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{\tenrm\ifodd\pageno\rightheadline \else
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\def\rightheadline{EJDE--2000/08\hfil  Nonlinear elliptic systems involving measures
\hfil\folio}
\def\leftheadline{\folio\hfil Shulin Zhou
 \hfil EJDE--2000/08}

\def\pretitle{\vbox{\eightrm\noindent\baselineskip 9pt %
 Electronic Journal of Differential Equations,
Vol.~{\eightbf 2000}(2000), No.~08, pp.~1--6.\hfil\break
ISSN: 1072-6691. URL: http://ejde.math.swt.edu or http://ejde.math.unt.edu
\hfill\break 
ftp ejde.math.swt.edu \quad ejde.math.unt.edu (login: ftp)\bigskip} }

\topmatter
\title
A note on nonlinear elliptic systems involving measures
\endtitle

\thanks 
{\it 1991 Mathematics Subject Classifications:} 35J60, 35B45. \hfil\break\indent
{\it Key words and phrases:} elliptic systems, measures, existence, regularity.
\hfil\break\indent
\copyright 2000 Southwest Texas State University  and
University of North Texas.\hfil\break\indent
Submitted November 5, 1999. Published Janaury 27, 2000.  \hfil\break\indent
Partially supported by the National Natural Science Foundation 
and by the \hfil\break\indent
Doctoral Program Foundation                         
of Institutions of Higher Education of China.                  
\endthanks
\author  Shulin Zhou   \endauthor
\address
Shulin Zhou \hfill\break\indent 
Department of Mathematics,  Peking University, \hfill\break\indent
Beijing 100871, P. R. China
\endaddress
\email zsl\@sxx0.math.pku.edu.cn
\endemail

\abstract
We study the existence and regularity of solutions to nonlinear 
elliptic systems whose right-hand side is a measure-valued function.  
 Using a sign condition instead of structure 
conditions, we obtain the same as those presented by
Dolzmann, Hungerb\"uhler and M\"uller  in [1]. 
\endabstract

\endtopmatter

\define\dive{\operatorname{div}}
\define\loc{\operatorname{loc}}
\define\ap{\operatorname{ap}}
\define\meas{\operatorname{meas}}
\define\Id{\operatorname{Id}}

\document
\head 1. Introduction \endhead

In [1], Dolzmann, Hungerb\"uhler and M\"uller 
use Young measures and the approximate derivatives to
study the existence and regularity 
of solutions to nonlinear elliptic systems of the form 
$$
\gather
-\dive \sigma\big(x,u(x),Du(x)\big)=\mu \quad \text{in } \varOmega\,,\tag 1.1\\
u=0\quad \text{on } \partial \varOmega\,,\tag 1.2
\endgather
$$
with measure-valued right hand side on an open bounded domain $\varOmega$
in $\Bbb R^n$. They obtained a series of complete and optimal
results which are very important when the exponent $p\in(1,2-1/n)$. 
 They assume that the matrix $\sigma$ satisfies the following 
hypotheses:
\parindent=25pt %It was 12.0pt

\item{(H0)} (continuity) $\sigma:\varOmega\times\Bbb R^m\times \Bbb M^{m\times n}
\to \Bbb M^{m\times n}$ is a Carath\'{e}odory function. 

\item{(H1)} (monotonicity) For all $x\in \varOmega$, $u\in \Bbb R^m$ and $F$, $G\in
\Bbb M^{m\times n}$, 
$$
\big(\sigma(x,u,F)-\sigma(x,u,G)\big):(F-G)\ge 0.
$$
 
\item{(H2)} (coercivity and growth) There exist constants $c_1, c_3>0$,
$c_2\ge 0$ and $p,q$ with $1<p<n $ and 
$q-1<(p-1)n/(n-1)$ such that 
for all $x\in \varOmega$, $u\in \Bbb R^m$ and $F\in
\Bbb M^{m\times n}$, 
$$
\align
\sigma(x,u,F):F&\ge c_1|F|^p-c_2,\\
|\sigma(x,u,F)| &\le c_3|F|^{q-1}+c_3.
\endalign
$$

\item{(H3)} (structure condition) For all $x\in \varOmega$, 
$u\in \Bbb R^m$, $F\in \Bbb M^{m\times n}$ and 
$M\in \Bbb M^{m\times m}$ of the form $M=\Id-a\otimes a$ with all
$a\in \Bbb R^m$, $|a|\le 1$,
$$
\sigma(x,u,F):MF\ge 0.
$$
\parindent=12.0pt

Here $\Bbb M^{m\times n}$ denotes the space of real $m\times
n$ matrices equipped with the inner product $M:N=\sum^m_{i=1}\sum^n_{j=1}
M_{ij}N_{ij}$ and the tensor product $a\otimes b$ of two vectors 
$a,b\in \Bbb R^m$ is defined to be the $m\times m$ matrix of 
entries $(a_ib_j)_{i,j}$, with $i,j=1,\hdots,m$.


For equation  (1.1) ($m=1$), the hypotheses (H0)-(H2) are sufficient to
prove the existence and regularity results. However, for system (1.1) ($m>1$)
it seems hopeless to obtain such results without further assumptions. 
Therefore, the structure condition (H3), often called
the angle condition, is assumed in [1] and [2]. 
In this note we assume that the matrix 
$\sigma$ satisfies another type of assumption 

\vskip .3 true cm
\noindent 
(H3)' (sign condition) For all $i=1,\hdots,m$,
$$
\sigma_i(x,u,F)\cdot F_i\ge 0\,.
$$
Here $\sigma_i$ and $F_i$ are respectively the $i$-th row vectors of 
$\sigma$, $F$, and the dot denotes the inner product in $\Bbb R^n$.

This indicates that system (1.1) is weakly-coupled. 
Using  (H3)' to replace  (H3) and assuming (H0)-(H2), we can
prove all the results in [1] and [2]. 
To make  this note short we are only concerned with system (1.1). 

In [1], a notion of solution where the weak derivative $Du$ is replaced
by the approximate derivative $\ap Du$ was introduced. This kind
of notion is useful when one considers the case $1<p\le 2-1/n$
since solutions of system (1.1) in general do not belong to the Sobolev
space $W^{1,1}$. We introduce the definition of the solution in
[1] for the sake of convenience. 

\proclaim{Definition 1} A measurable function $u:\varOmega \rightarrow
\Bbb R^m$ is called a solution of system (1.1) if
\parindent=25pt

\item{(i)} $u$ is almost everywhere approximately differentiable,

\item{(ii)} $\eta\circ u\in W^{1,1}(\varOmega,\Bbb R^m)$ for all $\eta \in C^1_0(\Bbb
R^m, \Bbb R^m)$,

\item{(iii)} $\sigma\big(x,u(x),\ap Du(x)\big)
\in L^1(\varOmega;\Bbb M^{m\times n})$,

\item{(iv)} the system 
$$
-\dive \sigma\big(x,u(x),\ap Du(x)\big)=\mu
$$
holds in the sense of distributions.
\parindent=12.0pt

\noindent Moreover, $u$ is said to satisfy the boundary condition (1.2)
if  $\eta\circ u\in W^{1,1}_0(\varOmega;\Bbb R^m)$ for all $\eta \in C^1_0(\Bbb
R^m, \Bbb R^m)\cap L^{\infty}(\Bbb R^m, \Bbb R^m)$ that satisfy $\eta \equiv
\Id$ on $ B(0,\rho)$ for some $\rho>0$ and $|D\eta(y)|\le C(1+|y|)^{-1}$
for some constant $C<\infty$.
\endproclaim

We will prove the following conclusion. 

\proclaim{Theorem 2} Suppose (H0), (H1), (H2) and (H3)' hold, and that 
one of the following conditions is satisfied.
\parindent=25pt
\item{(i)} $F\mapsto\sigma(x,u,F)$ is a $C^1$ function.

\item{(ii)} There exists a function $W: \varOmega\times \Bbb R^m
\times \Bbb M^{m\times n}\to \Bbb R$ 
such that $\sigma(x,u,F)=\frac{\partial
W}{\partial F}(x,u,F)$ and  $F\mapsto W(x,u,F)$ is convex and $C^1$.

\item{(iii)} $\sigma$ is strictly monotone with respect to $F$, 
i.e., $\sigma$ is monotone and 
$\big(\sigma(x,u,F)-\sigma(x,u,G)\big):(F-G)=0$ implies  $F=G$. 
\parindent=12.0pt

\noindent 
Also assume that $\mu$ is an $\Bbb R^m$-valued Radon measure on $\varOmega$ 
with finite mass. Then Problem (1.1)-(1.2) has a solution in the sense
of Definition 1, which satisfies the weak Lebesgue space estimate
$$
\|u\|^*_{L^{s^*,\infty}(\varOmega)}+\|\ap Du\|^*_{L^{s,\infty}
(\varOmega)}\le C(c_1,c_2, \|\mu\|_{\Cal M},\meas\varOmega)\,
$$
where 
$$
s=\frac n{n-1}(p-1),\quad s^*=\frac{ns}{n-s}=\frac{n}{n-p}(p-1)\,.
$$
\endproclaim

Theorem 2 remains true if we assume that (H0), (H2), (H3)' and
the matrix
$\sigma$ is strictly $p$-quasi-monotone, see Corollary 4 in [1]. 
We will follow the same procedure as in [1] to prove Theorem 2.
Instead of writing all details of the
proof, we will only prove Lemmas 10 and 11 in [1] where the
structure condition (H3) has
been used. Actually we will only show how to prove the essential parts
of Lemmas 10 and 11 when we use (H3)' to replace (H3). Our main idea is
to choose slightly different test functions. 
 
The relationship between (H3) and (H3)' will also be established in 
this section. 
In the scalar case $m=1$, (H3) or (H3)' is redundant. In the
vector case $m=2$, (H3) implies  (H3)' by choosing 
the vector $a=(0,1)\in\Bbb R^2$ or $a=(1,0)\in\Bbb R^2$ in (H3).
Nevertheless there seems no direct implication between (H3) and (H3)' when
$m\ge 3$. To our knowledge, there are two known examples 
satisfying (H0)-(H3). 

\proclaim{Example 3} $$\sigma(x,u,F)=a(u)|F|^{p-2}F$$
where $a:\Bbb R^m\rightarrow \Bbb R$ is a continuous function,
which is bounded from above and below by positive constants.
\endproclaim 

\proclaim{Example 4} 
$$\sigma(x,u,F)=\big((FA):F\big)^{(p-2)/2}FA$$
where $A=A(x,u):\varOmega\times \Bbb R^m\to\Bbb M^{n\times n}$
is a symmetric matrix satisfying the ellipticity
condition $\nu_1|\zeta|^2\le\sum^n_{i,j=1}A_{ij}(x,u)\zeta_i\zeta_j\le \nu_2
|\zeta|^2 $ with constants $\nu_1, \nu_2>0$.
\endproclaim

It is not difficult to verify that Examples 3 and 4 satisfy the sign 
condition (H3)'. Next, we present a linear elliptic system which 
satisfies (H0)-(H2) and (H3)', but does not satisfy (H3). 
To some extent, this example shows the restriction of the structure 
condition (H3). Since the sign condition (H3)' requires that the
components of the matrix $\sigma$ can be only weakly-coupled,  
this shows the limitation of (H3)'.  Therefore, 
it would be interesting to prove the same results
in [1] and [2] under a weaker condition than (H3) and (H3)'.

\proclaim{Example 5}  Let 
$$F=\pmatrix F_{11}&F_{12}\\ F_{21}&F_{22}\endpmatrix
\in \Bbb M^{2\times 2}\,,\quad
\sigma(F)=\pmatrix \varepsilon F_{11}&\varepsilon^{\alpha} F_{12}\\
F_{21}&F_{22}\endpmatrix\in \Bbb M^{2\times 2}
$$  with  $1\leq \alpha $, $0<\varepsilon\le 1/5$.
\endproclaim

It is obvious that $\sigma(F)$ satisfy (H0), (H1), (H2) and (H3)'.
We will show that $\sigma(F)$ does not satisfy (H3).

Choosing $a=(\varepsilon^{1/2},(1-\varepsilon)^{1/2})\in \Bbb R^2$, 
we have $|a|=1 $ and 
$$
M=\Id-a\otimes a=\pmatrix 1-\varepsilon &-\varepsilon^{1/2}
(1-\varepsilon)^{1/2}\\ -\varepsilon^{1/2}(1-\varepsilon)^{1/2}&
\varepsilon\endpmatrix\in \Bbb M^{2\times 2}.
$$
Now choosing $F=\pmatrix 1&1\\1&1\endpmatrix$, we have 
$\sigma(F)=\pmatrix
\varepsilon&\varepsilon^{\alpha}\\1&1\endpmatrix$ and 
$$
MF=\pmatrix 1-\varepsilon -\varepsilon^{1/2}(1-\varepsilon)^{1/2}&
1-\varepsilon -\varepsilon^{1/2}(1-\varepsilon)^{1/2}\\ 
\varepsilon -\varepsilon^{1/2}(1-\varepsilon)^{1/2}&
\varepsilon-\varepsilon^{1/2}(1-\varepsilon)^{1/2}\endpmatrix.
$$
Therefore,
$$
\align
\sigma(F):MF &=(\varepsilon+\varepsilon^{\alpha})
 \big(1-\varepsilon -\varepsilon^{1/2}(1
 -\varepsilon)^{1/2}\big) +2\big(
 \varepsilon -\varepsilon^{1/2}(1-\varepsilon)^{1/2}\big)\\
 &<\varepsilon+\varepsilon^{\alpha}+2\varepsilon 
 -2\varepsilon^{1/2}(1 -\varepsilon)^{1/2} \\
&<
4\varepsilon -2\varepsilon^{1/2}(1 -\varepsilon)^{1/2}\\
 & <2\varepsilon^{1/2}\big(2\varepsilon^{1/2}- (1 -\varepsilon)^{1/2}\big)
 \le 0\,,
 \endalign
 $$ 
which implies that (H3) does not hold for this example. 

\head
2. Key Lemmas
\endhead

In [1], the following {\it spherical truncation function} 
$$
T_{\alpha}(y)=\min\{1,\frac \alpha{|y|}\}y \tag 2.1
$$
is used with $\alpha>0$ and $y=(y_1,\hdots,y_m)\in \Bbb R^m$. 
Roughly speaking, $T_{\alpha}(u)$ is used as a test function for
system (1.1) in [1].
Direct calculation shows that 
$$
DT_{\alpha}(y)=\cases \Id, &\text{for $|y|\le \alpha$},\\
                      \frac{\alpha}{|y|}(\Id-\frac y{|y|}\otimes 
                  \frac y{|y|}), &\text{for $|y|> \alpha$}.
            \endcases
$$

 From this viewpoint, it is easy to understand 
why the structure condition (H3) is assumed in [1] and [2].
In this note we introduce the following {\it cubic truncation function}
$$
\align
{\Cal T}_{\alpha}(y)&=\big(T_{\alpha}(y_1),\hdots,T_{\alpha}(y_m)\big)\\
                    &=\big(\max\{-\alpha,\min\{\alpha,y_1\}\},\hdots,
                \max\{-\alpha,\min\{\alpha,y_m\}\}\big)
\tag 2.2
\endalign
$$
to build up some simpler test functions when the sign condition (H3)'
is satisfied.

To prove Theorem 2,  we only need to prove Lemmas 10
and 11 in [1] as we explained in the introduction. First we recall

\proclaim{Lemma 10}
Let $\varOmega\subset \Bbb R^n$ be an open set and 
$f\in L^1(\varOmega;\Bbb R^m)$. Assume that $\sigma$ satisfies (H2) and
(H3)' with $p=q$ and that $u\in W^{1,p}_0(\varOmega;\Bbb R^m)$ is a solution
of 
$$
-\dive \sigma\big(x,u(x),Du(x)\big)=f(x) \tag 2.3
$$
in the sense of distributions.  
Then 
$$
u\in L^{s^*,\infty}(\varOmega;\Bbb R^m),\quad 
Du\in L^{s,\infty}(\varOmega;\Bbb M^{m\times n})
$$ 
where 
$$
s=\frac n{n-1}(p-1),\quad s^*=\frac{ns}{n-s}=\frac{n}{n-p}(p-1).
$$
Moreover, 
$$
\|u\|^*_{L^{s^*,\infty}(\varOmega)}+\|Du\|^*_{L^{s,\infty}
(\varOmega)}\le C(c_1,c_2, \|f\|_{L^1},
\meas\varOmega).\tag
2.4
$$
\endproclaim

\demo{Proof}
In the weak formulation of (2.3) we use the test function ${\Cal T}_
{\alpha}(u)$ to replace $T_{\alpha}(u)$ in [1]. Then we have
$$
\sum^m_{i=1}\int_{|u_i|\le \alpha} \sigma_i(x,u,Du)\cdot Du_i \,dx
= \int_{\varOmega}f\cdot{\Cal T}_{\alpha}(u)\,dx\le  m\alpha\|f\|_{L^1}.
$$
By (H2) and (H3)', we obtain 
$$
\aligned 
\int_{\max\{|u_1|,\hdots,|u_m|\} \le \alpha} (c_1|Du|^p-c_2) \,dx
& \le \int_{\max\{|u_1|,\hdots,|u_m|\} \le \alpha}
 \sigma(x,u,Du): Du \,dx\\
&\le  \sum^m_{i=1}\int_{|u_i|\le \alpha} \sigma_i(x,u,Du)\cdot Du_i \,dx,
\endaligned
$$
which implies
$$
\int_{|u|\le \alpha} |Du|^p \,dx
\le \int_{\max\{|u_1|,\hdots,|u_m|\} \le \alpha} |Du|^p \,dx
\le C(\alpha\|f\|_{L^1}+\meas\varOmega).\tag 2.5
$$
Actually (2.5) is exactly (4.5) in [1], which is the starting point
for proving (2.4). Now following the same procedure as in [1],
 we obtain (2.4). 
\enddemo

And now we  prove Lemma 11 in [1]. It contains a div-curl inequality, 
which is the crucial ingredient for the argument in [1].

Let $f^k(x):\varOmega\to\Bbb R^m$ denote a bounded sequence in 
$L^1(\varOmega)$. Suppose that $u^k\in W^{1,1}(\varOmega;\Bbb R^m)$ is
the weak solution of the system 
$$
-\dive \sigma\big(x,u^k(x),\,Du^k(x)\big)=f^k(x)\tag 2.6
$$
with $Du^k\in L_{\loc}^r(\varOmega; \Bbb M^{m\times n})$ and 
$\sigma^k(x)=\sigma \big(x,u^k(x),Du^k(x)\big)\in L_{\loc}^{r'}
(\varOmega; \Bbb M^{m\times n})$
 for some $r\in (1,\infty)$. Suppose further that
(1) there exist an $s>0$ such that $\int_{\varOmega}|Du^k|^s\,dx\le C$
uniformly in $k$, (2) $\sigma^k$ is equi-integrable, (3) $u^k\to u $ in
measure and $u$ is almost everywhere approximately differentiable.

And we may assume that $\{Du^k\}$ generates a Young measure $\nu$ (see
[3]) such that $\nu_x$ is a probability measure for almost every $x\in
\varOmega$, see Theorem 5 (iii) in [1]. Now we recall 

\proclaim{Lemma 11}
Suppose the sequence $\{u^k\}$ is constructed as above. Then (after
passage to a subsequence) the sequence $\sigma^k(x)$ converges weakly to  
$\bar \sigma(x)$ in $ L^1(\varOmega)$ where 
$$
\bar \sigma(x)=\langle \nu_x,\sigma(x,u(x),\cdot)\rangle=
\int_{\Bbb M^{m\times
n}}\sigma(x,u(x),\lambda)\,d\nu_x(\lambda)\,.
$$
Moreover, the following inequality holds,
$$
\int_{\Bbb M^{m\times
n}}\sigma(x,u(x),\lambda):\lambda\,d\nu_x(\lambda)\le 
\bar\sigma(x): \ap Du(x)\quad \text{for a.e. } x\in \varOmega\,.
\tag 2.7
$$
\endproclaim

\demo{Proof}
First we choose $\varphi_1\in C^{\infty}_0(\varOmega;\Bbb R)$ with
$\varphi_1\ge 0$ and  $\int_{\varOmega}\varphi_1\,dx=1$. Choosing 
the test function ${\Cal T}_1(u^k-v)\varphi_1$ in (2.6) where $v
\in C^1(\varOmega;\Bbb R^m)$ is a suitable comparison function
as in [1], we have 
$$
\int_{\varOmega}\sigma^k:D\big({\Cal T}_1(u^k-v)\varphi_1\big)\,dx=
\int_{\varOmega}f^k\cdot {\Cal T}_1(u^k-v)\varphi_1\,dx\,.\tag 2.8
$$
Let $h^k =\sigma^k:D\big({\Cal T}_1(u^k-v)\varphi_1\big)$. Then
$$
\align
h^k &=\sigma^k:D{\Cal T}_1(u^k-v)D(u^k-v) \varphi_1+
    \sigma^k:{\Cal T}_1(u^k-v)\otimes D\varphi_1\\
    &=\sum^m_{i=1}\sigma^k_i\cdot Du^k_i \chi_{\{|u^k_i-v_i|\le 1\}}
    \varphi_1- \sum^m_{i=1}\sigma^k_i\cdot Dv_i \chi_{\{|u^k_i-v_i|\le 1\}}
    \varphi_1\\
    &\quad+ \sigma^k:{\Cal T}_1(u^k-v)\otimes D\varphi_1.
 \endalign
 $$
 
 In view of (H3)', the first term on the right hand side of the last
equality is nonnegative. 
Recalling our assumptions, we conclude that $(h^k)^{-}$
is equi-integrable. By Theorem 5, Lemma 6 in [1] and the
equi-integrability of $\sigma^k(x)$ together with the convergence of $u^k(x)$ in
measure we obtain
$$
\align
\liminf_{k\to\infty}\int_{\varOmega} h^k\,dx &\ge
\int_{\varOmega}\varphi_1\int_{\Bbb M^{m\times n}}\sigma\big(x,u(x),\lambda
\big):D{\Cal T}_1(u-v)\big(\lambda-Dv(x)\big)\,d\nu_x(\lambda)\,dx\\
&\quad +\int_{\varOmega}\bar\sigma:{\Cal T}_1(u-v)\otimes D\varphi_1\,dx\,.
\endalign
$$
The right hand side of (2.8) may be estimated as in [1]. 
And then we use the  blow-up method in [1] to prove (2.7)  with
some minor changes.
\enddemo

Now the lemmas involving (H3) in [1] have been proved if (H3) is
replaced by (H3)'. Therefore, Theorem 2 and other results in [1] hold.
\medskip

\noindent {\bf Acknowledgements:} The author would like to thank the
anonymous referee for reading an early version of this article and  
offering his/her valuable suggestions. 


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\enddocument