On quasilinear boundary value problems in domains with corners

Nonlinear Analysis,

Theory, FVintcd in Great Britain.

Methods & Applicstiom,

ON QUASILINEAR

Vol. 5,No.7,

0362.546W81M70721-15 SU2.WO 0 1981 Pergamon Press Ltd.

1981.

pp. 721-735,

BOUNDARY VALUE PROBLEMS WITH CORNERS

IN DOMAINS

PETER TOLKSDORF* Inst. f. Angew. Anal., Univetsitlt

Bonn, Betingstt. 6, 53 Bonn 1, Fed. Rep. of Germany

(Received 27 October 1980) Key wora’s: Ditichlet problem for a class of quasilinear gradient neat cornets.

equations, behaviout of the solution and its

0. INTRODUCTION BEHAVIOUR near singular boundary points of elliptic boundary value problems is of particular interest for physical applications (cf. [l]) an d numerical computations (cf. [2]). For linear equations this subject is almost completely treated by Grisvard [3] and Kondratjev [4]. They proved that the solution can be split near a plane corner or conical point into a smooth part and a linear combination of certain singular functions. For the model problem THE

-Au =

f,

u =g,

inQ, on aQ,

posed on a plane domain Q, the solution behaves like (x -x~lniBo, where 0, is the interior angle of a corner at xn. The knowledge of these singular functions can be used to improve numerical algorithms (cf. [ 11). Only recently some papers appeared treating the behaviour near corners or conical points of the solutions of certain semi&ear equations or systems. Sperner [5] and Dziuk [6] gave estimates of the type lu(x) - U(Q) 1G c . Ix - x#,

(0.1)

[Vu(x)\ c c . Ix -x&y

for vector valued solutions of the problem -Au(x)

= f(x, u(x), Vu(x)),

u(x) = 0,

in Q,

(0.2)

on asl,

near a singular boundary point XO,where the function f satisfies the growth condition

if@,4x1, VW) ( s a . IV+4 I2+ b, for some constants a, b. In this work, we consider quasilinear boundary value problems of the form -div{(k + IVU(P-~) *Vu} =

f,

u = g, * This research was supported by the Sondetfotschungsbeteich 721

in &, on 8s2,

72 of the Deutsche Fotschungsgemeinschaft.

(0.3)

PETER TOLKSDORF

722

(p > 1, k 3 0). We give estimates

of the type (0.1) and U(X) - U(Xc,)2 c . /x - X”iA,

(0.4)

(c > 0) in the neighbourhood of a corner with vertex at x0 and interior angle Q0 E (x, 2~). In the case p = 2, i.e., the Laplace equation, we can choose A and h arbitrarily close to JC/&. Forp > 2, (0.1) and (0.4) are valid with A and A greater than X/C&, and forp < 2, with Iz and A smaller than n/0,. Generally, the solution becomes smoother near the corner with increasing p and decreasing interior angle @,. The exponents A and A in (0.1) and (0.4) can be chosen independently of the constant k in (0.3). We also treat three-dimensional corners and give inequalities corresponding to (0.1). The proofs of the estimates for the solution itself are based on the observation that the functions c * r’ * sin (~0) are usable as barriers for problems of the type (0.3), with suitably chosen constants c > 0 and A, ,U E (0, 1) ( r and 8 are the plane polar coordinates). The gradient bounds are obtained similarly as by Dziuk [6] for the problem (0.2). His analysis rests on an inequality of the type ,sig, IOU(X)] d c, + c2 . r-l . sup {I+)

- u(Y) I IX>Y E

B217

(0.5)

where B, and B2 are balls with radius r and 2r, respectively. Such an estimate was proved by Nagumo [7, p. 2121, for linear equations, and by Heinz [8, p. 2281, for the semilinear problem (0.2). Our Proposition 1 generalizes Heinz’s result to the quasilinear equations considered here. As a byproduct of our proofs, we also obtain estimates of the type (0.1) near singularities of the boundary function similar to 1.x - XO/* (0 < A < 1). 1. ASSUMPTIONS

We consider

the boundary

AND

RESULTS

value problem -div

in Q,

{~(/VU(~) . VU} =f,

(1.1)

on &?.

u =g,

Here, Q is an open bounded subset of R”. The “right side” f belongs to L”(Q), and g to #P(Q) fl L”(Q), for somep E (1, 00). The function a( . ) satisfies the following conditions, for some positive constants cl, ~2, ~3, cd and all t > 0: 4t *)

3 cl . min {tp-2. (t + l)p -“},

a(t 2,

< c2. max{tP-2,

* t2J S c3. max {tp -2, (t + 1)pm2},

Ia’ a’(t) . t

a’(t).t !iEZ

(t + l)“-*},

a(t)

3 (cd - 112) . a(t),

(1.2) (1.3) (1.4) (1.5)

p-2 = ___2

.

(1.6)

In the following, u always stands for the weak H’,P(Q)-solution of (1.1). It exists, because, on account of Lemma 1, the usual assumptions for “monotone operators” (cf. Theorem 1.1 of [9]) are satisfied by the differential operator considered here. The uniqueness of u can also easily be derived from Lemma 1.

On quasilinear boundary value problems in domains with corners

123

From now on these assumptions are used without being mentioned explicitly. They allow us to apply the results of this work to the following equations, for arbitrary c 3 0: -div {(c + IVU\P-~) . Vu} = f, -div {(c + \VU[*)@-~)‘*.VU}= f. Finally, we introduce two functions A(8) and A(0) depending on 8 E (n, 27r) and p. 0(p - 2) + d4??@ - 1) + e*(p - 2)2 2*8*(JJ-1) 7

A(B) =

- 1)(2p - 3) + e*@ - 2)2 2 .8.(2~ - 3) ) p f 1.5,

e(p - 2) + q4,;(,

A(e) = i

n2/e2,

p = 1.5

Plane corners

Let XA have a plane corner with vertex precisely: There is a ball Br centered C2-curves I’i, I2 which meet at x0 including boundary function g to each Ii belongs to radius smaller than that of B1.

at x0 E &? and interior angle t9,,E (n, 279, more at x0 so that aQ n B, consists of two regular the angle f30.We assume that the restriction of the C*(IJ. By B2, we denote a ball with center x0 and

THEOREM 1.

The additional assumptions cited above imply that, for every E > 0, there is a constant c so that the solution u of (1.1) satisfies: \u(x) - u(xlJ) / c c . (x - Xol*(@y (Vu(x)( s C. lx - ~~l*(~~)-~-‘,

vx E 22, VX E

B2 n Q.

Remarks.

The influence of the various parameters upon the constant c is very difficult to describe. For example, c depends strongly on how well (p - 2)/2 is approximated by (a’(t) - f)la(t), for t large. In particular, for the gradient bound near the corner, an arbitrarily small variation of E in the exponent has more influence than any variation of the constant c. The next theorem shows how sharp the estimates of Theorem 1 are.

THEOREM 2. Let Q be the plane wedge {(r . cos 8, r .

sin @IO < r -C R and 0 < 8 < eo} with opening angle 0, E (,7~,27r), and let g = 0 in 52. Then, for every E > 0, there is a constant c such that the solution u of (1.1) satisfies

ne

1I

u(r, 19)2 den)+& . sin e. for

,

all r E (0, R/2) and 8 E (0, eo), provided that f 2 c in S2.

Because of the trivial equality div {\V(c * u)(Pd2 . V(c * u)} = cP_l . div {IVU[P-~ . VU} (c > 0), we can formulate Theorem 2 in a simpler way, for this special case.

PETERTOLKSDORF

724

THEOREM2’. Let D be as in Theorem 2. Assume that f satisfies the inequality f 2 6 in Q, for some positive 6. Then, for every E > 0, there is a positive constant c such that the solution u of the problem -div{(VuJP-2 * VU}=f, u = 0,

in 52, on an,

satisfies the following inequality, for all r E (0, R/2) and 6 E (0, 0,):

Three-dimensional

corners

We suppose that S2 has a corner with interior angle 19,E (Ed,2~)~ more precisely: There is a ball B1 centered at 0 satisfying

We assume that g vanishes in B1 fl Q. By Bz, we denote a ball with center 0 and radius smaller than that of B1. THEOREM 3. The additional assumptions cited above imply that, for every E > 0, there is a constant c such that the following inequalities hold, for all x =(x1, x2, xx) E Bz n Q: lug

s c ’ I(XI,X2))*@?

pu(x)I

=z c. J(c~,X2)/*(oo)-~--.

Singular boundary data

Let 0 be a plane domain, and p boundary function g has a singularity The function g belongs to C’(c) rl following inequalities hold, for all x

be greater than 1.5. We suppose that, at x0 E aQ, the of the type Ix - x0(*, for some /1 E (0, l), more precisely: C2(S2). M oreover, there is a constant go such that the E BI n 52 and all i, j E (1, 2):

[g(x) - g(xo)l c go * lx - &dAj

Further, we assume that there is a ball B1 centered at x0 such that a&! fl BI is a regular C2curve. By Bz, we denote a ball with center x0 and radius smaller than that of B,. THEOREM4. The assumptions cited above imply that the following inequalities hold, for some constant c: lu(x) - U(X”>l=Sc . Ix - xoia, p4(x)(

6 c * Ix - x01*-~,

vx E !a. Vx E Bz n Q.

725

On quasilinear boundary value problems in domains with corners 2. SOME

SIMPLE

INEQUALITIES

We use the abbreviations a,(V) = a(M*) * vi,

The assumptions (1.2), (1.3), (1.4) (1.5) imply that the following ellipticity and growth conditions hold, for some positive constants p and p, and all g, n E R”, q # 0:

(2.1)

(2.2) From (2.1) and (2.2), we obtain positive constants y and r such that, for every E, q E R” satisfying (q( 2 1, (2.3)

il Iail

=sr. (1 + lnl)p-?

(2.4)

LEMMA 1. There are positive constants y’ and l? so that, for every q, 9’ E R”, the following inequalities are true:

p E (L21, P E 1% cc)),

(2.5) (2.6)

Proof. For 117’1 > 1~1and t E [0, l/4], we have

~~4~l~-~‘I~Irl’+~~~r7-rl’~l~lIrll+l11’I, and

X

(qj - qj)(qi - vi)

drn

These inequalities and (2.1) imply (2.5). The estimate (2.6) is almost trivial. From the assumptions (1.2) and (1.4), we get lima(t)*IA f--trn

= 00,

lim a’(t)la(t) = 0. f--t_

(2.7) (2.8)

726 The functions

PETERTOLKSDORF n(13) and A(0) defined

in Section

q(A, l9) = -n$J

- 1) + h(p - 2) + Jt*/e*,

Q(& 0) = 472~ We need some properties

1 are the zeros of the functions

- 3) - il(p - 2) + n2(p - 1)/02.

of A, A, q, Q which we formulate

in the following

lemma.

LEMMA 2. 0
< A(e) < J-r/%, = A(0) = n(e),

p = 2,

(2.9)

Jc/nlB < A(0) < A(0) < 1, q{A( 0) + E, 13) < 0, Q(A(0)

(2.10)

- c, 0} > 0,

Proof. For p = 2, these statements are obvious. In the other from the following properties of q and Q with 0 being fixed.

cases,

they can be derived

(i) p < 2: The f unction q and, for p > 1.5, also Q has one negative zero. For p S 1.5, Q has at most one zero smaller than ~18. Moreover, q(d0, 0) =Q(d/e, 0) < 0, q(0, 0) > 0, Q(0, 0) > 0, q(A, 0) >Q(A, 0), for 0 < il < ~10. (ii) p > 2: The f unctions q and Q have one negative zero each. Moreover, q(d0, 0) = Q(d0, 0) > 0, q(1, 0) -=c0, Q(1, 0) < 0, q(A, 0) > Q(A, f3), for A > n/8.

3. STANDARD

BARRIERS

In this section, we use standard barriers to obtain two inequalities. In the first one, we estimate the solution u of (1.1) near a smooth part of the boundary. In the second one, we establish a bound for (u l,_=(o). The dependence of the constants stated there is very important for us. Therefore, we give proofs though similar estimates are known (cf. [9, p. 2951).

LEMMA 3. Let bi, b2 E H1,p(SL) be such that bi - & s 0 on IXJ, and

(3.1) for every nonnegative

Q, EHA-P(Q). Then we have 61 d 62 almost

everywhere

in Q.

Proof. In [lo] (p. 266) it is shown, for p = 2, that max (bl - b2, 0) belongs to HA,p(Q). from Therefore, we may set Q, = max (bi - b2, 0) in (3.1), and we obtain the proposition (2.5). For the proof I4C-VV

of the next lemma,

we have to define

explicitly

the quantities

Iu/c~(~J and

121

On quasilinear boundary value problems in domains with corners

Here, Q’ is an open subset of R”, u E C’(Q’),

w E C’(Q’).

4. Let B1 be a ball centered at x” with radius r E (0, l), and B1 fl a = {x’}. Suppose that the boundary function g can be extended to a function g E C’(&), where B2 is the ball with center x” and radius 2r. Let go and uo be constants such that LEMMA

IMCI(&)s r-l . go, sup iI+>

lMC+%)c r-* ’ go,

- 4.y) I Ix, Y E B21 s uo.

Then, there is a constant c depending

only on y, r, lfl~-(o),~ such that, for all x E B2 n

Q2, ILL(x)- u(x’)l s c ’ go + y + r . (x - x’ I. Proof. We set a =r . y-l . r-*, p = min (2,p), bo = em3”Y= e-3arz,fo = IflLm(Q), and

b(x) = k . (1 - exp (u(r* - lx - x”I’))}, where k is the maximum of the following four constants:

2uo+ go l-b0

r . y *(go *r-l + 1) _ go . r-l

’

2.bo+I-

2arbo ' * a-‘.

By definition of the barrier b, we get in BZ lsIV(b+g)/G12.k.a.r-1. Now, using (2.3) and (2.4) it is easy to show that, in B2, 2kabo(2ayr2 c IflL”(R)

r) - rgd.*

12(ka)* -P

The definition of k implies that u - (b + g) s 0 on a(B, fl Q). Therefore, Lemma 3 to (b + g) and u to obtain

we may apply

U(X) - u(x’) s 12 * k . a . r * lx - x’ 1, for x E Bz fl Sz. The corresponding completes the proof.

inequality for -(u(x)

- u(x’)) is shown similarly. This

728 LEMMA

PETERTOLKSDORF 5. There

is a constant c depending only on y, r, p, (fl~l(a), Igj~-cn~, R such that lul L”(Q)=Sc.

Proof. We choose a point x” E R” satisfying dist (xl’, Q) = 1, and we set

a = I- . y-i, D = sup {IX- yl lx, y E 52) + 1,

b@) = k . (1 _ e-+x”/2), where k is chosen sufficiently large such that the following inequalities hold: k

*(1- ema> 3 IgL-(~1, 2ka . eeaD2P 1,

2kaT . eMaD 3 max {IflL-p,,

!~IL-(QJ*(1 + 2kaD)‘-?.

Now, in the same way as in the proof of Lemma 4, one can show that Ju( Gb,

inn.

4,SPECIALBARRIERS

In this section, we use the cylindrical coordinates (r . cos 8, r . sin 0, z) and the plane polar coordinates (r . cos 8, r . sin 0). As indicated in the introduction, we construct barriers with the aid of the functions r’ . sin (~0). The equalities (4.1) and (4.2) of Lemma 6 are obtained by elementary calculations. In the Corollaries 1-3, we give the barriers which can be used to obtain the estimates of the Theorems 1-4, for the solution itself. The proofs of the corollaries consist mainly of exploiting the equalities (4.1) and (4.2). LEMMA

6. Let

c be a positive constant, A E (0, l), cc E (0, l), b2 E Cm(R). We set bl(r, 0)

= c . rh. sin (PO),

b(r, 8, z) = b,(r, 13)f by. Then, IVb/*= c2. r2(‘-l) . {A2 . sin’(@) + ,u~. cos*(@)} + (b$)‘,

-div {a(lVb(‘) . Vb} =

[i

{

-b;

. a(lVb12) . rAe2}

-AZ@ - 1) + A@ - 2) + p*(p - 1) -

X

+

{c. sin (~0)

2.

a’Wl*) . WI2 41Vb12)

.{a(lVbl*)

(4.1)

(p - 2) - (b;)*

+ 2. (bi)*.a’(lVb)?}.

(p - 2) .Ik2.J + p2 . cos2(pf3) I

A2 .sin2(@)

. ;;,;;,!t)}] (4.2)

129

On quasilinear boundary value problems in domains with corners

Proof. The equality (4.1) is verified directly. By elementary -div{a(lVb/‘)

‘Vb} = - $!{a(iV6/‘)

calculations,

~c~A~r”~sin(@)}

- &$j{a(lV61Z) . c . p. ?J * cos (/A@}

=

{c. sin (~0) + {c. ti-“. X

. a(lVbl*) * rid2. (p* - A”)}

a’(lV612)}

-A. sin (~0) . r-i

(IV6j’)

- p . cos (~0) -$ (lV612)) - 5 {a(lV612) * 65). This, and the equalities r *-$-(jV6[2) = 2(A-- 1) . (Vbr(*,

p * cos (pe) & (lV6l’) = 2 * sin (@I) . b’ . A* . c* ’ ?(h-l) - p*)Vbrj*}, imply (4.2). COROLLARY

1. Let go, gl, f. be positive constants, and let Sz be {(r.cose,r.sin8,z)IO
for some e, E (n, 27~). We set ~0 = Ace,), for p c 2, and Q = (A(eo) - x/0,), forp > 2. Then, for every E E (0, ~g), there are positive constants c and 6 so that the function b(r, 8, z) = c . r*(@-E . sin{$oe:z]

+ g2.,r2

satisfies, in &, -div {a(lV6(’ . Vb} >:fo,

63

gl

.

r +

g2

.

z*.

Proof. On account of (1.6), (2.8), (2.9), (2.10), Lemma 6, for every E E (0, ~g), we can find constants COand S such that, for every c 3 co, -div {a(lV612) *Vb} 3 l/2 . c * sin {zoe++i)} in 52. Corollary 1 is now easily seen to be true.

.a((V6(2) .rA(B”)-E-2.Q{A(eo)

- E, eo},

PETERTOLKSDORF

730

COROLLARY 2. Let Q be the plane wedge {(r cos 0, Y . sin 0) (0
satisfies -div

{a(/Vb(‘)

Proof. Let E E (0, GJ) be arbitrary. a r-0> 0 such that

Lemma

-div in 52, for 0 < r < rO. From

&= n/4 * (lllh

in 9,

bs0,

onaQ.

6, (1.6), (2.8),

(2.9), (2.10) imply that there

is

{a(lVbj’) . Vb} G 0,

this, the corollary

COROLLARY 3. Let R,fo, go be positive

Vb) G c,

follows.

constants,

A E (0, l), p 3 1.5. We set

- l), 80 = min {~-r/2. (lid

+ l), 3~c/2}.

We suppose that Q is contained in {(r. cos 0, r . sin 0)/O < 0 < @aand 0 < r < R}. Then, there is a positive constant c such that the function b(r, 0) = c . r’ * sin {vi satisfies,

. (8 + E)}

in Q. - div {a(/Vb/*) . Vb} zfo, b(r, 0) 2 go ’ r’.

ProoJ

For ,u =fi,

we have

-AZ@ - 1) + il(p - 2) + &JJ - 1) Therefore,

the corollary

can be derived

5. AN

0, - 2) . AZ. p2 A2sin’(@)

from Lemma

L”-BOUND

FOR

THE

> o

+ p2 cos (~0)

’

6 using (1.6) and (2.7).

GRADIENT

In the introduction, we announced the La-bound (0.5) for the gradient which depends essentially on the oscillation of the solution. This section is devoted to the proof of that estimate. Our proof requires some regularity of the solution u of (1.1) which is not known to hold for equations satisfying only the ellipticity and growth conditions (2.1) and (2.2). In order to avoid this difficulty, we approximate u by solutions of equations satisfying stronger ellipticity and growth conditions.

On quasilinear boundary value problems in domains with corners

731

PROPOSITION 1.Let B3 be a ball with center x0 and radius 3r contained in Q, and let B1 be a ball centered at x0 with radius r. Further, suppose that there is a constant uo such that

Then, there is a constant c independent

For the proof of Proposition LEMMA 7.

of x0, r and the solution u of (1.1) such that

1, we need the following lemmas.

Let E > 0, cx > 0, u E L’(Q) satisfy IAk

(u - k) dx s LY.{meas (Ak)}l+E,

for every k 2 0, where Ak is {x E Qju(x) > k}. Then l+& esjEstp n(x) 2 _ E . (ylw + E)’ (1 u

IL1(A,,))E’(l

+ E).

Proof. This result can be found in [ll, p. 711 or in [9, p. 2811. It is easily seen that one may choose the constants in the estimate in this way.

For E > 0, we set a’(t) = a(t + E), and we define a; and u$ correspondingly and aij. Let uE be the solution of (1.1) with a replaced by a’. Then, we have:

LEMMA 8.

to Uj

(9 The

inequalities (1.2), (1.3), (1.4), (1.5), (2.1), (2.2), (2.3), (2.4), (2.5), (2.6) are valid for a” with constants independent of F. (ii) For every E > 0, there are positive constants yEand JYEsuch that the following ellipticity and growth conditions hold, for every 5, r] E R”: iil

#rll5&j

i& lG(rl)

I

a YE ’ C1 +

c rE *(1 +

ld)p-2*15‘1*, I~I)@.

(5.1)

(5.2)

(iii) liiO Iu - UE(#G(Q)= 0. Proof. The statements (i) and (ii) are easily checked. For (iii), we get from the definition of U&using Holder’s inequality

732

PETER TOLKSDORF

This, together with (i), (2.5) and (2.6), G 2, we use additionally the inequality

implies

(iii), in the case p 2 2. In this other

case, p

i i, (Vu - Vzf,~ dx j2u 4 / I, (1 + (VUJ + ,Vu”,)P dx ((2-p)‘p

x * (1 + /vu/ + IVU”l)P~2. pu - Vu’)%, I

to obtain

(iii).

Proof of Proposition 1. Let us suppose that Proposition 1 holds, for ZY (E > 0), with a constant c independent of E. Moreover, suppose that B3 is contained in Q. These assumptions imply that z/ is Lipschitz-continuous uniformly with respect to E, since Lemma 5 and Lemma 8 yield a uniform bound for sup {/U”(X) -~~(y)j (x, y E B3}. Hence by Lemma 8, up + u uniformly on B3. Consequently, Proposition 1 will hold for the function II itself once the above assumptions about uE and B3 have been established. Moreover, it is easily seen that the condition B3 C Q can be dropped. Now it remains to prove Proposition 1, for up. According to Lemma 8, we may assume that (5.1) and (5.2) hold. Hence by the regularity theory (cf. [ll]), we know that U&belongs to C’(Q) fl H?$(Q). Consequently,

(5.3) holds, for every s E (1, 2, . . , n} and v E H’,2(Q) having compact support. During this proof, c stands for a generic constant independent of x0, r, ~8, E. From now on, we write u instead of uE, ai instead of a:, etc. The proof consists mainly of three parts. (i) We estimate J . (1 + (Vu/)” d_x in terms of (UO + r)/r and r. (ii) By means of a version of the iteration technique used in [ll, pp. 259-2631, we bound _r& (I +lV4)q d.x in terms of (~0 + r)lr and r, for every q E [l, cc) (B2 is the ball with center x0 and radius 2r). (iii) We show the proposition with the aid of (5.3), (ii), Lemma 7. During the whole procedure, we have to be careful not to lose powers of (uO + r)lr and r. We take a function p E C”(R) with values in [0, 11, equal to 1, for t c 1, and equal to 0, forta1.5.Fork=1,2,3 ,... ands=1,2 ,..., n,weset Q?k(x) =

u,(x) 0,

u,(x) = i (i) Testing

(1.1) with (U -Z&O)).

~(2~+’ . (Ix -x&r - 1,

4$(X)+ 19

q4 we get

u,(x)

- 2)) 2 I,

733

On quasilinear boundary value problems in domains with corners

Using (2.5) and (2.6) we obtain

Finally, by applying Holder’s inequality,

6 (ii) We shall o b tain the announced estimate ). . . . Consequently, we suppose, for k 3 1,

by induction,

for q =p + 2,p f 4,p +

(5.5)

sR

In (5.3), we set t/ =IR

$+l

* &+I,

and we use (2.3), (2.4) to obtain

(1 + jVu))P-2 * IUp

)vu,p * &+I dx

+ c * r-l . * (1 + IVUl)P+2k~lpk+l dx. I

With the aid of (5.5) and Cauchy’s inequality, this is transformed IQ

(1 + IVul)p-2.lz@

* pu,(*.

Q$+, &s

c. t-2.

into p+2k.

7 1

I

(5.6)

Only by integrating by parts one gets IQ

ux, . 4 . IU,IP+*k. cp;+, dx

s c. zig. Q (Vu,l * (1 + I +c ‘?*I,(1

(VuJ)P_ . IU,l2k+l.

+ jV~()P+2k+1’P)k+,‘k

q;+,

dx

(5.7)

Finally, using the trivial inequality

I

R

(1+IVUI)P+2(k+l).Q?2k+l~~C.r”+C.

I ~u,~u,.Iu~,p+2k.(Pi+ldX as=1

the inequalities (5.5), (5.6), (5.7), and Cauchy’s inequality, we obtain (5.5) with k replaced by k + 1. For k = 1, (5.5) can be shown in the same way using (5.4) instead of (5.5), for k

134

= 0. From

PETER TOLKSDORF

(_5.5), we obtain

with the aid of Holder’s

inequality u”+r

4

1 1

I

(1 + /VU~)~~XGCC~~. B2

-

r

(5.8)

’

for all q E [l, co). (iii) We set T(X) =p(lx - x0//r), (J = max(2, p), Ak = {x E Q / u,(x) . q(x) > k}, for k 2 0. In the following, the generic constant c will also be independent of k. We use (5.3) with i$ = +-1. to obtain max (u, . cp -k, 0), (2.3), (2.4), and Cauchy’s inequality

IAk

(1 + ]VU/)~-~ * /Vu,)‘. @d.z G c .r-‘.

Now we have to distinguish

The integral

inequality

and the Sobolev

Ak (u, . q - k) dx 4 c . {meas (Ak)}l’n

on the right side can be estimated

Ii

C’

(1 +

I

(1 + pq

imbedding

theorem,

we get

L, lV(u, . q)I dx.

by

puj)p-2 * (Vu,12. p12 dx

At

+ c.rml.

(5.9)

two cases

p c 2: With the aid of Holder’s

i

(1 + )VuI)” &. IAk

11’2. Ii,/

+ ~VUl)‘~“&~“~

dx.

Ak

Combining

this with (5.8) and (5.9) we obtain

by Holder’s

Ak(U, . q _ k) & < c . r-l/O . !f!$

inequality

that

. {meas (,+)}l+[l’h’)l.

(5.10)

I p a 2: In this case, we get with the aid of Holder’s theorem

I The integral

Ak (us

inequality

imbedding

(Ak)}l-[(“-2)‘@‘d . /i,, IV(4. dPi212 d.x1Ih. *Q,- k) b < c. {meas

on the right side can be estimated c.

I

by

A,(1 + JV~~)p~2~~V~.~Jz-~pdx+c~r~2~~

Now we can conclude in the same way as above In both cases, (5.10) and Lemma 7 imply

inequality

for -u,

(1 + IVul)pdX. Ak

that (5.10) holds.

u0 + r ess sup U,(X) G c . r XEB, The corresponding

and the Sobolev

can be shown similarly.

On quasilinear boundary value problems in domains with corners 6. PROOF

135

OF THE THEOREMS

Proof of Theorem 1. The estimate for the solution itself follows from Lemma 3, Lemma 5 and Corollary 1. In some extreme cases it may happen that the barrier of Corollary 1 does not belong to H’lP(Q). However, one can approximate this barrier in a suitable manner, for example by drawing the singularity away from Q. The smoothness of the curves Ii guarantees the existence of an & E (0, l/4) so that, for every x’ E as2flBt, there is a ball B’ with radius a . (x’ - xg( satisfying 3 fl B’ = {x’}. Employing Proposition 1, Lemma 4, and the estimate for the solution itself we get the gradient bound, for all x E B2 fl Q whose distance to the boundary is smaller than a/2 . Ix - x01. For the remaining x E BZ II S2, we obtain the gradient bound directly from Proposition 1 and the estimate for the solution. Theorem 2 follows directly from Lemma 3 and Corollary 2. Theorem 3 and 4 can be proven similarly as Theorem 1. For Theorem 4 one has to use Corollary 3 instead of Corollary 1. REFERENCES 1. JACKSONJ. D., Clussical Electrodynamics, John Wiley & Sons, New York (1975). 2. STRANGG. & FIX G. J., An Analysis ofrhe Finite Element Mefhod, Prentice-Hall, Englewood Cliffs (1973). 3. GRISVARDp., Behaviour of the solutions of an elliptic boundary value problem in a polygonal or polyhedral domain, Num. Sol. part. diff. Eqns 3, 207-274 (1976). 4. KONDRATJEVV. A., Boundary problems for elliptic equations in domains with conical or angular points, Trans. Moscow Math. Sot. 1967, 227-313 (1968).

5. SPERNERE., Nichtlineare elliptische Differentia[gleichungen in singuliiren Gebieten, Habilitationsschrift, Universitat Bayreuth (1979). 6. DZUK G., Das Verhalten von Losungen semilinearer elliptischer Systeme an Ecken eines Gebietes, Math, Z. 159, 88-100 (1978).

7. NAGUMOM., On principally linear elliptic differential equations of the second order, Osaka math. J. 6, 207-229 (1954).

8. HEINZ E., On certain nonlinear elliptic differential

equations and univalent mappings, J. d’Ana1. Math. 5,

197-272 (1956157).

9. HARTMANP. & STAMPACCHIA G., On some non-linear elliptic differential-functional equations, Acfa Math. 115, 271-310 (1966). 10. TREVESF., Basic Linear Partial Differential Equations, Academic Press, New York (1975). 11. LADYZHENSKAYA 0. A. & URALTSEVAN. N., Linear and Quasilinear Elliptic Equations, Academic Press, New York (1968).