significance of (10.4). Since

(BjU)*ajV = Ejk(u)aJVk =2pEjk(it)ajVk+X(dlvu)akVk = 21.LE jk (u)Ejk (v) + A(div u) (div v),

Linear Elasticity

298

the sesquilinear form associated with P is

(pc(u, v) = f [21LEjk(u)Ejk(v)+A(divu)(divv)]dx. For a physical displacement field u : 0 -+ 1R3, the quadratic form

2Osz(u, u) = 2 f Ejk(u)Ejk(u)dx z

is the free energy of the elastic medium within S2; see Landau and Lifshitz [53, p. 12]. It will be convenient to let grad u denote then x n matrix whose jk-entry entry is ajuk, and to write

IIE(u)Ili2(sz)"xn = f Ejk(u)Ejk(u)dx and z

J

8juk8jukdx.

Notice that

cl z(u, u) =

21L11E(u)IIi2(U)"xn

+ I1divu11t2(12).

(10.5)

If the Lame coefficients satisfy (10.4), so that P is strongly elliptic, then we know from Theorem 4.6 that (D is coercive on Ho (S2)". In fact, a stronger result known as Korn's first inequality holds. Recall that, by Theorem 3.33, Hi (Q)" = Hp (S2)" if S2 is Lipschitz.

Theorem 10.1 If 0 is an open subset of R", then IIE(u)112 (n)1xn

grad u11L2foru E

>_

(Q) n.

all

Proof. It suffices to consider u E D(O)". As in the first part of the proof of Theorem 4.6, we apply Plancherel's theorem to obtain

JR" Ejk(u)Ejk(u)dx = fR#l

=j 2

kuj)(17T)(5juk+} kuj)d

I . ul2) d "

f

2

fR- Iaju12dx. j=1

The result follows, because we can replace R" by 0 in both of the integrals with respect to x.

0

Fundamental Solutions

299

A much deeper result is Korn's second inequality (or just Korn's inequality). Theorem 10.2 If S2 is a Lipschitz domain, then IIE(u)IlL,()nxn ? cllgradUHL,(f)nxn - CIIuIIL2ISZ),7

foru E H'(SZ)n.

Proof. The left-hand side has the form (4.10) with L = n2, and for convenience we change the index set, writing N1ku = EJk (u) instead of N u. Since

.AIku = 2(a;uk + aku;) = 2(ekaj +ei ak)u, we have

(Nfku (x) } = Njk (i2rc )u (l; ), where NJk (

) = 2 (ek1 + e Sk).

The desired inequality holds because the hypotheses of Theorem 4.9 are sat-

isfied, with q,. = 1 for 1 < r < m = n. For instance, when n = 3 and

r=1, =2el,

1N11(e)T =tiel,

-6 N22

2NI1(S)T = 12e1,

-1N23(e)T +3N12()T +2N,3( )T = 2e3e1,

t3 N, ]( )T = 1e3e1,

-1N33( )T +3N13()T + 3N31( )T = t3e1,

)T

and the other cases can be handled in the same way.

In view of (10.5), Korn's second inequality implies the following result, which allows us to apply the general theory of elliptic systems. Necas and Hlavacek [73, pp. 46-49] give simple physical arguments showing that both Lames coefficients should be positive for typical elastic materials.

Theorem 10.3 For any Lipschitz domain S2, the elasticity operator (10.2) is coercive on H I (S2)" if µ > 0 and X > 0.

Fundamental Solutions Since the polynomial (10.3) is homogeneous, we may obtain a fundamental solution for the elasticity operator using Theorem 6.8; see Landau and Lifshitz [54, p. 30] for an alternative approach.

Linear Elasticity

300

Theorem 10.4 If µ # 0 and 2µ + A # 0, then a fundamental solution G (x, y) G(x - y) for the elasticity operator (10.2) is given by T

G(x)

8nµ(2µ + .X)

C(3µ + X)

1 13 + (µ +,X) IxI3) I

when n = 3, (10.6)

and by G(x)

=

1

4gµ.(2µ +X)

((3p' + .) log

1 I2 + (µ + A) xxTI2) 1

I

when n = 2.

IX

Proof By (10.3), if CO E S", then

P(w) = (2n)2[µ1 + (µ +,l)WWT ] and so by Exercise 10.1, z

p(w)-I =

(27r)

µ(2µ + ),)

[(2µ + ),)I - (µ +))WWT ].

Assume that n = 3, and choose an orthonormal basis ?71, 712 E JR3 for the plane normal to x, so that the unit circle in this plane has the parametric representation SY : w1 = (cos 0)x1i + (sin 0) 712

for -7r < B < n.

By Theorem 6.8(iii), z

G(x)

- I µ(2µ + X) J [(2µ

+ ),)I3 - (µ + )A)wlwl] dw1,

and since

fs

xx T

+ (sine 0)r1271i] dO = 7r (7JI 17T + 712711) = 7r (13

- IxI2 )'

the formula for G(x) follows. Suppose now that n = 2; by (6.13), the formula

G(x) =

-(2n)

z

µ(2µ +,X)

J((log Iw sI

xI)[(2µ + ),)12

- (µ +)-)wwT ] dw

Uniqueness Results

301

defines a fundamental solution. The vectors

ni =

x

x,

1

=

Ixl - Ixl

X,21

and

X2

J7,

Ixl L

form an orthonormal basis for R`, and by putting co = (cos 9)r71 + (sin 0) 112 we see that

Js

log Iw xI dco =

T

_n

log(Ix cos01) dO = 2.7r log IxI + const

1

and

(log 1w x l )WWT dco

Js'

=J log(Ixcos01)[(cos20)17,riT +(co59sin9)(ri,riz +rl2rli) + (sin2 9)7721i2 ] d9

J

"

1 +cos 20 2

1og(IxCOSel)

T

,+

1 - cos 20

T1 dB.

2

2 J/

n

An integration by parts gives ;r

f

log (Ix cos 91) cos 20 d0

=

-,

rr

,

IT

sin O sin 20 dO = Cos 9 2

sine 0 dO = rr, n

and one easily verifies that

xxT

and

'?Irli +rl2riz =12

ntrli -7722 =2Ixle -12,

so

f

1

(log lc) xl)wwTdco= 1

r

log(IxcosOl)dO12+

/ 2xxT

I 7rI

1x12

12)

= rr log Ix 112 + it x 12 + const,

leading to the stated formula for G(x).

U

Uniqueness Results Throughout this section, we assume that the components of u are real, and treat only three-dimensional problems.

Linear Elasticity

302

To apply the Fredholm alternative (Theorem 4.10) to the mixed boundary value problem in linear elasticity, we must determine all solutions of the homogeneous problem. As a first step, we show that the only strain-free displacement fields are the infinitesimal rigid motions, and that such displacement fields are also stress-free.

Lemma 10.5 Let S2 be a connected open subset of R3. A distribution u E D*(52;R3) satisfies E(u) = 0 on S2 if and only if there exist constant vectors a, b E R3 such that

u(x)=a+bxx forxES2.

(10.7)

Moreover, in this case E(u) = 0 on S2.

Proof. Let B = [b,3] E 83x3 denote the skew-symmetric matrix defined by Bx = b x x, i.e.,

B=

0

-b3

b2

b3

0

-b1

-b2

b1

0

Ifu(x)=a+b xx,then ajuk =bkj,so Ejk(u) = 1 (bkj + bjk) = 0. To prove the converse, assume that E(u) = 0 on S2. Since, with the notation of (3.9) and (3.10),

E(*,*u)='YE*E(u) on(xES2:dist(x,I')>e}, we can assume that u E C`O(S2)3. The diagonal entries of the strain tensor are

just Ejj(u) = ajitj (no sum over j), so a1u1 = a2u2 = 83113 = 0

on 0.

Since the off-diagonal entries of the strain tensor also vanish, we can show that

a2u1=83u1=0,

82

a1u3=a2u3=0

on Q;

for instance, a uk = al (2Elk (u) - aku 1) = -ak (al u 1) = 0. Therefore, Fu = 0 on 0 if (a I > 3, implying that u is a quadratic polynomial in x. In fact, the vanishing of the partial derivatives listed above shows that u must have the form ul(x) = al + b12X2 + b13x3 + C1X2X3,

u2(X) = a2 + b21X1+ b23X3 + C2X1X3. u3 (X) = a3 + b31x1 + b32x2 + c3X1X2,

Uniqueness Results

303

for some constants aj, bik and cj. Since E(u) equals 0

b12+b2,

b13+b31

b,2 + b2,

0

b23 + b32

b, 3 + b3,

b23 + b32

0

1

1

+ 2

0

(C) + C2)X3

(Cl + C3)X2

(Cl + C2)x3

0

(C2 + C3)x1

(Cl + C3)X2

(C2 + C3)xl

0

we conclude that bfk = -bk! and c! = 0 for all j, k. Finally, if u has the form (10.7), then E(u) = 2AE(u) + A(divu)13 = 0 because E(u) = 0 and div u = E!j (u) = 0. O Theorem 10.6 Assume that 0 is a bounded, connected Lipschitz domain in and that the Lame coefficients satisfy

A>0 and A>0.

(10.8)

Let W denote the set of solutions in H' (S2; R3) to the homogeneous, mixed boundary value problem

-p Au - (µ + A) grad(div u) = 0 on 0,

yu =0

on I'D,

0

on F.

(10.9)

(i) If I'D # 0, then W = {0}, i.e., (10.9) has only the trivial solution. (ii) If I'D = 0, so that (10.9) is a pure Neumann problem, then W consists of all functions of the form (10.7) for a, b E 1R3.

Proof. If U E H' (Q)3 is a solution of (10.9), then c(u, v) = 0 for all v E H1(Q)3 such that yv = 0 on I'D. In particular, by taking v = u and recalling (10.5), we see that 2 tjIE(u)IIL,(Q)3x3 +AIIdIvuIIL,(g2) = 0.

Our assumptions on a and A then imply that E(u) = 0 on Q, and so u has the form (10.7). If FD # 0, then, because rD is relatively open in r, we can find x, y, z E rD such that x - y and z - y are linearly independent. From the three equations

a+bxx=0, a+bxy=0, a+bxz=0,

Linear Elasticity

304

it follows that b x (x - y) = 0 and b x (z - y) = 0, and we conclude that b = 0. (Otherwise, x - y and z - y would both be scalar multiples of b.) In turn, a = 0, and part (i) is proved. If I'D = 0 and u has the form (10.7), then E (u) = 0 on S2, by Lemma 10.5, and so u is a solution of the homogeneous Neumann problem, i.e., u E W. 0 To conclude this section, we consider the boundary integral operators S : H-'t2(F; 1183)

H112(F; 1183)

and

R : H't2(r; R3) -+

H-1/2(1,; R 3)

associated with the three-dimensional elasticity operator (10.2), and defined using the standard fundamental solution (10.6). Theorem 10.7 Assume that the Lame coefficients satisfy (10.8).

(i) The weakly singular boundary integral operator is positive and bounded below on the whole of its domain, i.e.,

(Si, Or ? cIIrf1H-,r-(r)3 for all Ir E H-1/2(r; R3). In particular, ker S = (0). (ii) The hypersingular boundary integral operator is positive and bounded below on the orthogonal complement of its null space. Indeed, if SZ- is connected, then the six functions Xi : I' -+ 1183 (1 < j < 6) defined by

forxEI'and1
X1(x)=el and X,+3(x)= e1xx form a basis for ker R, and we have (R1G, Or >- cII*II

1r_(r)3

for* E H1t2(r; R3) such that (Xj, Or = 0 for 1 < j < 6. Proof. By Theorem 10.3, the assumptions on µ and X ensure that the elasticity Since, in three dimensions, the operator (10.2) is coercive on H1(Q'; elastic single-layer potential satisfies R3).

SL*(x) = O(Ixl-1) and gradSLt/r(x) = O(Ixl-2)

as Ixl -+ oo,

we can argue as in the case of the Laplacian (Theorem 8.12) to show that

(S*, O)r = (Df[2tEJk(SL +(SL 1/i, SL O) + - (SL i*r, SL 0)

=llr)Eik(SLgi) +A(divSL*r)(divSL0)]dx

Exercises

305

for all i/r, q5 E H-112(x)3. In particular,

(S*, 1G)r = 2p lE(SL )IILz(R3)3x3 +.klldivSL,GllLz(R3) > 0. Moreover, if (S*, i)r = 0 then E(SL ir) = 0 on 1R3, so SL*(x) = a +b x x for some a, b E R3. In fact, a = b = 0 because SL * (x) -+ 0 as Ix I - + oo, and hence i/r = -[By SL *]r = 0. Part (i) now follows by arguing as in the case of the Laplacian (Corollary 8.13). Turning to the hypersingular operator, we can argue as in Theorem 8.21 that (Ri/r, cb)r = (D+(DLt/r, DL.O) + (D-(DL,/r, DL-0)

for all i/r, 95E H1/2(I')3,

andinparticular (R1/r, Or ? 0. Moreover, if (Rir,1/r)r = 0, then E(DL i/r) _ 0 on St}, implying that E (DL /r) = 0 on SZ} and hence Ri/r = -B, DL t/r = 0 on r. Exercise 2.17 then shows that R is positive and bounded below on the orthogonal complement of ker R. To complete the proof of part (ii), we assume that Sl- is connected. It suffices to show that t/r E ker R if and only if ti = u I r for some u of the form (10.7).

Let Ri/r = 0 on F. Since (Ri/r, Or = 0 we have E(DL ifr) = 0 on Was above, and so by Theorem 10.6, there are vectors a±, b± E 1R3 such that DL i/r (x) = a± + b± x x for x E SZ±. In fact, a+ = b+ = 0 because DL i/r (x) -* oo, and hence /r = [DL i/r] r = u I r where u is given by (10.7) with 0 as Ix I

a= -a_ andb=-b_. Conversely, suppose that ilr = u I r where u (x) = a + b x x for x E R3. 0 on I', the third Green identity for u reduces Since Pu = 0 on Sl, and

to u = - DL i/r on SZ-, implying that 0 = -Br, DL i/r = Ri/r on I', i.e., i/r E ker R.

Exercises

10.1 Show that ifa00,a+b#0andwES"-',then (aI + bwwT)-1

= a(a + b) [(a + b)I

- bwwT ].

10.2 Nitsche [79] gives the following elementary proof of Kom's second inequality for C1 domains. (The same paper also extends the method of proof to cover Lipschitz domains, with the help of a regularised distance.) Suppose first that S2- is the hypograph x" < (x'), and let u E H 1(S2-)". Given s > 0, we define us E H 1(S2+)" by reflection in

Linear Elasticity

306

the surface x _ (x'), i.e.,

us(x) = u(x', (x') - s[x" - (x')]) for x > (x'), and then consider v E H I (S2+)" of the form

I au''+bu''. vj =

pu,+qu,',

ifl < j
ifj=n,

for unspecified constants a, b, p, q, s and t such that s > 0 and t > 0. (i) Show that y+v = y-u if and only if

a+b=1 and p+q=1. (ii) Show that if x E Q+, then

(aju)r(x)

(ajus)(x) _

for 1 < j < n - 1, for j = n.

+(1 -s(a"u)s(x)

(iii) Deduce that for I < j < n - I and I < k < n - 1,

Ejk(v) = aEjk(u)s +bEjk(u)' +

all

(a"Uj)Sak0 + 2(1 + t)[(anukYaj + (anuj)'akf], whereas

E,,,,(v) = -spE, (u)S - tgEnn(u)'(iv) Show that if

p = -sa and q = -tb, then for 1 < j < n - 1, Ep,(v) = pEj,,(u)s +qEj"(u)' + + 2(1 + t)E,,,,(u)'8j

(1 +s)E..(u)sajg 2

(v) Show that IlusllL,cn+) = s-I IIuIIL2c01.,,

Exercises

307

and deduce that, with M = max l < j <,1_ 1

Il aj

11 cx (!rt°-' )'

CI IIE(u)IIL2(9-)"" +C2M

where Cl and C2 depend only on a, b, p, q, s, t and n.

(vi) Choose (say) a = -2, b = 3, p = 4, q = -3, s = 2 and t = 1, so that these constants satisfy the conditions in parts (i) and (iv), and define U E H 1 (R")' by

U= I u L

u

on 2

,

on 52+.

Show, by applying Korn's first inequality (Theorem 10.1) to U, that

2(1 +C1)IIE(u)Ili + 2C2 M2 Ilgrad U112

and deduce that if M < 1 / 2C2 then

II grad u II L, (sI-)"" x <

(vii) Finally, use a partition of unity to prove Kom's second inequality (Theorem 10.2) for a C 1 domain (with compact boundary). 10.3 For n = 2, the elasticity operator (10.2) has the form 2

2

Pu = ->

aj(Ajkaku)

j=I k=1

where 21L+ ,X

All

o],

01, µ

L

A22 = Thus, f o r Z ; I = [ 2

t1

121T,

µ 0

0

2µ+.1]'

2 = R2I ,221T E R2,

2

j=1 k=1

I

= 2[fitl

22

12

2I1

4µ+2), µ+X µ+A 4µ+2), 0

0

0

0

0

0

0

0

2µ µ+A µ+A 2µ

Linear Elasticity

308

Assuming P is strongly elliptic, so that the Lame coefficients satisfy (10.4), show that the condition (4.9) fails to hold if h > µ or if -2µ <

A < -5µ/3. 10.4 Show for n = 3 and for u e C I (7)3 that the surface traction can be written as

-µ(v x curl Or. [Hint: first establish the identity (v x curl u)k = P J 8k U f - V J 8 J uk .]

10.5 Consider the pure Neumann (i.e., pure traction) problem in linear elasticity:

-µEu - (µ + X) grad(div u) = f on 0, on1. Show that a solution exists if and only if the resultant force and the resultant torque both vanish, i.e.,

r

J f(x)dx+J g(x)dcx = 0 r

and

xx f(x)dx+ f xxg(x)dar=0. Jn

r

Appendix A Extension Operators for Sobolev Spaces

We say that E : WP(S2) -* W, (1R") is an extension operator if E is bounded and satisfies

Euln = u for u E Wp(S2). For our purposes, the significance of such operators stems from Theorem 3.18.

If Q is Lipschitz, then a construction due to Calderbn [8] yields, for each integer k > 1, an extension operator Ek : WP (S2) -3 WP (R) that is bounded for 1 < p < oo. Using a different method, Stein [96, p. 181] obtained an extension operator E : W PI (S2) -+ WP (118"), not depending on k > 0, and bounded

for 1 < p < oo. In the case when 0 is smooth, there is a simpler construction, due to Seeley [93]; see Exercise A.3. In the main result of this appendix, Theorem A.4, we shall use a modified version of Calderon's extension. Suppose that S2 is a hypograph, S2= (x

x _ 1), and the function

: 1R11- I -- R is Lipschitz:

Mix' - y'i for x', Y' E R"-'.

(A.2)

A crude extension operator is obtained simply by reflection in the boundary of S2.

Theorem A.1 If 0 is the Lipschitz hypograph (A.1), and if

Eou(x) =

for x E S2,

U (X)

1u(x',2 (x')-x") forx c- W' \S2,

then Eo : W p (S2) --* Wp (IR") is bounded for 0 < s < 1 and I < p < oo. 309

Extension Operators for Sobolev Spaces

310

Proof Puti = (x',

xn). One easily verifies that x E 0 if and only if x E R" \ 0, and vice versa, with x = x. Moreover, the Jacobian determinant of the transformation x H x is identically equal to -1. Thus, II Eou II L,,(W'\n) _ IIUIILP(n), and IIEouIIL,,(R11) = 211uIILn(12) Also, if x E R" \ 0, then

for 1 < j < n - 1, for j = n,

8;u(2)

ajEou(x)

-anu(2)

implying that II8;UIILP(s2) +2MIIanUIIL,,(52) { I1

fort < j < n - 1, f j = n.

u11 z,,(9)or

8

Hence, Eo : W, (0) --+ WP (R") is bounded if s = 0 or 1. Assume now that 0 < s < 1 and 1 < p < oo. Recalling the definition (3.18) of the Slobodeckii seminorm, we write IEouIf pR,,

=lulsps2+I(+12+I3,

where

I,

lu(x) - u(Y)IP

Ix -

fL >x').

Yln+ps

dxdy ,

n

Iu(2)-u(y)Ipdxd

I213 = Since I2, that

Y,

n+ps

Iu(x) fL,<(X),

>t(Y')

v,

Ix - Y 112+p$

dxdY.

/f 4M2 IX - y1, we see

- 5 I < 21(x') - (y')I + Ixn -


Iz-j'I<2 1+M21x-yI, and so

lu(2)-u(Y)Ipdxd 11

Ix - yIn+Ps

< (2 1 +

y

p

M2)n+Ps

IL

(X7, ?5,<;(Y')

I u(x) - u(y)1 dz f

IX-

d"Y

=C

uIs P.

I

If x,, > (x') and y < (y'), then

-Y'I,

Extension Operators for Sobolev Spaces

311

so

Ix -

+21x,, - (x')1 < CIx -y I,

Iy +x,, - 2C(x')I < ly -

and hence

I2-

Iu(x)-u(Y)IPdxd y, Ix - YI,1+Ps

ff

Iu(x) -u(Y)Ip


Ix - y1n=+PS

X...

dz dY= cIuIP P.sz,

Similarly, 1 3 < C I u I ° P n, giving the desired bound for Eou.

Finally, consider the remaining case 0 < s < 1 and p = oo. If x > (x') and y" > (y'), then I Eou(x) - Eou(y)I = Iu(z) - u(Y)I < Iuls.oo.nlx - YI'`

< [2V-1 + M2lsluls,oo,szlx - yls.

If x > (x') and y < (y'), then Eou(x) - Eou(y)I = Iu(i) - u(y)l < Iuls,..nIi - yls < CIuls,.,S21x - yls, and similarly if x < (x') and y > (y'), then I Eou (x) - Eou (Y) I < C l u (s,oo,5

Ix - yIs. To obtain an extension operator for s > 1, we shall use the Sobolev representation formula; recall the notation of (3.7). Lemma A. 2 For each integer k > 1, if i/r E C°°(S"-') satisfies

f

f(co) dco =

-1=1

(-1)k (k - 1)!'

(A.3)

and if u E C o ,(R" ), then

u(x)=f t^

* \ I_

u(k) (x

I'

+ y; Y) dy for x E R".

Proof By Exercises A.1 and 3.5,

(k_I()( 00

u(x)

(k -11)!

dp

°o

k

(k- 1)!

x + pco) dp

pk-lu(k)(x+pco;co)dp.

10

312

Extension Operators for Sobolev Spaces

Multiplying both sides by * (w) and integrating with respect to co, we see that 00

u(x) = f

*(c)) f

uI=1

p-flu(x + pco; pw) p"-1 dp dm.

0

We use the abbreviation I u 1 µ for the Slobodeckil seminorm on R" with p = 2.

Lemma A.3 If K E C u E D(R"), then

\ (0}) is homogeneous of degree 1 - n, and if

(

for-oo<s
IIa,(K * u)IIHs(II) < CIIUIIH=(RH) and

laj(K*u)lu
81(K * u)(x) = (K * aju)(x) = lim) E1,0

Iy-XI>E

K(x - y)aj u(y) dy,

and since

a;.y[K(x - y)u(y)] = -a;K(x - y)u(y) + K(x - y)a;u(y), the divergence theorem gives

xj fly_Xj=45

y' K(x - y)u(y) day = - j

y -XI>E

E

+f

ai K(x - y)u(y) dy

K(x -y)a;u(y)dy.

ly-xl>E

Making the substitution y = x - Eco and using the homogeneity of K, we see that the left-hand side equals

f

cojK(Eco)u(x

Eco)&'

dco = f

wl=t

coK(w)u(x - Eco)

WI=t

so, defining aj = f.I=) cod K (co) dw, we have

af(K*u)(x)=aju(x)+lim E,,0

f

fly-xI>E

a;K(x-y)u(y)dy.

Extension Operators for Sobolev Spaces

313

Hence, by Exercise 5.14, the desired estimate for aj (K * u) will follow at once if we show that

ajK(co)dw=0.

(A.4)

Choose a cutoff function X E C 1P(0, oo) satisfying f0 X (p) dp/p = 1. Integration by parts gives

f ajK(x)X(Ix1) dx = ,.

fR"

K(x)X'(Ix1) X dx, 1X I

and by transforming to polar coordinates, we have aj K(Pw)X (P)Pi-1 dp dw fp>O jwl=rI

f

"'1=1

p>o

K(Pw)X'(P)wjpn-1

dpdw,

which, using the homogeneity of aj K and K, simplifies to

f

0

00

X(P)dp f P

ajK(co)dco=-f' X'(p)dp

f

K(w)wjdo.

I"I_1

IWI=1

Since ff ° X (p) dp/p = 1 and fo x'(p) dp = -X (0) = 0, the function Kj satisfies (A.4), as required.

We are now in a position to obtain the desired extension operator.

Theorem A.4 Assume that 0 is a Lipschitz domain. For each integer k > 0, there exists an extension operator Ek : WZ (Q) -* W2 (R") that is bounded

forks
V = {yER":y"<-Mly'IJ, and observe that by (A.2),

x+VCQ forxEQUT. Fix an integer k > 1 and a function * E CO0 (S"-1) such that (A.3) holds, with

supp * c Sn-1 n V.

Extension Operators for Sobolev Spaces

314

Let X E C ,-..p [0, oo) be a cutoff function satisfying X = 1 on a neighbourhood of 0, and replace u (x + y) by X (I Y I )u (x + y) in the proof of Lemma A.2 to obtain the identity k

u(x) _ E 1=0

Jv

*,(y)u('(x + y; y) dy

for x E S,

where *1 (Y) =

(k)jlk_l_fl(k...l)(1l),(_)

forO
Let Eo be the extension operator from Theorem A. 1, assume u E V(SZ), and put

ua = Eo(a"u) We define

f 'Eku(x) 1=0

Jv

t.I ua(x

r(Y)

+ y) y' dY = >2 (pa * ua)(x)

Ial=1

lal
for'x E R", where

"a (Y) = I' *,(-y) (-y)' for la l =1, so that EkuIk = u. If Ial
forlal
so by Theorem A.1, IIEkull

(R-) _

IIaflEkullL2(R") < C lal
IRI
CE lal
118aU112

- CIIUIIW,(n).

Exercises

315

Also, if 0 < j.c < 1 then

iflal
< k, if lal = k and I1I = k,

CIIfIIL2(R1)

_ 10R. * f)Im,>R < {

Clf lµ,p

implying that

Ia1Ekal

C

>Rn <_

I" I=k

I

CIIUI12

)+C

la"ul'2`.,

=CIIUI1wk+

).

El

I"I=k

Exercises A.1 Show that, for any integer k > 1, if f : [0, oo) -+ C is a Ck function with compact support, then

_ .f (0) =

(k

k

-11) Jo

o0

tk-1 fck) (t)

dt.

o

A.2 In Exercise A.3, we shall need a sequence (,lk)k° satisfying 00

E 2'klk = (-1)' for all j > 0.

(A.5)

k--O

(i) Let ao, ..., aN-1 be distinct complex numbers, let b be any complex number, and consider the N x N linear system N-1

E(ak)'xk=b' for0< j
Show that the unique solution is given by N-1 xk =

aj - b for 0 < k < N - 1.

1=0

aj - ak

h 4k.

[Hint: by Cramer's rule, xk is the ratio of two Vandermonde determinants.]

(ii) Show that 00

00

i=o

1=1

1
Extension Operators for Sobolev Spaces

316

(iii) Deduce that the sequence ,kk =

00

1 + 2-j

1 1 - 2k-j i=0 jek

satisfies k

Ixkl

1

1

C 2k(k-1)/2

and is a solution of the infinite linear system (A.5). A.3 Seeley [93] has given a simple construction of an extension operator for the half space c2 = R. Let the sequence (,kk) be as in Exercise A.2, and define 1

u(x)

Eu(x) _

00

if X. < 0,

Xku(x',

if x > 0.

I k=° (i) Show that E : D(Q) -+ D(R"). (ii) Show that E : Wn (S2) -+ WP (R") is bounded for s > 0 and I< p
A.4 Let 0 < µ < 1 and E > 0, and choose a cutoff function X E C mp[0, co) satisfying x (y) = 1 for 0 < y < 1. Define the C°'µ epigraph n = {(x, Y) E R2 : y > IxI'`}, and the function

u(x, Y) =

y'-Ex

(y)

for (x, y) E Q.

2(µ-' - 1). (i) Show that u E W2 (S2) if E < (ii) Show that u l C°'- (Q) if I - E < X < 1. (iii) Deduce that no extension operator from W2 (S2) to W2(llt2) exists. [Hint: use Theorem 3.26.]

Appendix B Interpolation Spaces

Suppose that Xo and X 1 are normed spaces, and that both are subspaces of some

larger (not necessarily normed) vector space. In this case, X0 and X1 are said to form a compatible pair X = (Xo, X1), and we equip the subspaces Xo n X1 and Xo + X 1 with the norms IIuIIX,)1/z

IIulIxonx, = (IIuIIXa + and

IIuIlxa+x, = inf {(IIuoIIX0 +

11U1 11X21)1/2

u = uo + ul where uo E Xo and u1 E X1 }.

Notice that for j = 0 and 1,

X0 nX1 cXj cX0 +X1, and these inclusions are continuous because IIuIlxa+x, < II U II x1 < II ulIxonx,

If XI c Xc,then XonX, =X1 andXc+X1 =X0. In this appendix, we present a general method for constructing, from any given compatible pair X, a family of normed spaces Xe,q = (Xo, X 1)e.q

for 0 < 9 < 1 and I < q < oo,

each of which is intermediate with respect to Xo and X1, in the sense that Xo n X1 c Xe,q c Xo + X1. 317

(B.1)

Interpolation Spaces

318

Moreover, we shall see that XB,q has the following interpolation property. Take

a second compatible pair of normed spaces Y = (Yo, Y1), and two bounded linear operators Ao : Xo -+ Yo

and

A, : X 1 -+ Y1.

If Aou = Alu

for U E Xo n X1,

then AO and A 1 are said to be compatible, and there is a unique bounded linear operator AB : XB,q -* YY,q

such that

ABU =Aou = Alu foruEXonXl.

(B.2)

We will also show that if X0 and X1 are Sobolev spaces based on L2, then so is X8.2

For technical reasons, it is convenient to construct Xe,q in two different ways. Thus, we shall define two spaces, Ko,q (X) and Jo,q (X), and show X B,q = KB,q (X) = Je.q (X ),

with equivalent norms. The K-method will be used to prove the interpolation properties of HS (c2), after which the interpolation properties of HS (Q) follow by a duality argument that relies on the J-method. We conclude by considering the interpolation properties of HI (F). For more on the theory of interpolation spaces, see Bergh and Lofstrom [5].

The K-Method The K -functional is defined for t > 0 and u E Xo + X 1 by K(t, u) = inf {(IIuoIIX0 + t2IIu111X,)112

u = uo + u l where uo E X0 and U1 E X1 }. When necessary, we write K (t, u; X) to show explicitly the choice of the compatible pair X = (Xo, X1). For fixed t > 0, the K-functional is an equivalent

The K-Method

319

norm onX0+X1:

K(t, u + v) < K(t, u) + K(t, v)

K(t,.Xu) = IXIK(t, u), and

min(l, t)Ilullxo+x, <- K(t, u) < max(l, t)Ilullxo+x, If we fix u, then the K-functional is a non-decreasing function of t, and in fact, for all positive s and t,

min(1, t/s)K(s, u) < K(t, u) < max(l, t/s)K(s, u). Next, we define a weighted Lq-norm,

dt lq

00

llflle,q

=

` It-e.f(t)Iq r

for 0 < 9 < 1 and 1 < q < oo,

0

with the obvious modification when q = oo, Il f Ile.00 = ess sup It-If (t) I. t>0

This weighted norm has an important dilatation property, namely,

Ilt H f(at)Ile,q =aellflle,q fora > 0.

(B.3)

Now define

Ko,q(X) = (u E Xo + X1 :

II

u)IIe,q < oo},

and put II u11 K., (x) =

u) III,?,

where the constant Ne,q > 0 may be any desired normalisation factor. As the default value, we take

ifl q
I

Nq

Ilmin(l, )Ile,q

I[qO(1-9)Vk if q = oo, 1

and thereby simplify the statement of the next lemma.

(B.4)

Interpolation Spaces

320

Lemma B.1 Assume the normalisation (B.4).

(i) If U E Xa fl Xj, then u E K°,q(X) and II'IIxe.,(X) -< IIu11X-°IIuIIX, < Ilullxonx,

(ii) If U E K°,q(X), then u E Xo + X,, with

K(t,u)
Ilullxo+x, < IIu11xe.,(x)

Proof We can assume u 54 0. Put a = II u II x, / II a II x-, so that

K(t, u) < min (Ilullxo, tllullx,) = Ilullxo min(l, at),

(B.5)

and hence u)Ilo,q < Ilullxoa°II min(l, )Ile,q = Ilullxo°IIuIIX,/N°,q, implying the inequality II u II xe,, (x) < IIuIIX-°IIuIIX,. Next, taking p = (1 - 0)-', we have (Ilu!Ix-

Hull X-°IIuIIX, <

< [(1

p

s)p

+

(II

u

IP*,)r

= (1 - 9)Ilullxo +alluIIx,

- 9)2 +02]'/211u11xonx,,

completing the proof of (i). In a similar fashion, the inequality min(1, s/t) K(t, u) < K(s, u) implies that t-" 11 min(l, )II°,7K(t, u) <-

u)Ilo,q,

and so K(t, u) < t9 11 u11X,.q Finally, because min(l, t) 11 u11 X" +X, < K(t, u) we 0 have II u II xo+x, /No,q < II K u)11 °.q, which completes the proof of (ii).

Lemma B.l shows that X°,, = K°,q(X) satisfies (B.1), with continuous inclusions. The next theorem establishes the interpolation property. Here, the choice of normalisation is irrelevant (provided it is the same for X and Y). Theorem B.2 If the bounded linear operators AO : Xo Yo and A, : X 1 -+ Yi are compatible, then there exists a unique bounded linear operator A° : K°,q (X) -+ Ko,q (Y) satisfying (B.2). In this case, if Ma and M1 are positive constants such that

IlAjullrj < Mjllullxj

fore E Xj and j =O, 1,

then IIAoullxo.g(r) < Mo-9M°IIuIIxo.q(X)

foru E Ko,q(X).

The J-Method

321

Proof If AB exists, then it must satisfy Aeu = Aouo + A1u1 whenever u = uo +u1 with u1 E Xj, so uniqueness is clear, and Exercise B.1 shows that A9u is in fact well defined in Yo + Y1. Put a = M1 /Mo, so that K(t, Aeu; Y) < (IlAouo11Y0 +t21IA1u111Y,)1,2 < (Mo11 uo112 +t2Mi 11u111x,)1/2

< Mo(Iluollzo + (at)211 u111x1/2.

Hence, K(t, Au : Y) < MOK(at, u; X), and so by (B.3), M0 _B

II As u II K0.q (Y) < Moae 11 u ll K, (X) =

MB II U KII g cx> 11

O

The J-Method Our second construction of Xe,q uses the Bochner integral for functions taking

values in a normed space, and we digress briefly to review a few pertinent definitions and facts; see Yosida [106, pp. 130-136] for more details. Let (S, A) be a measure space and let Z be a normed space. We say that a function f : S -+ Z is finite-valued if there exist finitely many vectors Uk E Z and mutually disjoint p-measurable sets Ek c S with A(Ek) < oo such that f takes the constant value Uk on Ek, and is identically zero on S \ Uk Ek. In this case, the integral of f is a well-defined vector in Z, given by

Is

f (t) dµt =

uk/) (Ek) k

A function f : S -* Z is said to be strongly Z-measurable if there exists a sequence f,,, : S --> Z of finite-valued functions such that ,,,(t) converges to f (t) in the norm of Z for A-almost all t E S. In this case, the real-valued function t t-+ II fn (t) - f (t) II z is measurable, and if the condition

lim fSI1 m-.oc

fn(t)-f(t)Ilzdlkt=0

is satisfied, then f is said to be Z-integrable. The integral of such an f is well defined, as a vector in the completion of Z, by taking the limit of the integrals of the f,,,. A strongly Z-measurable function f : S -+ Z is Z-integrable if and only if the real-valued function t i-+ II .f (t) II z is integrable, in which case

f s

.f(t)dA,

< z

f

s

11f(t)Ilzd,ir

Interpolation Spaces

322

Resuming our consideration of Xo,q, we define the J functional,

J(t, u) = (IIuIIXo

fort>O and uEXoflXi.

+t211ul1z.)1/2

For each fixed t > 0, the J-functional is equivalent to the usual norm on Xo fl X1,

and for each fixed u E Xo fl X1, the function t -+ J(t, u) is non-decreasing. Furthermore,

min(1, t/s)J(s, u) < J(t, u) < max(1, t/s)J(s, u) and

K(t, u) < min(1, t/s)J(s, u).

(B.6)

We define Je,q (X) to be the subspace of Xo + X 1 consisting of those vectors u that possess a representation

u=

f

00 f(t)t

(B.7)

0

for some function f satisfying 00

11 f (t) 11 xo+x,

d t<

oo and

fb

II f (t) 11 xonx,

d t<

00

for0
= inf 11t H J(t, f (t)) 11 o.q,

where the infimum is taken over all possible representations (B.7).

Theorem B.3 If 0 < 0 < I and I < q < oo, then Je,q (X) = Ke,q (X) with equivalent norms.

Proof Suppose that u E Je,q(X) has a representation (B.7). Using (B.6), we see that

K(t, u) <

f f

00

K(t, f (s))

o

=

o

d < fo s

00

min(1, 1/s)J(ts,

00

min(l, t/s)J(s, f(s))

f(ts))d s

ds s

The J-Method

323

so °O

f min(1, l/s)s011 J(.,.f())II8,q 0

ds s

and hence Jo00

min(1, 1/s)se

II UII J9.q(X)

-

ds

l11 IIJ9.,(x

Conversely, suppose that u E Ko.q (X), and let c > 0. For each m E Z there is a decomposition u = uon, + U I., with urn, E Xj and where t,,, =2n'

(1+E)K(tm,u)2,

Iluon,IlXo+t

By Lemma B.1, K (t,,, , u) ::S C t e I I u I I Ka.4 (x), so I l uom l l xn

= 0(t,',,) and II u,n, ll x, _

O(te-'). In particular, IIuo,nI1xo -* 0 as m -+ -oo, and Ilu1,,,11x, m -,- +oo. Define f : (0, oo) -+ Xo fl X, by f(t) _ UOm - Uo,m-1 - Ul.m-1 - Uln, log 2 log 2

0 as

for t,,,-1 < t < tm,

so that

u- J r-M

= U-

f(t)dt

(UOn,

-M
Xo+X,

-

UO.m-1) Xo+X,

= Ilu - UO.M' + u0,-M II xo+x, = II u0.-M + U 1.M' II xo+x, IIu1,M'IIX,)1/2,

(Iluo,_MIIX0 +

implying the representation formula (B.7). Moreover, if tm_1 < t < tn then

(log2)2J(t,1(t))2 = Iluon, - uo.rn-IIIXo +t211u,,n,-1- u,mUx, < 2[IIu0,nII2X0

Iluo,m

112

2[(l + E)K(t,n, u)2 + 4(1 + E)K(t,,,_,, u)2]

< 2(1 + E)[(tm/t)2 +4]K(t, u)2 < 16(1 + -)K(t, u)2, and so (log 2)11J(.,f('))IIe,q <4 IIu11Ja.4(x) <

E Je,q(X)and

u)IIo,q.

We now show that the K- and J-functionals are dual to each other.

Interpolation Spaces

324

Lemma B.4 If X0 fl X 1 is dense in X0 and in X1, then Xo fl X 1 is dense in Xo + X1, and X * = (Xo, X i) is a compatible pair of Banach spaces. Moreover,

Xo + X- = (Xo fl X1)*

and Xo fl x * = (Xo + X1)*,

with equal norms. In fact, for each t > 0,

K(t, g; X*) =

J(t, g; X*) =

I (8, u)I

sup

0 uExonx, J(t- , u; X) sup '05kuEXo+X,

and

I (g, u) I

K(t-1, u; X)

Proof. Given u = uo + u 1 E Xo + X1, the density assumption means that we can find sequences uo,,, and u 1 in Xof1X1 such that uj,» -+ uj in Xj as m --* oo. Define u», = uom + U lm E Xo fl X1, and observe that um - u = (uo,,, - uo) + (ulm-u1),So llu»,-uIlX0+x, Um U in Xo + X1, showing that Xo fl X 1 is dense in Xo + X 1. Also, the continuous dense inclusion Xo fl X2 c Xi gives an imbedding X! c (Xo n X1)*, so Xo and X i can be viewed as subspaces of (Xo fl X 1)*, and hence form a compatible pair.

Let g E Xo + X i , and take any decomposition g = go + gl with gj E X . For U E Xo fl x 1, the Cauchy-Schwarz inequality implies that

I(8 u)I

(so, u)+(81, u)I

so I(g, u)I < K(t, g; X*)J(t-1, u; X). In particular, by putting t = 1 we see that g e (Xo fl X1)* and llgH(xonx,)- < llgllxo+x; Conversely, let g E (Xo fl X 1) * and put

M, =

sup o#uExonx,

I(8,u)I

J(t-1, U'; X)

We equip the product space Xo x X 1 with the norm II(uo, ul)Ilxoxx, = (IIuollX0

+t-211U1112)'11,

and denote the diagonal subspace by W = {(u, u) : u E Xo fl X1 }. Now define a linear functional g w on W by

(gw, (u, u)) = (g, u)

for it E Xo fl X1,

The J-Method

325

and observe that

I(gw, (u, u))I < M,J(t-', U; X) = M, II (u, u)Ilx0Xx

so the Hahn-Banach theorem gives (go, g1) E Xo x X = (Xo x X 1)* such that

(gw, (u, u)) = ((go, gi), (u, u)) = (go, u) + (gi, u) for u E Xo fl X1, and II(go, g1)Ilxoxx; _ (IIgoIIXo +t211g11IX1/2 = M,.

Hence, g = go + gi E Xo + Xi, and K(t, g; X*) < M. In particular, putting t = 1 gives Ilgllxo+x; < M1 = IIgll(xonx,)»

Next, let g E Xo fl X. If u = uo + u1 E Xo + X1, then 2»

2

2 112(IIu ollXo 2 I(g, u)I = I(g, uo)+(g, u1)1 _ (Ilgllxo+t IISIIX,)

+t-211u111X')1I2,

so I (g, u) I < J (t, g; X*)K(t-', u; X), and by putting t = 1 we see that g E (Xo + X1)* with Ilgllxo+x,)» <_ Ilgllxonx;

Conversely, let g E (Xo + X1)*, and put

M, =

Ifu X, then l(g,u)I

sup

I(g,u)I

O#UEXO+X, K (t-1

, u; V X)

<M,K(t-1-,u; X)<Mtmin(IIullxo,t-1IIulIx,),show-

ing that g E Xo fl X j . Given E > 0, we can find u1 E Xj such that

(g, uj) < Ilgllxj < (1 +E)(g, uj)

and

IIuj IIx, = 1.

(In particular, (g, uj) isreal.)PutAj = 1181Ix;,sothat 11811X. < (1+E)(g. AJu) and J(t, g; X*)2 < (1 + E)(g, ),ouo + t2)1u1)

_< (1 +E)M,K(t-1, Aouo+t2A1u1; X)

< (1

+E)Mt(IR,Xouol12

(1 + E)Mt(IIgIIXo +

+t-2IIt2A1u11IXYi2

(1 + E)M,J(t, g; X*).

Hence, J(t, g; X*) < Mt, and in particular IISIIxanx; < IIg11(x,,+x,)

0

Interpolation Spaces

326

Theorem B.5 Assume that Xo fl X1 is dense in Xo and in X1. If 0 < 0 < I and 1 < q < coo, then X0 fl X 1 is dense in Xe,q and (Xo, X i

where

.q = (Xo, X')e.q-,

*+ 1

1

q*

q

1

= 1,

with equivalent norms.

Proof Let u E Je,q (X) have a representation (B.7), and define u,,, E Xo fl X

1

by f(t)GIt

un, =

JI/m

t

Since

e

u 11 J".' (X) < (JO.1,,I1)U(,fl.OO) I t

J (t, f (t))

-) t

jdt

11q

we see that u,,, -+ u in Je,q (X), and hence Xo fl x 1 is dense in Xe,q. Thus, the inclusions Xo fl x 1 c Xe,q c Xo + X 1 are continuous and have dense images, so by Lemma B.4,

Xo fl Xi c (X9,q)* c Xo + x

.

It suffices to show that there are continuous inclusions c KK,q(X)*

and

Je,q(X)* 9 Ke.q*(X*)

Let g E Je,q=(X*), and take any 0 : (0, oo) -+ Xo fl x* such that

8=

f

000(t) dt, t

with the integral converging in Xo + X* = (Xo fl X1)*. For any u E Ke,q(X), I(8, u)I _5

f

00

1(0(t), u)I dt <

f

x J(t, 0(t); X*)K(t-1, u; X)

dt

< 11tH J (t, 0 (t); X*) 11 e,q 11 t H K (t-', u; X) II _e.q' so 1(g, u)1:5 1181IJA.,,.(x*) Ii t H K(r', u; X)11-e,q showing that g E Ke,q (X )* and II g II K .q (x)

II

u; X) 110,q,

NO, q' II B II JJ.q«

Now let g E Jo.q(X)*. Given c > 0, we can use Lemma B.4 to find a piecewise-constant function >1t : (0, oo) -+ Xo fl X1 such that (g, sli(t)) is real,

The J-Method

327

and

(g, fi(t))

K(t-', g; X*) < (1 +E)

J(t, fi(t); X) For any measurable function f : (0, oo) -f (0, oo) such that II f Ile,q < oo, the integral

f (t) * (t)

00

of = J

dt

J(t, *(t); x) t

defines a vector U f E Je,q (X) satisfying II u f II Jd.q cx) < II f Il o,q We choose f

so that

I

00

K(t-',

dt

g; X*)f(t) t = lit H K(t-' , g; x*)II _e ,q =jjK(-.g;X*)jjo,7»

and II f 11 0,7 = 1. Thus,

11

g; X*)11O.q» <

f

00

(1 + E)

o

(g, fi(t))

f(t) dt t

J(t, *(t); x)

(1

= (1 + E)(g, Uf)

(X) _< (1


showing that g E Ko,q»(X*) and

D

The next result is known as the reiteration theorem.

Theorem B.6 Let 1 < q < oo, and for j = 0 and 1 put (Xej,q

Y'=jl X3

if0
If 00 # 91, then (Yo, Yi),1.q = (Xo, Xi)e.q

for 9 = (1 - ri)9o + n91 and 0 < i < 1.

Proof. Let U E K,1,q(Y). For any uj E Yj such that u = uo + u1, we have K(t, at; X) < K(t, uo; X) + K(t, u1; X) < Ct°'Iluo11yo + Cto' IIu111r,

<

Cto°[IIuoIIY°+t2(0,-O,)IIu111r,]112,

where, in the second step, we use Lemma B.1(ii) if 0 < 9j < 1, or (B.5) if 9j E {0, 11. Hence,

K(t, u; X) < Cto0K(to'-o0, u; Y),

Interpolation Spaces

328

and therefore the substitution t = t°' -°o gives

< C f 0" It-°t°0K(t°,-°°,

q

f0

f

=C

u; Y) Iq

dt t

It-nK(t,u;Y)Ig101-9o1

dr

(B.8)

t

= C191 -00,11Ul1K,q(Y)

for 1 < q < oo, with II u II

K9..,,(x)

< C sup t-ete° K (te' -e0, u; Y) = C sup r-" K (r, u; Y) = C 11U II K,,..(Y) t>o

r>o

in the limiting case q = oo. Thus, Y,1,q c Xe,q.

Conversely, let u E X°,q, and take any representation of the type (B.7). By (B.6), 00

t°OK(t°'-e°, u; Y) < f

t°OK(te,-e0, f (s); Y) ds S

o

<

r

t°° min (1, (t/s)el -eo) J(se,-eo, f(s); Y)

Jo

d s

Using Exercise B.2 if 0 < 9j < 1, or just the definition of the J-functional if 9j = j, we see that 11f (s) II Y; < Cs-0j J(s, f (s); X) and so j (SO, -°D, f (S); Y) =[11f(S)11 y°+ S2(e, -e0)

II f (S) II Y1

]1/2 < CS-26° j (S' .f (s); X)

Thus, with the help of the substitution s = at,

x teOK(te'-e0, u; Y) < C

Jo

= C f "0

min ((t/s)°°, (tls)°')J(s, f (s); X) mina-°°,

a-'91)J (at, f (at); X)

ds s

da ,

and hence by (B.8), IIUIIK,,.a(Y) =

1

let-eol

11t i-+ t °o K(t°' -°°, u; Y)II°,q

too

< CJ min(a-OD,a-°')IIt )-+ J(at, f(at); X)II °,q da Q

0

p

=CJ

0

a ° min(a-°0, a-A')

It It H J(t, f(t); X) II °,q

Interpolation of Sobolev Spaces

329

Finally, taking the infimum over all f satisfying (B.7) gives

II u II K,,.,, (Y)

C11 u11 j,,, (x), proving that Xo,q c Y,?,q.

Interpolation of Sobolev Spaces If Xo and X1 are Sobolev spaces on R", then the K-functional can be computed explicitly via the Fourier transform, allowing us to prove the following.

Theorem B.7 If so, s! E R, then (HS0(I8"), H`' (Il8"))8,2 = H'(R")

for s = (1 - 9)so + 9s1 and 0 < 9 < 1.

Moreover, the Sobolev norm (3.21) equals the Ko.2-norm if, instead of the default

normalisation (B.4), we take NB,q

=

(2sinir9\'2 J

(B.9)

n

Proof. Let u = uo + u1 with ui E H''i (1R") for j = 0 and 1, and observe that

f [(1 + I

+t2I1U1112H

I2)S°luo( )I2

+ t2(1 + I 12)s' Iu 1(4)12]

Since u () = uo

u

we see from Exercise B.4 that for each

integrand is minimized when uo and u 1 are such that

t2(1 +

t2(1 +

(1 +

t2(1 +

(1 +

It follows that t2(1 +

K(t, u; HS0(18"), HS' (R"))2

J =

(1 +

t2(1 + 112)s

j(l + ,I

where

a(') = (1 + 1

+t2

lu()I2d

the

Interpolation Spaces

330

Thus,

IIK(, u)IIa2 =

f

(1 + 1

11f 110.2]21u( )12 d = Il.f

,1

and we have only to apply Exercise B.S.

We also have an interpolation theorem for Sobolev spaces on domains. Theorem B.8 Let S2 be a non-empty open subset of R. If so, s 1 E R, then

(HS0 (0), HS' (52))9,2 = H'(Q)

for s = (1 - 9)so + 9s1 and 0 <0 < 1.

Moreover, the Sobolev norm (3.23) equals the KB,q-norm if the latter is normalised by (B.9). Proof Put X j = HS' (S2) and Yj = Hs; (IIR") Let U E HS (a), and choose U E HS (R") such that u = U I n and II U 11 H= (2) _ II U II H'(R^) Take any decomposition U = Uo + U1 with Uj E Yj, and observe that since u = uo + u1, where u j = Uj Isi E X j, we have

K(t, u; x)2 <

IIuoIIX° +t211u111X,

IIUO112 +t211U111y,,

and thus K (t, u; X) < K (t, U; Y). It follows by Theorem B.7 that u E K9,2 (X) with IIuIIKB.2(x) <- II UII K0.2(Y) =

IIUIIHI(Q)

Conversely, let u E K9,2(X), and take a decomposition u = uo + ul with U j E X j. Choose U j E Y j such that u j= U j I sz and II u j II x1 = II Uj II r; , and put

U = Uo+U1 E Yo+Y1. We have K(t, U; Y)2 < IIUoIIy° 2 +t21IU1IIY, = IIuoIIX° +t21Iu11IX1 ,

so K(t, U; Y) < K(t, u; X) and hence 11U11 K,., (y) < I1 u11KB.2(x) Since u = U

Theorem B.7 implies that IIuffH'(S) < IIUIIHsr(R") = IIUIIK0.2(Y) < IIUIIK9.2(x)

0 An interpolation result for HS (S2) follows at once, by duality; see Corollary 3.30 and Theorem B.S. Theorem B.9 Assume that 0 is a Lipschitz domain. If so, s1 E 1R, then

(R' m), HS' (S2))e 2 = HS(Q) with equivalent norms.

for s = (1 - 9)so + 9s1 and 0<0 < 1,

Interpolation of Sobolev Spaces

331

Our final result deals with Sobolev spaces on the boundary r = 8 Q. The proof makes use of the reiteration theorem (Theorem B.6) and a simple interpolation property of pivot spaces.

Lemma B.10 If H is a pivot space for V, then H = (V, V*) 1/2,2. Proof Let Y = (V, V *)1/2. z. By Theorem B.5 and Exercise B.7, Y* = (V*, V)1/2.2 = (V, V*)1-1/2.2 = Y, so if u E Y, then II u II H = (u, u) < II u II Y II u II Y < C II u II .. Hence, we have a

continuous, dense inclusion Y C H, and dually, H = H* c Y* = Y. Theorem B.11 Assume that 0 is a Cr-1,1 domain for some integer r ? 1. If so, S1 E R satisfy Iso I < r and is, I < r, then

(Hs0 (F), Hs' (r))0,2 = HS (r)

for s = (1 - 9)so + 9s1 and 0 <0 < 1, (B.10)

with equivalent norms.

Proof Suppose in the first instance that r is a Cr-1,1 hypograph, and recall the definition of Hs (F) for the two cases 0 < s < r and -r < s < 0, given in the discussion after Theorem 3.34. The interpolation property follows at once from Theorem B.7 if both so and sl belong to [0, r], or if both belong to [-r, 01. Furthermore, we claim that

(H-r(r), Hr(r))9 2

=

H2e-1(F)

for 0 < 0 < 1.

Indeed, the case 0 = z follows from Lemma B.10, after which the cases 0 < 0 < 1 and 1 < 0 < 1 follow with the help of Theorem B.6. Another application of Theorem B.6 then shows that (B.10) holds when one of the sj belongs to [0, r] and the other to [-r, 0). Suppose now that r is the boundary of Lipschitz domain in the sense of Definition 3.28. Thus, recalling (3.29), IIuIIHJ(r)

_

II01uII2W(r,).

If we put

X = (HS°(r),

HS' (r))

and

X1 = (HsG(rt), HS' (rt)),

Interpolation Spaces

332

then K9,2(XI).= Hs(rl) for each 1, and the problem is to show that Ke,2(X) _

Hs (r). Let U E HS(r). We choose cutoff functions Xi E C o p(R'1) satisfying XI = 1 on a neighbourhood of supp lpl, and supp X/ c W1, so that 4ru = X101u.

Take any decomposition 01 u = uro + u11 with Ulj E Hsi (I,1), and observe that

U = 2biU = EXIU1o+EX1U11, l

I

I

so 2

2

+ t2

H i (r)

H o (r)

C Y(IIXIUiOI Jpo(r) + t211Xru11 IIHr, (r)} I

C E(IlurollHxo(r,) + t211Un IIH,,(rv) I

Thus,

K(t, u; X)2 < C >2 K(t, 01u; X1)2, and therefore u E Ke,q (X) with IIUIIK9.Q(x)

Ilb1UIiK,(x,)

C

=IIuIIH=(r)

Conversely, let u E Ke,q (X) C Hmin(so,s,) (r). Taking any decomposition u = uo + ul with uj E Hs1(r), we have Olu = Oluo + (plug with O1u1 E Hsi (F,), so E[1101uoIIHw(r,)

K(t, 01 u; X1)2

+ tell

01UI

IIHs'(r,)]

l

1

=

IIUO112

+ t211u111H., (r)

and hence >1 K(t, 01 u; X1)2 < K(t, u; X)2. It follows that ¢IU E Ke,2(XI) _ HI (rl) for each 1, with IIuIIH= (r)

IIp1uIIKe.2(x,) -<

IIUI1K2e.

2(X)

El

Exercises

333

Exercises B.1 Suppose that AO : Xo -)- Yo and A : X 1 --* Y1 are compatible, and let u E Xo + X 1. Show that Aouo + A 1 u does not depend on the choice of 1

uo E X0 and U 1 E X 1 satisfying u = uo + u 1. B.2 Show that J(t, u) > to IIuIIK.,4(x). [Hint: use (B.6).] B.3 Give a direct proof of the interpolation property for Je,q (X), i.e., show that

Theorem B.2 holds if Ke,q is replaced by Jo,q. [Hint: J(t, Af (t); Y) < MoJ(at, f (t); X), where a = M1 /Mo.] B.4 Fix real numbers Ao > 0 and A 1 > 0, and a complex number z. Show that min (AoIzo12 + A1Iz112) =

z=zo+zi

AOA1

Ao + Al

Iz12,

and that the minimum is achieved whenAozo = A1z1-= AoA1z/(Ao+A1). B.5 Use contour integration to show that cc t 1-26

,r

1 + t2 dt

for 0 < 9 < 1.

2 sin r9

0

B.6 Show that if Xo and X 1 are complete, then so are Xo fl X 1, X0 + X 1 and

Xe,q for 0 < 9 < 1 and 1 < q < oo. [Hint: use Exercise 2.1.] B.7 Show that (X1, Xo)B,q = (Xo, X1)I-o,q for0 < 9 < 1 and I < q < oo. B.8 Assume that H, V and A satisfy the hypotheses of Corollary 2.38, and equip V with the energy norm II II A. By arguing as in the proof of Theorem B.7, show

K(t, u; H, V )2

= E 1+?

t2I(0;,u)12,

and deduce that for the normalisation (B.9), CO

IIUIIK9.z(H.v) =

E'Xjl(4),,

j=1

u)12 = IIAB"2uIl2.

Appendix C Further Properties of Spherical Harmonics

We shall prove a result (Corollary C.2) used in Chapter 9, and also construct the classical spherical harmonics, which form an orthogonal basis for xm Recall the definition of the Legendre polynomial Pn, (n, t) in the discussion following Lemma 8.6. (S2).

Theorem C.1 The orthogonal projection Q,n : L2 (5"-1) -> xm (S' -1) is given by the formula Q,n

,/ (CO) = N(n, m)

Pm (n, w 1) (r1) d?l

T. 4-1 form > 0, w E S' ' and it E

L2(S"-1).

Proof. Let (rmp : 1 < p < N(n, m)) be an orthonormal basis for

xm(S'

)

By part (i) of Exercise C.1, Qm 1F' (w) =

f

_

K(w, n)i(n) dn,

where

N(n,m)

'I, 'I' K(w, n) = E Y'mp(w) lmp(n) p=1

If A E

nxn

is an orthogonal matrix, then

J

*(Aw) dco =

J

*(w) dco for r E L1(S"-1),

and, by Exercise 8.3, the function co 1-* u(Aco) belongs to Rm(S") whenever u E xm (Sn-1). It follows by part (iii) of Exercise C. 1 that

K(Aco, An) = K(w, n) for co, n E Sr-1, 334

Further Properties of Spherical Harmonics

335

and in particular, when Aen = e we have K(Aw, en) = K(cv,

Since

w H K (co, e,,) belongs to ln, (S"-' ), if u is as in Lemma 8.6 then

K(w, en) = au(w) = aP.. (n, w en)

for w E S"_ 1,

where a = 1/K(en, en). Given r! E Sn-1, choose an orthogonal matrix A E Rnxn such that Ail = en; then K(w, rl) = K(Aw, en) = aP.,(n, Acv en)

Finally, since K(w, w) = aP,n(n, 1) = a, we see that N(n,m)

aTn=

f ,-

K(w,co)dw= E Il*mpllL,

,

p=1

giving a = N(n, m)/Tn.

O

The proof above also establishes the addition theorem.

-

Corollary C.2 If (if,np : 1 < p < N(n, m)) is an orthonormal basis for xm (Sn-1), then N(n,m)

'

for w, )l E Sn-'

(CO) Y',np (11)

P=I

The next result is known as the Funk-Hecke formula.

Theorem C.3 Let f : [-1, 1] -+ C be a continuous function. If m > 0, then

f (w rl)(n) drf = A(w) for* E 71 fS.-I

where

= Tn-1

f

f (t)Pm(n, t)(1 -

t2)(n-3)/2

dt.

(C.1)

Proof We begin by showing that f (l; w) Pm (n, rl co) d w = A Pm (n, l; rl)

fore, rl E Sn-' .

(C.2)

rl) to be the left-hand side of (C.2), and observe that for a fixed l;, Define Also, if A E RI"" is an the function >) r-# F(l;, r7) belongs to

Further Properties of Spherical Harmonics

336

orthogonal matrix, then F(A4, Arl) = F(4, rl), so by arguing as in the proof of Theorem C.1 we see that ,XP,,, (n, rl) for some constant .l. Since

Pm(n,1)=1, I = XPm(n, 1) = F(en, en) =

f

f(en w)P,n(n, en W) do),

S`n-I

and the formula (C.1) follows by Exercise C.2. Thus, (C.2) holds, and upon multiplying both sides of this equation by *(q), where 1/r E xm (Sn- t ), and integrating with respect to q, we have

f

S.-I

f(

. w)

\

Sn

-

Pm(n, n

w)*(rl) drl dw

I

fs.-I

P. (n,

rl)*(rl) dil.

Applying Theorem C.l, the result follows at once. We now begin our construction of an explicit orthogonal basis for H. (S! I- ),

starting with the case n = 2. Remember that 1-1o(Sn-1) consists of just the constant functions on S", so it suffices to deal with m > 1. Lemma C.4 Let 9 be the polar angle in the usual parametric representation of the unit circle S1, co = (cos9, sin 9).

If m > 1, then N(2, m) = 2 and the functions cosm9

1rm1(w) _

and

*,n2 (W)

1/7-r

r7r

sin m9

form an orthonormal basis for Hm (S1)

Proof. We have seen already in (8.13) that N(2, m) = 2 form > 1. Define two real-valued solid spherical harmonics u 1, u2 E Nm (R2) by u1(x) + iu2(x) = I (x1 + ix2)m,

and observe that 1lrn,1 and i/r,,i2 are the corresponding surface spherical harmonics in 11m (S1), i.e., 1/ m p = u p is, for p = 1 and 2. One readily verifies that *,,l and

1/rm2 are orthonormal in L2(S1).

Any non-trivial function Amj (n, t) satisfying the conclusion of the next theorem is called an associated Legendre function of degree m and order j for the dimension n.

Further Properties of Spherical Harmonics

337

Theorem C.5 Assume n > 3, let 0 < j < m, and define

A,nj(n, t) = (1 - t2)jj2Pm-j(n +2j, t).

(C.3)

If i/r E ?-l j (Si-2) and

where co =

W(co) = A,nj (n, t)i/r(r1),

then

1 - t2 n + ten and rl E gi-2,

E fm(Sn-1)

Proof For any 1(r E L i (Sn-2), the formula

u(x) = f-2(xn + ix' )'n

(

) dt

defines a solid spherical harmonic of degree m, whose restriction to S"-' may be written as

u(w)=f (t+i 1-t2 r! If we now assume that and Exercise C.5,

E

?j j (S, -2), then by Theorem C.3, Exercise C.4(ii)

t

u(w) = Tn-2*(r1) f (t + i l - t2 s)mPj(n - 1, s)(1 = cl (17) (1 - t2)'/2

J

(t + i l - t2 1

s)m-I (1

-

s2)(n-4)/2

ds

s2)r+(n-4)/2

ds

= c2i(11)(1 - t2)j/2Pm- j(n + 2j, t) = c2`1(w), where the constants cl and c2 depend on n, m and j. Thus, 41 E ?-lm claimed.

(S"), as

Combining Theorem C.5 and Exercise C.6, and recalling (8.12), we see how to construct an orthogonal basis for W n (S"-1) by recursion on the dimension n. Corollary C.6 If {7(rjp

x j (Sn-2), and if

:

I < p < N(n - 1, j)) is an orthogonal basis for

q'mjp(w) = Amj(n, t)'Yjp(q),

where w =

1 - t2 q + ten and r1 E Sn-2,

then {Wmjp:O < j < m and 1 < p < N(n - 1, j)) is an orthogonal basis

Further Properties of Spherical Harmonics

338

for H,n (Sn-1), and

N(n + 2j, in - j) T +2l! 1 II*jP ,(S,,-2) In particular, taking n = 3 and using a basis for fl3(S1) of the type in Lemma C.4, we arrive at the classical spherical harmonics. Theorem C.7 Use the standard parametric representation for the unit sphere S2,

w = (sin 0 cos 0, sin 0 sin 0, cos 0) for 0 < 0 < 2ir and 0 < 0 < rr.

If in > 1, then N(3, m) = 2m + 1 and the functions *mo (w) = Pn, (3, cos 0),

*mj (w) = (sin Ql )' Pm_j (3 + 2j, cos 0) cos j O for 1 < j < m, YIm.m+i (w) = (sin 1)i

Pm_j (3 + 2j, cos ¢) sin jO for 1 < j < m,

form an orthogonal basis for lm (52), With II1f,no II L2(s2) = 4n' and T3+2i

It

'I, II

n=; II L2cs2) = IIY'm.m+J HL,(S2) =

N(3 + 2j, m - j) T2+2j

for 1 < j < m.

Exercises C.1 Suppose that (S, p) is a measure space, and let Q be the orthogonal projection from L2(S, µ) onto a finite-dimensional subspace V. (i) Show that if {¢p)n 1 is an orthonormal basis for V, and if we define N

K(x, y)

LOp(x)Op(y), p=1

then

Qu(x) =

Js

K(x, y)u(y) dµy

for x E S and u E L2(S, µ).

(ii) Show that the kernel K does not depend on the choice of the orthonormal basis for V.

(iii) Suppose that a group G acts on S, and that µ and V are invariant under G, i.e., if g E G, then

u(gx) d,i = J f u(x) d/.L s

s

for u E L1 (S, A),

Exercises

339

and

x H u (gx) belongs to V whenever u E V.

Show that the kernel K is invariant under G, i.e., if g E G then K(gx, gy) = K(x, y) for x, y E S. C.2 Show that if f is, say, continuous on Si-1, then

f Jg f

(co)

f

dw =

I I

Jg,-2

f

1 - t2 >7 + te,i) d>) (1 - t2)(n-3)/2 dt.

C.3 Prove the orthogonality property of the Legendre polynomials:

f

T.

1

1

P., (n, t)PI(n, t)(1 - t2)(n-3)l2dt =

N(n, m) Tn_1

1

smI

form >Oandl >0. [Hint: use Theorems C.1 and C.3.]

C.4 For n > 2 and m > 0, let m

P n

(t) = (1 -

t2)-(n-3)/2-d

dtm (1

-

t2)m+(n-3)/2

(i) Show that pm is a polynomial of degree m. (ii) Use integration by parts to show that if, say, f E C'n [-1, 1], then

f

f(t)Pm(t)(1 - t2)(n-3)/2dt 1

j f ('n) (t) (1 -

t2)m+(n-3)/2

dt.

(iii) Deduce the orthogonality property fJ

Pm(t)PI(t)(1 -

t2)3/2 dt = 0

if m

(iv) Find pm(1), and conclude from Exercise C.3 that

(-),n

P(n, t) _ (n+2m-3)(n+2m-5)...(nresult known as the Rodrigues formula.

1)

C5 Show that

P.(n,t)=

1

Tn-t

g,-z

(t+i

foralla)

ES"-2,

Further Properties of Spherical Harmonics

340

and then derive the Laplace representation,

P. (n, t) =

Tn-1

j (t + i

1 - t2 s)m (1 -

s2)(n-4)12 ds

for n > 3.

[Hint: use Theorem C.3 with f (s) = (t + i 1 - t2 s)m and 1/r = 1 E ? jO(Sn-2).)

C.6 Suppose n > 3, and let Am j (n, t) be the associated Legendre function (C.3).

Show that for *1, *2 E C(Sn-2), if and

IPi(W) = Amj(n, where W =

42(W) = Amj(n,

1 - t2 + ten, then

('P1, W2)L20°-i) =

1

N(n + 2j, m - j)

(*I,

2)

Tn+2j-1L2(5-z).

References

[1] M. Abramowitz and I. Stegun, Handbook of Mathematical Functions, Dover, New York, 1970. [2] R. A. Adams, Sobolev Spaces, Academic Press, 1975. [3] K. E. Atkinson, The Numerical Solution of Integral Equations of the Second Kind, Cambridge University Press, 1997. [4] A. Beer, Allgemeine Methode zur Bestimmung der elektrischen and magnetischen Induction, Ann. Phys. Chem. 98 (1856), 137-142. [5] J. Bergh and J. Lbfstrbm, Interpolation Spaces - An Introduction, Springer, 1976. [6] Yu. D. Burago and V. G. Maz'ya, Potential theory and function theory for irregular regions, Seminars in Mathematics, Volume 3, V. A. Steklov Institute, Leningrad. (English translation: Consultants Bureau, New York, 1969.) [7] G. Birkhoff and U. Merzbach, A Source Book in Classical Analysis, Harvard University Press, 1973. [8] A. P. Calderbn, Lebesgue spaces of differentiable functions and distributions, Partial Differential Equations, Proc. Sympos. Pure Math. 4 (1961), 33-49. [9] A. P. Calderdn, Cauchy integrals on Lipschitz curves and related operators, Proc. Nat. Acad. Sci. U.S.A. 74 (1977), 1324-1327. [10] J. Chazarain and A. Piriou, Introduction to the Theory of Linear Partial Differential Equations, North-Holland, 1982. [11] R. R. Coifman, A. McIntosh and Y Meyer, L'integrale de Cauchy definit un operateur borne sur L2 pour les courbes lipschitziennes, Ann, of Math. 116 (1982), 361-387. [12] D. Colton and R. Kress, Integral Equation Methods in Scattering Theory, Wiley, 1983.

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[66] S. G. Mikhlin and S. ProRdorf, Singular Integral Operators, Springer, 1986. [67] C. Miranda, Partial Differential Equations of Elliptic Type, Second Revised Edition, Springer, 1970. [68] D. Mitrea and M. Mitrea, Generalized Dirac operators on nonsmooth manifolds and Maxwell's equations, preprint.

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[71] N. I. Muskhelishvili, Singular Integral Equations: Boundary Problems of Function Theory and Their Application to Mathematical Physics, Nordhoff, 1953. [72] J. Ne6as, Les Methodes Directes en Theorie des Equations Elliptiques, Masson, Paris, 1967. [73] J. Ne6as and I. Hlavacek, Mathematical Theory of Elastic and Elasto-plastic Bodies: An Introduction, Elsevier, 1981. [74] J. C. Nedelec, Curved finite element methods for the solution of singular integral equations on surfaces in R3, Comp. Methods Appl. Mech. Engrg. 8 (1976), 61-80. [75] J. C. Nedelec, Integral equations with non-integrable kernels, Integral Equations Operator Theory 4 (1982), 563-572. [76] J. C. Nedelec and J. Planchard, Une m6thode variationelle d'6lements finis pour la resolution num6rique d'un probl6me ext6rieur dans R3, R.A.I.R.O. 7 (1973) R3, 105-129. [77] C. G. Neumann, Zur Theorie des logarithmischen and des Newtonschen Potentials, Ber. Verhandlungen Math. -Phys. Classe Konigl. Sachs. Akad. Wiss. Leipzig 22 (1870), 49-56, 264-321; reprinted in Math. Ann. 11 (1877), 558-566. [78] L. Nirenberg, Remarks on strongly elliptic partial differential equations, Comm. Pure Appl. Math. 8 (1955), 648-674. [79] J. A. Nitsche, On Korn's second inequality, R.A.I.R.O. Model. Math. Anal. Numer. 15 (1981), 237-248. [80] F. Noether, Uber eine Klasse singularer Integralgleichungen, Math. Ann. 82 (1921), 42-63. [81] L. E. Payne and H. F. Weinberger, New bounds for solutions of second order elliptic partial differential equations, Pacific J. Math. 8 (1958), 551-573. [82] H. Poincar6, La m6thode de Neumann et le probl6me de Dirichlet, Acta Math. 20 (1896-1897), 59-142; reprinted in Oeuvres de Henri Poincare, Volume 9, pp. 202-272. [83] H. Rademacher, Uber partielle and totale Differenzierbarkeit von Funktionen mehrer Variabeln and fiber die Transformation der Doppelintegrale, Math. Ann. 79 (1919), 340-359. [84] F. Rellich, Ein Satz fiber mittlere Konvergenz, Gottingen Nachr. (1930), 30-35. [85] F. Rellich, Darstellung der Eigenwerte von Au + ku = 0 durch ein Randintegral, Math. Z. 46 (1940), 635-636. [86] F. Rellich, Uber das asymptotische Verhalten der Losungen von AX + Au = 0 in unendlichen Gebieten, Jber. Deutsch. Math. Verein 53 (1943), 57-65. [87] F. Riesz, Uber lineare Funktionalgleichungen, Acta Math. 41 (1917), 71-98. [88] F. Riesz and B. Sz.-Nagy, Functional Analysis, Frederick Ungar, 1955. [89] Ja. A. Roltberg and Z. G. Seftel, On equations of elliptic type with discontinuous coefficients, Dokl. Akad. Nauk SSSR 146 (1962), 1275-1278; English summary in Soviet Math. Dokl. 3 (1962), 1491-1494. [90] M. Schechter, A generalization of the problem of transmission, Ann. Scuola Norm. Sup. Pisa 14 (1960), 207-236. [91] M. Schechter, Principles of Functional Analysis, Academic Press, 1971. [92] L. Schwartz, Theorie des Distributions, Hermann, Paris, 1966. [93] R. T. Seeley, Extensions of C1 functions defined in a half space, Proc. Amer. Math. Soc. 15 (1961), 625-626.

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[94] G. F. Simmons, Introduction to Topology and Modern Analysis, McGraw-Hill, 1963.

[95] V. I. Smirnov, A Course of Higher Mathematics, Volume IV, Pergamon and Addison-Wesley, 1964. [96] E. M. Stein, Singular Integrals and Differentiability Properties of Functions, Princeton University Press, 1970. [97] J. W. Strutt (Lord Rayleigh), On the theory of resonance, Phil. Trans. Roy. Soc. London 161(1870), 77-118. [98] W. Ritz, Uber eine neue Methode zur LSsung gewisser Variationsprobleme der mathematischen Physik, J. Reine. Angew. Math. 135 (1908), 1-61. [99] S. P. Thompson, The Life of William Thomson, Baron Kelvin of Largs, Macmillan, London, 1910. [100] C. Truesdell, Notes on the history of the general equations of hydrodynamics, Amer. Math. Monthly 60 (1953), 445-458. [101] C. Truesdell, Essays in the History of Mechanics, Springer, 1968. [102] G. Verchota, Layer potentials and regularity for the Dirichlet problem for Laplace's equation in Lipschitz domains, J. Funct. Anal. 59 (1984), 572-611. [103] V. Volterra, Opera Matematiche, Accad. Lincei, 5 volumes, 1954-1962. [104] H. Weber, Uber die Integration der partiellen Differentialgleichung

82u/axe + 82u/aye + k2u = 0, Math. Ann. 1 (1869), 1-36. [105] H. Whitney, Geometric Integration Theory, Princeton University Press, 1957. [106] K. Yosida, Functional Analysis, Sixth Edition, Springer, 1980.

Index

Adjoint (formal) of a differential operator, 116 of an abstract linear operator, 37, 43 of conormal derivative operator, 201 of trace operator, 201 Annihilator of a subspace, 23 Arzela-Ascoli theorem, 28 Associated Legendre function, 336, 340 Beer, A., 11 Beltrami operator, 277 Bessel function, 278 spherical, 279. 293 Bessel potential, 75 Bochner integral, 321 Boundary integral equation and logarithmic capacity, 264, 275 for Dirichlet problem, 226 for exterior problem, 236 for problem with mixed boundary conditions, 231 for Neumann problem, 229,242 side condition for, 262. 274 Boundary integral operator (Schwartz) kernel of, 220, 223 adjoint of, 218 arising from a self-adjoint differential operator, 218 arising from the Laplacian, 248, 249 definition of, 218, 233 mapping properties of, 219, 245 on an open surface, 275 symbol of, 244, 275

Calderdn, A. P., 309 Calderbn projection, 243 Capacity, 263 and exterior Dirichlet problem, 271 behaviour under dilatation, 272

logarithmic, 264 and conformal mapping, 271 of a line segment, 275 of an ellipse, 272 of an open surface, 275 variational characterisation of, 272 Cauchy-Riemann equations, 2 Cauchy-Schwarz inequality, 54 Chebyshev polynomials, 255 explicit solutions in terms of, 272, 273 Codimension, 18 Coercivity abstract definition of, 44 for differential operators, 118 change of coordinates, 156 on H 1(12), 122, 126 on Ha (0), 119 for elasticity operator, 298, 299 for hypersingular integral operator, 230 Compact linear operator, 28 properties of, 54 transpose of, 29 Compact subsets of LN, 28 Compatible pair of normed spaces, 317 Completely continuous linear operator, see compact linear operator Conjugate exponent, 58 Conjugation, 37 Conormal derivative, 114 L2 estimates, 149 generalised, 117 relative to the formal adjoint, 116 Convergence in D(S2), 65 in E(S2), 65

in E(S2) but not in D(P), 109 in S(]R' ), 72 Convex set, 38

347

348

Index

Convolution, 58 and approximation, 63, 111 and differentiation, 62. 109 and Fourier transform, 73 associativity of, 108 support of, 108 Cooling-off problem, 157 Costabel. M., 102, 202 Cutoff function, 83

d'Alembert, J., 2 Density of Cm p(S2) in L p (c ). 63 of D(S2) in E(S2), 109

of D(Q) in Hs(9), 77 of D(R") in S(R"), 109 of D(S2) in H'(Q), 111 of S(R11) in E(W), 109 of D(S2) in W" (Q), 91 of Ws (0) fl E(92) in Ws(S2), 86 Dirac delta function(al), 66 convolution with, 68 homogeneity of, 187 Dirichlet form, 246 Dirichlet problem, 4 solution operator for, 145 Dirichlet's principle, 8 abstract form, 55 Dirichlet, P., 8 Distribution, 65, 109 multiplication with a smooth function, 68

of form u(a x), 189 partial derivative of, 67 temperate, 72 with compact support, 67 Divergence theorem, 97 Domain Lipschitz, see Lipschitz domain 89 of class Ck, 90 of class 90 Double-layer potential, see surface potential du Bois-Reymond, P., 12 Dual space, 20 of Lo, 58, 107 of a Sobolev space, see Sobolev spaces, duality relations realisation of, 27

Eigenfunction expansions, see spectral theory Eigenvalue, 45 Elasticity operator, 297 Energy inner product, 44 example from linear elasticity, 298 Epigraph, 186, 316 Equicontinuous set of functions in C(X), 28 in LP, 28

Equilibrium density, 263 Euler, L., 2 Extension operator, 81, 309, 313 non-existence of, 316 Seeley, 316

External conformal radius, 271 Far-field pattern, 294 Finite part, 159 Finite-part extension differentiation of, 169 homogeneity of, 162, 166, 168 in n dimensions, 166

ofx'k-1, 164 of x+, 160 Finite part integral change of variables formula, 177, 180 hypersingular integral operator. 223 on a surface, 181 Fourier transform, 70 inversion theorem, 70 of a homogeneous distribution, 172, 173, 189

of a temperate distribution, 72 of partial derivatives, 72 of f.p. u, 174 Fourier, J.-BA., 4 Fredholm alternative, 14, 37, 43 for boundary integral equations, 226, 228, 229, 240 for coercive operators, 44 for the mixed boundary value problem, 128 for the third boundary value problem, 131 relation to eigensystem, 51 Fredholm equation of the second kind, 13 abstract theory, 30, 35 Fredholm operator, 32 Fredholm, 1., 13 Fundamental solution, 191, 197 for elasticity operator, 300 for Laplacian, 2, 11, 247, 268 for the Helmholtz operator, 279 radiating, 282 integral formula for, 198 series expansion of, 255, 284 Funk-Hecke formula, 335

Gamma function, 169, 188 Gauss, C. F., 7 Generalised function, 66 Green identity first, 4, 114, 116, 1 1 8, 141

first, dual version of, 115, 118, 141 second, 4, 118 third, 5, 202

dual version of, 211 with radiation condition, 235

Index Green's function, 5 symmetry of, 16 Green, G., 4, 8

Hadamard, J., 159 Hahn-Banach theorem, 20 Hankel function, 280 spherical, 281, 293 Hardy's inequalities, l 11, 112 Harmonic analysis techniques, 209 Heat equation, 4 Helmholtz equation, 276 radiating solution of, 281 Hermitian sesquilinear form, 43, 116 Hilbert space, 38 best-approximation properties, 38, 39 dual of, 41, 42 weak sequential compactness in, 42 Hilbert, D., 14 Holder's inequality, 58 Homogeneous distribution, 158 derivatives of, 187 Homogeneous function, 158 and change of variables, 175 derivatives of, 187 orthogonality condition for, 167 parity condition for, 168, 169, 175 Hypograph, 186 of class C't, 90 Lipschitz, see Lipschitz hypograph Image, 18 Imbedding of S* (W) in D* (W), 72

of L11(2) in D`(S2), 66 Index of a Fredholm operator, 33 compact perturbation, 36 homotopy, 54 small perturbation, 54 Inner product, 38 Interpolation of normed spaces, 318 duality properties, 324, 326

J-method, 322 K-method, 319 reiteration theorem, 327 Inverse point with respect to a sphere, 259, 270 J-functional, 322 Jump relations, see surface potential K-functional, 318 determined by a positive-definite, self-adjoint operator, 333 for Sobolev spaces, 329 Kelvin transform, 259, 270 Kelvin, Lord, see Thomson, W.

349

Kernel (null space), 18 of boundary integral operator, 240 Helmholtz equation, 288 Laplacian, 267 linear elasticity, 304 Kom's inequality first, 298 second, 299, 305 Lagrange, J.-L., 2 Lame coefficients, 296 Laplace equation, 1 Laplace operator, 246 eigenvalues of, 249 rotational invariance of, 268 Laplace, P. S., 3 Lax-Milgram lemma, 43 Le Roux, J., 12 Legendre polynomials, 255 generating function for, 269 Laplace representation, 340 orthogonality property, 339 recurrence relation for, 269 Rodrigues formula for, 339 Liouville, J., 6-8 Lipschitz dissection, 99 Lipschitz domain definition, 89 non-examples of, 90 outward unit normal to, 96 surface element for, 96 Lipschitz hypograph, 89 Locally integrable functions. 64

Meyers-Serrin theorem, 85 Modulus of continuity, 60, 110 Mollifier, see convolution Multi-index, see partial derivative Ne&as, J., 123, 126, 147 Nedelec, J. C., 289 Neumann, C., 10, 12 Newtonian potential, see volume potential Nirenberg, L., 133 Nitsche, J. A., 305 Noether, F., 33

Open mapping theorem, 19 Orthogonal complement, 40 Orthogonal projection, see projection, orthogonal

Parametrix, 192 adjoint of, 197, 211 behaviour of kernel, 195 mapping property for, 193, 197

350

Index

Partial derivative, 61 weak, 74 Partition of unity, 83 and Sobolev norm, 111, 331 Peetre's inequality, 88, 110 Pivot space, 44 interpolation property of, 331 use of L2, 118 Plancherel's theorem, 73 Poincard, H., 10, 13, 145 Poisson integral formula, 5 Poisson's equation, 15

Poisson, S: D., 3-6 Positive and bounded below, 43 boundary integral operator, 262, 264, 267, 275 Potential electrostatic, 3, 5, 263 gravitational, 3 surface, see surface potential vector, 292 volume, see volume potential Principal part, 114 and coercivity, 118 Principal value, 166, 190 Projection, 20 orthogonal, 40, 54

Quotient norm, 19 Quotient space, 18 Radiation condition, 234, 243 for the Laplacian, 259 Sommerfeld, 281, 283, 294 Reflexive Banach space, 22, 37 Regulariser, 35 Regularity theory for boundary integral equations, 239 interior, 135,196 up to the boundary, 137 Relatively compact set, 27 Rellich-Payne-Weinberger identity, 146

Rellich, F., 87, 147, 286 Riesz representation theorem, 40 Riesz, F., 15 Rigid motion (infinitesimal), 302 Scalar wave equation, 276 Self-adjoint operator, see adjoin Separation of variables, 4, 277 Sequential compactness, 27 Sesquilinear form, 42 arising from a boundary integral operator,

261,275 arising from an elliptic differential operator, 114

arising from the Helmholtz operator, 276 arising from the Laplacian, 246 Single-layer potential, see surface potential Singular integral operator, 190, 312 Slobodeckii seminorm, 74, 79 and Fourier transform, 79 Smoothing operator, 192 Sobolev imbedding theorem, 86 Sobolev representation formula, 311 Sobolev spaces compact imbeddings, 87 definition via Bessel potentials, 76 definition via weak derivatives, 74 density theorems, see density duality relations, 76, 78, 92, 98 equivalent norms for, 96, 110

Hs(1R") = W(W), 80 Hs(Q) = Ws (0), 81, 92 Hs (S2) = Ho (S2), 95,112

Hs(S2)=H' 91 interpolation properties of, 329-331 invariance under change of coordinates, 85 of negative order, 74 of vector-valued (generalised) functions, 106

on the boundary of a domain, 98, 99 Sommerfeld radiation condition, see radiation condition, Sommerfeld Spectral radius, 55 Spectral theory for coercive self-adjoin[ operators, 49 for compact self-adjoint operators, 47, 55 for self-adjoint elliptic differential operators, 132 Spectrum of a linear operator, 45 Spherical harmonics, 250, 252 addition theorem for, 335 and boundary integral operators, 252 and the Helmholtz equation, 279 classical, 338 eigenfunctions of the Beltrami operator, 278 for the circle, 336 orthogonal basis for, 337 orthogonal projection onto, 334 L2(S"-1), orthogonality in 265 series expansion in, 257 Stein, E. M., 309 Steklov-Poincare operators, 145 estimates for a C"+1 , 1 domain, 146 estimates for a Lipschitz domain, 155 representations in terms of boundary integral operators, 244 Strain tensor, 296 Stress tensor, 296 Stress-strain relation, 296 Strictly positive-definite operator, 44

Index Strongly elliptic differential operator, 119 change of coordinates, 156 linear elasticity, 297 with constant coefficients, 193 Sturm-Liouville problem, 6 Sturm, C. F., 6 Successive approximations, method of, 11 Support essential, 66 of a distribution, 66 of a function, 61 Surface area of unit sphere, 247, 268 Surface potential double layer, 10, 202 traces of, 221 duality relations, 212, 213 for self-adjoint differential operator, 212, 218 jump relations for, 3, 11, 186, 203, 215 mapping properties of, 203, 205, 210 single layer, 3, 201 traces and conormal derivatives of, 218 Tangential differential operator, 147 Taylor expansion, 61 Test function, 65 Thomson, W., 6, 8 Totally bounded set, 27 Trace operator, 100 and Ho (f ), 105

351

and surface potentials, 209 for Ct- 1, 1 domains, 102 for Lipschitz domains, 102 112 from Wk (R") to W; one-sided, 141 right inverse for, 101 Traction, 296 alternative formula for, 308 as conormal derivative, 297 Transmission property, 142, 143 for surface potentials, 183, 186, 210 Transpose of a linear operator, 22 inverse of, 53 Uniformly directionally differentiable surface, 221

Uniqueness theorem for the Helmholtz equation, 288 for the Laplace equation, 260 mixed boundary conditions, 250 Neumann problem, 266 Volterra, V., 13 Volume potential, 2, 191 behaviour at the boundary, 216

Wave number, 276 Weak convergence, 42, 55 Weber, H., 9 WeierstraB, K., 10

Index of Notation

Functional Analysis A*

A/ At

dist(u, W) im A

(g, u) )A II

11A

ker A

£(X, Y) ®

(g, u)

u1v

uIW ti spec(A) Wa

av

uj - u (X0, X1)e,q X*

adjoint of A, 37 induced map on cosets modulo ker A, 18 transpose of A, 22 distance from point u to set W, 21 image (range) of linear operator A, 18 same as (g, u), 37 energy inner product for A, 44 energy norm for A, 44 kernel (null space) of linear operator A, 18 space of bounded linear operators from X to Y, 18 direct sum, 20 value of functional g E X* at u E X, 20 u is orthogonal to v, 39 u is orthogonal to the set W, 39 equivalence of norms, 17 spectrum of A, 45 subspace of X* that annihilates W c X, 23 subspace of X that annihilates V C X*, 23 uj converges weakly to u, 42 interpolation space, 318 dual space of X, 20

Theory of Distributions Ccomp°O

(Q)

Comp(c2)

space of C°O functions with compact support in 0, 61 space of Cr functions with compact support in 0, 61 353

Index of Notation

354

D(S2) D(S2)

space of infinitely differentiable functions on 0, 61 space of functions in CO°(S2) having support in K, 61 space of r times continuously differentiable functions on 0, 61 space of functions in C` (S2) having support in K, 61 C mp(Q) with sequential convergence defined, 65 space of restrictions to 7 of functions in D(IR"), 77

S

same as So, 66

CO0 (Q)

CK (S2)

C' (n) CK (S2)

S(R")

Dirac delta function(al) at x, 66 CK (S2) with sequential convergence defined, 65 space of Schwartz distributions on S2, 65 space of distributions with compact support in 92, 66 C°°(0) with sequential convergence defined, 65 finite-part extension of u, 166 principal value of u, 166 finite-part integral of xa i (x) over the half line x > 0, 160 abbreviation for (u, v)g when S2 = R", 68 same as (u, v)s2, 68, 107 space of locally integrable functions on 0, 64 dilatation operator, 158 tensor product of functions or distributions, 104 abbreviation for (u, v)n when 0 =1R", 66 integral (generalised, if necessary) of u v over S2, 58, 66, 106 Fourier transform of f.p. xt, 169 pa+'t-(x) over p > 0, 166 finite-part integral of Schwartz class of rapidly decreasing Coo functions on 1R", 72

x+

xa if x > 0, but 0 if x < 0, 159

f.p. X"

f.p. x-k-1

finite-part extension of x+, 160 (x l" if x < 0, but 0 if x > 0, 163 finite-part extension of x° , 163 finite-part extension of x-k_1 for an integer k > 0, 164

(x ± i0),

164

SX

DK (S2)

-D. (0)

E. (0) E(S2) f.p. U P.V. U H a ((a)

(u, v)

(u, On L1.1°c(0)

A ® (u, v)

(u, v)c

n () Ra0

X0

f.p. X'.

Sobolev Spaces HF HS (R") HS (I-) HS (S2)

HS (S2)'"

space of distributions in HI (RI) with support in F, 76 Sobolev space on 1R" (definition via Bessel potential), 76 Sobolev space on 17, 98 space of restrictions to S2 of distributions in HS (R" ), 77 space of HS functions on Q with values in Cm, 107

Sobolev Spaces

Ho (0) H` (Q)

closure of D(S2) in HS (S2), 77

HS (52)"'

space of HS functions on S2 with values in Cm, 107 Bessel potential of order s, 75 Slobodeckil seminorm, 74

is

HA.P,0

355

closure of D(2) in HS (I8"), 77

I

Wp(S2) Wp(S2)m

abbreviation for W2 (S2), 75 Sobolev space of orders > 0 based on LP(0), 73, 74 space of WP functions on S2 with values in C"', 107

Differential and Integral Operators AS"-1

B; B,,

BV 13*

B; B,,

DL DL Eik(u) G (x, y) G

G(x - y) Gj(x, x - y)

[u]r

P PO

(P = On

4)t R

M S

Elk

Beltrami operator on the unit sphere, 277 ft h component of generalised flux or traction, 114 conormal derivative, 114 conormal derivative from S21, 141 adjoint of B,,, 201 dual version of B;, 115 dual version of 8,,, 115 double-layer potential, 10, 202 dual version of DL, 211 strain tensor, 296 fundamental solution or parametrix, 2, 191 volume potential, 191 G(x, y) in translation-invariant case, 193 jth term in homogeneous expansion of G(x, y), 195 jump in across r, 142

jump in BA across P, 142 jump in u across I', 142 Laplace operator, 1 second-order differential operator, usually strongly elliptic, 113 principal part of P, 114 sesquilinear form arising from P for the domain £2, 114 abbreviation for (Dnt, 141 boundary integral operator, conormal derivative of DL, 218 operator arising in radiation conditions, 234 boundary integral operator, trace of SL, 7, 218 stress tensor, 296

Index of Notation

356 S§L_ L

T T

U V

single-layer potential, 3, 202 dual version of SL, 211 boundary integral operator, sum of one-sided traces of DL, 11, 218 dual version of T, 218 solution operator for the Dirichlet problem, 145 solution operator for the adjoint Dirichlet problem, 145

Other Symbols a!

IaI

8"u ya C+

CCapr u*v A1,h

dQ

u = ,'Fu u = .P*u

t y

factorial of the multi-index a, 61 order of the partial derivative determined by a, 61 partial derivative of u determined by the multi-index a, 61 monomial determined by the multi-index a, 61 complex upper half plane Im z > 0, 183 complex lower half plane Im z < 0, 183 capacity of IF, 263 convolution of u and v, 58 difference quotient in lth variable with step size h, 62 element of surface area on 1, 1, 97 Fourier transform of u, 70 inverse Fourier transform of u, 70 (common) boundary of S2 = St- and of 52+, 1, 89, 141 trace operator for S2, 100, 102

Yadjoint of y, 201 Y}

rD FN hml), h(2)

Ju j," LP (S2)

M(n, m) N(n, m)

trace operator for Sgt, 1, 141 portion of r with Dirichlet boundary condition, 128 portion of r with Neumann boundary condition, 128 spherical Hankel functions, 281 Bessel function of the first kind, 278 spherical Bessel function of the first kind, 279 Lebesgue space of pth-power-integrable functions on 0, 58 dimension of P,, (R"), 250

v

dimension of R. (R"), 250 Euclidean norm in R" or unitary norm in C'", 1 outward unit normal to 9 = S2-, 1, 97, 141

0

domain in 1R", 1

Sgt p*

interior (-) and exterior (+) domains, 1, 141 conjugate exponent to p, 58

1X I

Other Symbols

generalised Legendre polynomial of degree m for the dimension n, 255 space of homogeneous polynomials of degree m, 250

P. (n, t)

P. (R")

upper half space x > 0, 183 lower half space x < 0, 183

]R+

]R"

xm (W)

f. (S'

I)

u*

uv utkI(x; y)

T. T}(x) xa Yu ym

F(a) HM H(2)

f

space of solid spherical harmonics of degree m, 250 space of surface spherical harmonics of degree m, 252 transpose of the complex conjugate of the vector u, 107 dot product of vectors u and v, 107 kth Fr6chet derivative of u, 61 Kelvin transform of u, 259 surface area of S"- 1, 247 221

inverse point of x with respect to a sphere, 258 Bessel function of the second kind, 278 spherical Bessel function of the second kind, 279 gamma function, 169 Hankel functions, 280 special contour integral, 183

357