\documentclass[reqno]{amsart}
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\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2009(2009), No. 138, pp. 1--13.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2009 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2009/138\hfil Differential equations in exterior domains]
{Quasilinear differential equations in exterior domains with
nonlinear boundary conditions and application}

\author[D. Motreanu, N. Tarfulea\hfil EJDE-2009/138\hfilneg]
{Dumitru Motreanu, Nicolae Tarfulea}  % in alphabetical order

\address{Dumitru Motreanu \newline
D\'{e}partement de Math\'{e}matiques, Universit\'{e} de Perpignan,
66025 Perpignan, France}
\email{motreanu@univ-perp.fr}

\address{Nicolae Tarfulea \newline
Department of Mathematics, Purdue University Calumet, IN 46323, USA}
\email{tarfulea@calumet.purdue.edu}

\thanks{Submitted October 5, 2009. Published October 30, 2009.}
\subjclass[2000]{35J65, 83C05}
\keywords{Quasilinear equation; exterior domain; general relativity;
 \hfill\break\indent nonlinear boundary conditions;
initial data problem; conformal factor}

\begin{abstract}
 We investigate the existence of weak solutions to a class of
 quasilinear elliptic equations with nonlinear Neumann boundary
 conditions in exterior domains. Problems of this kind arise in
 various areas of science and technology. An important model case
 related to the initial data problem in general relativity is
 presented. As an application of our main result, we deduce the
 existence of the conformal factor for the Hamiltonian constraint
 in general relativity in the presence of multiple black holes.
 We also give a proof for uniqueness in this case.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{remark}[theorem]{Remark}

\section{Introduction}

Let $\Omega\subset\mathbb{R}^N$ be an exterior domain with smooth
compact boundary. In this paper, we study the existence and
uniqueness of solutions of the following elliptic boundary-value
problem
\begin{gather}\label{quasi}
-\mathop{\rm div}{[A(x,\nabla u)]}=F(x,u),\quad x\in\Omega,\\
\label{quasi_bc}
A(x,\nabla u)\cdot n=f(x,u),\quad x\in\partial\Omega,
\end{gather}
where $n$ stands for the unit exterior normal to $\partial\Omega$.
Here $A:\Omega\times\mathbb{R}^N\to\mathbb{R}^N$ is a Carath\'{e}odory
function satisfying the following conditions:
\begin{itemize}
\item There exist $p>1$, $a_1(\cdot)\in L^{p'}(\Omega)$
 ($p'$ is the conjugate of $p$, that is $1/p+1/p'=1$), and $b_1>0$
such that $|A(x,\xi )|\leq a_1(x)+b_1|\xi |^{p-1}$, for
a.e. $x\in\Omega$ and all $\xi\in \mathbb{R}^N$.

\item $A(x,\xi)$ is strictly monotone in $\xi$, that is
$[A(x,\xi_2)-A(x,\xi_1)]\cdot (\xi_2-\xi_1)>0$, for a.e.
$x\in\Omega$ and all $\xi_1$, $\xi_2\in\mathbb{R}^N$ with
$\xi_1\not=\xi_2$.

\item There exist $a_2\in L^1(\Omega)$ and $b_2>0$ such that the
following coercivity property holds
$A(x,\xi)\cdot\xi\geq b_2|\xi|^p-a_2(x)$, for a.e. $x\in\Omega$ and
all $\xi\in \mathbb{R}^N$.
\end{itemize}

Problems of this type arise in many and diverse contexts like
differential geometry (e.g., in the scalar curvature problem and
the Yamabe problem), nonlinear elasticity, non--Newtonian fluid
mechanics, mathematical biology, general relativity, and
elsewhere. In Section~\ref{sec3} we address one of these
applications related to the initial data problem in general
relativity (more precisely, the existence of conformal factor to
the Hamiltonian constraint equation in the case of multiple black
holes).

Nonlinear boundary value problems related to
\eqref{quasi}-\eqref{quasi_bc} have been studied for some time by
numerous authors and in variuos frameworks. For example, in
\cite{Pfluger} Pfl\"{u}ger considered the problem
\eqref{quasi}-\eqref{quasi_bc} for the $p$-Laplacian with
polynomial nonlinearities on the right hand side and in the
boundary condition. In this context, Pfl\"{u}ger showed the
existence of a nontrivial, positive weak solution. Due to the
unbounded domain, the lack of compactness was overcome through the
use of weighted Sobolev spaces. For more recent work on this
subject, see
\cite{CMR,CW,Kandilakis,Ma,Mezei,Montefusco,Pfluger2,Ta2,VC-S},
and references therein.


We denote by $W^{1,p}(\Omega)$ the weighted Sobolev space (the
suitable weight function in our case is $(1+|x|^2)^{-1/2}$  for
$x\in \Omega$)
\[
W^{1,p}(\Omega):=\{u\in L^p_{\rm loc}(\Omega):
\frac{u}{(1+|x|^2)^{1/2}}\in L^p(\Omega)\text{ and } \nabla u\in
L^p(\Omega)\}.
\]
Notice that on each bounded part of the open set $\Omega$,  the
space $W^{1,p}(\Omega)$ coincides with the usual Sobolev space
$W^{1,p}_{\rm loc}(\Omega)$. Functions in these two spaces differ only
by their behaviour at infinity. For more on these spaces, see
\cite{Nedelec, SWM}, and references therein.

A variational formulation for the exterior boundary-value  problem
\eqref{quasi} and \eqref{quasi_bc} is
\[
\int_{\Omega} A(x,\nabla u)\cdot\nabla v\,
dx-\int_{\Omega}F(x,u)v\, dx-\int_{\partial\Omega}f(x,u)v\,
d\sigma=0, \quad \forall v\in W^{1,p}(\Omega).
\]
A function $\underline{u}$ (resp. $\overline{u}$) in
$W^{1,p}(\Omega)$ is called a (weak) \emph{subsolution} (resp. \emph{
supersolution}) of \eqref{quasi} and \eqref{quasi_bc} if
\begin{equation}
\int_{\Omega} A(x,\nabla \underline{u})\cdot\nabla v\,
dx-\int_{\Omega}F(x,\underline{u})v\, dx-
\int_{\partial\Omega}f(x,\underline{u})v\, d\sigma\leq 0, \quad
\text{(resp. $\geq$)}
\end{equation}
for each $v\in W^{1,p}(\Omega),\  v\geq 0$ a.e. in $\Omega$.

Under the above conditions, our main result may be stated as follows.

\begin{theorem} \label{result}
Assume there exist a pair of sub-
and supersolution $\underline{u}$ and $\overline{u}$ of
\eqref{quasi}-\eqref{quasi_bc} and that the functions $F$ and $f$
satisfy the following growth conditions:
\begin{itemize}
\item There exists $a_3\in L^{p'}(\Omega)$ such that
 $|F(x,u)|\leq a_3(x)/(1+|x|^2)^{1/2}$, for a.e. $x\in\Omega$
and all $u\in [\underline{u}(x),\overline{u}(x)]$.
\item There exist $a_4\in L^{p'}(\partial\Omega)$ and
$b_3\in L^p(\partial\Omega)$ such that $|f(x,u)|\leq
a_4(x)+b_3(x)|u|^{p-1}$, for a.e. $x\in\partial\Omega$ and  all
$u\in [\underline{u}(x),\overline{u}(x)]$.
\end{itemize}
Then, \eqref{quasi}-\eqref{quasi_bc} has at least one (weak)
solution $u\in W^{1,p}(\Omega)$ such that
$\underline{u}\leq u\leq\overline{u}$.
\end{theorem}

A proof of this theorem is given in Section~\ref{sec2}.  As an
application of this result, we will discuss the existence of the
conformal factor for the Hamiltonian constraint in general
relativity in Section~\ref{sec3}. We also provide a proof for the
uniqueness of the conformal factor in the case of multiple black
holes in Subsection~\ref{Nbh}.

\section{Proof of Theorem~\ref{result}}
\label{sec2}
Let $\rho:=(1+|x|^2)^{1/2}$. For $u\in W^{1,p}(\Omega)$, define
\[
b(x,u):=\begin{cases}
[u(x)-\overline{u}(x)]^{p-1}/\rho^p & \text{if }u(x)>\overline{u}(x)\\
0 & \text{if }\underline{u}(x)\leq u(x) \leq \overline{u}(x)\\
-[\underline{u}(x)-u(x)]^{p-1}/\rho^p &  \text{if
}u(x)<\underline{u}(x)
\end{cases}
\]
\[ (Tu)(x):=\begin{cases}
\overline{u}(x) & \text{if }u(x)>\overline{u}(x)\\
u(x) & \text{if }\underline{u}(x)\leq u(x) \leq \overline{u}(x)\\
\underline{u}(x) &  \text{if }u(x)<\underline{u}(x)
\end{cases}
\]
Next, consider the operators $\mathcal{A}$, $\mathcal{B}$,
$\mathcal{F}$, and $\mathcal{G}:W^{1,p}(\Omega)\to
(W^{1,p}(\Omega))^*$ defined by:
\begin{gather*}
\langle \mathcal{A}(u),v\rangle:=\int_{\Omega}A(x,\nabla u)\cdot\nabla v\, dx,\quad
\langle \mathcal{B}(u),v\rangle:=\int_{\Omega}b(x,u)v\, dx,
\\
\langle \mathcal{F}(u),v\rangle:=-\int_{\Omega}F(x,Tu)v\, dx,\quad
\langle \mathcal{G}(u),v\rangle:=-\int_{\partial\Omega}f(x,Tu)v\,
d\sigma,
\\
\Gamma :W^{1,p}(\Omega)\to (W^{1,p}(\Omega))^*,\quad \Gamma (u):=\mathcal{A}(u)+
\mathcal{B}(u)+\mathcal{F}(u)+\mathcal{G}(u).
\end{gather*}
The following lemma states that solving $\Gamma (u)=0$ in
$(W^{1,p}(\Omega))^*$
produces a weak solution $u$ to problem
\eqref{quasi}--\eqref{quasi_bc}, with $\underline{u}\leq u\leq
\overline{u}$ a.e. in $\Omega$.
Its proof relies on arguments largely similar to the ones used
in \cite{LS1,LS2} (see also \cite{CLM})
in a different context.

\begin{lemma} \label{existence}
Assume that $u\in W^{1,p}(\Omega)$ is a
solution to $\Gamma (u)=0$. Then $u$ is also a week solution to
\eqref{quasi}--\eqref{quasi_bc}, with $\underline{u}(x)\leq
u(x)\leq \overline{u}(x)$ a.e. in $\Omega$.
\end{lemma}

\begin{proof}
Since $u$ and $\underline{u}$ are elements of $W^{1,p}(\Omega)$,
it follows that $(\underline{u}-u)^+\in W^{1,p}(\Omega)$. Then
\begin{equation}
\label{gammau} \langle \Gamma u,
(\underline{u}-u)^+\rangle=\langle \mathcal{A}(u)+
\mathcal{B}(u)+\mathcal{F}(u)+\mathcal{G}(u),(\underline{u}-u)^+\rangle=0,
\end{equation}
and so
\begin{equation} \label{gammaue}
\begin{aligned}
&\int_{\Omega}A(x,\nabla u)\cdot\nabla (\underline{u}-u)^+\, dx
+\int_{\Omega}b(x,u)(\underline{u}-u)^+\, dx\\
&-\int_{\Omega}F(x,Tu)(\underline{u}-u)^+\,
dx-\int_{\partial\Omega}f(x,Tu)(\underline{u}-u)^+\, d\sigma =0.
\end{aligned}
\end{equation}
Since $\underline{u}$ is a subsolution to
\eqref{quasi}--\eqref{quasi_bc}, we have
\begin{equation}\label{subsolest}
\int_{\Omega} A(x,\nabla
\underline{u})\cdot\nabla (\underline{u}-u)^+\, dx-
\int_{\Omega}F(x,\underline{u})(\underline{u}-u)^+\, dx-
\int_{\partial\Omega}f(x,\underline{u})(\underline{u}-u)^+\,
d\sigma\leq 0.
\end{equation}
Subtracting \eqref{gammaue} from \eqref{subsolest} gives
\begin{equation} \label{0b}
\begin{aligned}
&\int_{\Omega} [A(x,\nabla \underline{u})-A(x,\nabla
u)]\cdot\nabla (\underline{u}-u)^+\, dx
-\int_{\Omega}[F(x,\underline{u})-F(x,Tu)](\underline{u}-u)^+\, dx\\
&-\int_{\partial\Omega}[f(x,\underline{u})-f(x,Tu)](\underline{u}-u)^+\,
d\sigma\\
&\leq  \int_{\Omega}b(x,u)(\underline{u}-u)^+\, dx.
\end{aligned}
\end{equation}
Observe that (from the hypotheses and Stampachia's Theorem)
\begin{equation} \label{1b}
\begin{aligned}
&\int_{\Omega} [A(x,\nabla \underline{u})-A(x,\nabla u)]
 \cdot\nabla (\underline{u}-u)^+\, dx\\
&=\int_{\{\underline{u}(x)>u(x)\} }[A(x,\nabla
\underline{u})-A(x,\nabla u)]\cdot(\nabla \underline{u}- \nabla
u)\, dx\geq 0.
\end{aligned}
\end{equation}
Furthermore, from the definition of $Tu$, it follows that
$Tu(x)=\underline{u}(x)$ on $\{\underline{u}(x)>u(x)\}$, and so
\begin{equation} \label{2b}
\begin{aligned}
&\int_{\Omega}[F(x,\underline{u})-F(x,Tu)](\underline{u}-u)^+\, dx\\
&=\int_{\{\underline{u}(x)>u(x)\}
}[F(x,\underline{u})-F(x,Tu)](\underline{u}-u)\, dx=0.
\end{aligned}
\end{equation}
Also,
\begin{equation} \label{3b}
\begin{aligned}
&\int_{\partial\Omega}[f(x,\underline{u})-f(x,Tu)](\underline{u}-u)^+\, d\sigma \\
&=\int_{\{x\in\partial\Omega:\,\underline{u}(x)>u(x)\}
}[f(x,\underline{u})-f(x,Tu)](\underline{u}-u)\, d\sigma=0.
\end{aligned}
\end{equation}
By \eqref{0b}, \eqref{1b}, \eqref{2b}, and \eqref{3b}, we obtain
\[
0\leq \int_{\Omega}b(x,u)(\underline{u}-u)^+\, dx
=-\int_{\{\underline{u}(x)>u(x)\} }(\underline{u}-u)^p/\rho^p\, dx\leq 0,
\]
and thus $\underline{u}=u$ a.e. in $\{ \underline{u}(x)>u(x)\}$.
That is, the set $\{ \underline{u}(x)>u(x)\}$ has measure 0. This
shows that $\underline{u}(x)\leq u$ a.e. in $\Omega$. For the
inequality $u(x)\leq \overline{u}$ a.e. in $\Omega$, we proceed
similarly (by considering $(u-\overline{u})^+$ this time). Since
$\underline{u}(x)\leq u(x)\leq \overline{u}(x)$ a.e. in $\Omega$,
we have both $b(x,u(x))=0$ and $Tu(x)=0$ a.e. in $\Omega$. Thus,
$u$ is a weak solution of \eqref{quasi}--\eqref{quasi_bc}.
\end{proof}

\begin{lemma}
\label{boundedness}
The operator $\Gamma $ is bounded.
\end{lemma}

\begin{proof}
Let $M$ be a bounded subset of $W^{1,p}(\Omega)$, that is, there
exists a constant $C_1\geq 0$ such that $\|
u\|_{W^{1,p}(\Omega)}\leq C_1$, for all $u\in M$. Our goal is to
prove that there is a constant $C_2\geq 0$ such that $\|\Gamma
(u)\|_{W^{1,p}(\Omega)^*}\leq C_2$, for all $u\in M$. Hereafter,
the symbol $\lesssim$ between two terms means that the first term
is bounded from above by the second term up to a multiplicative
positive constant that may depend on $M$ but not on the individual
elements of $M$.


For $u\in M$ and $v\in W^{1,p}(\Omega)$, we have
\begin{equation}
\label{ineq}
|\langle \Gamma (u),v\rangle |\leq |\langle \mathcal{A}(u),v\rangle |
+ |\langle\mathcal{B}(u),v\rangle |+|\langle\mathcal{F}(u),v\rangle |+
|\langle\mathcal{G}(u),v\rangle |.
\end{equation}
Let us place an upper bound on the terms on the right-hand side of inequality \eqref{ineq}.
\begin{equation}\label{A}
\begin{aligned}
|\langle \mathcal{A}(u),v\rangle |
&\leq \int_{\Omega}| A(x,\nabla u)|\cdot |\nabla u | dx\\
& \leq \int_{\Omega}(a_1(x)+b_1|\nabla u|^{p-1})\cdot |\nabla v| dx\\
& \leq \| a_1\|_{L^{p'}(\Omega)}\|\nabla v\|_{L^{p}(\Omega)}+
b_1\|\nabla u\|^{p-1}_{L^{p}(\Omega)}\|\nabla v\|_{L^{p}(\Omega)}\\
& \leq (\| a_1\|_{L^{p'}(\Omega)}+b_1\| u\|^{p-1}_{W^{1,p}(\Omega)})\| v\|_{W^{1,p}(\Omega)}\\
& \lesssim \| v\|_{W^{1,p}(\Omega)}
\end{aligned}
\end{equation}
Next, observe that
\begin{align*}
|b(x,u)|
&\leq \rho^{-p}(|u(x)|+|\overline{u}(x)|+|\underline{u}(x)|)^{p-1}\\
&\lesssim \rho^{-p}(|u(x)|^{p-1}+|\overline{u}(x)|^{p-1}
+|\underline{u}(x)|^{p-1})\\
&\lesssim \rho^{-1}A_1(x)+\rho^{-p}|u(x)|^{p-1},
\end{align*}
with $A_1(x):=|\rho^{-1}\overline{u}(x)|^{p-1}+|\rho^{-1}\underline{u}(x)|^{p-1}\in L^{p'}(\Omega)$. Thus,
\begin{equation} \label{B}
\begin{aligned}
|\langle\mathcal{B}(u),v\rangle |
&\leq \int_{\Omega}|b(x,u)|\cdot |v|dx\\
&\lesssim \int_{\Omega}(A_1(x)+|\rho^{-1}u|^{p-1})|\rho^{-1}v|dx\\
&\lesssim (\| A_1\|_{L^{p'}(\Omega)}+ \|\rho^{-1}u\|_{L^{p}(\Omega)}^{p-1})\|\rho^{-1}v\|_{L^{p}(\Omega)}\\
&\lesssim \| v\|_{W^{1,p}(\Omega)}.
\end{aligned}
\end{equation}
For the third term of the right-hand side of \eqref{ineq} we obtain
the following upper bound
\begin{equation} \label{F}
\begin{aligned}
|\langle\mathcal{F}(u),v\rangle |
&\leq \int_{\Omega}|F(x,Tu)|\cdot |v|dx\\
&\leq \int_{\Omega}\rho^{-1}a_3(x)|v|dx\\
&\leq \| a_3\|_{L^{p'}(\Omega)}\| \rho^{-1}v\|_{L^{p}(\Omega)}\\
&\lesssim \| v\|_{W^{1,p}(\Omega)}.
\end{aligned}
\end{equation}
Finally, for the last term of the right-hand side of \eqref{ineq} we have
\begin{equation} \label{G}
\begin{aligned}
|\langle\mathcal{G}(u),v\rangle |
&\leq \int_{\partial\Omega}|f(x, Tu)|\cdot |v|d\sigma \\
&\leq \int_{\partial\Omega}(a_4(x)+b_3(x)|Tu|^{p-1})\cdot |v|d\sigma \\
&\leq \int_{\partial\Omega}[a_4(x)+b_3(x)(| \underline{u}(x)|^{p-1}+| \overline{u}(x)|^{p-1})]\cdot |v|d\sigma \\
&\leq \| a_4(x)+b_3(x)(| \underline{u}(x)|^{p-1}+| \overline{u}(x)|^{p-1})\|_{L^{p'}(\partial\Omega)}
\| v\|_{L^{p}(\partial\Omega)}\\
&\lesssim \| v\|_{W^{1,p}(\Omega)},
\end{aligned}
\end{equation}
where the last inequality is a consequence of the trace theorem.
Returning to inequality \eqref{ineq}, and using
\eqref{A}, \eqref{B}, \eqref{F}, and \eqref{G}, it follows that
there exists a positive constant $C_2$ such that
$|\langle \Gamma (u),v\rangle |\leq C_2\| v\|_{W^{1,p}(\Omega)}$,
for all $u\in M$ and all $v\in W^{1,p}(\Omega)$;
 that is, $\|\Gamma (u)\|_{W^{1,p}(\Omega)^*}\leq C_2$, for all $u\in M$.
\end{proof}

\begin{lemma} \label{coercivity}
The operator $\Gamma$ is coercive; that is,
\begin{equation}
\label{coercive}
\lim_{\| u\|_{W^{1,p}(\Omega)}\to\infty}
\frac{\langle \Gamma (u),u\rangle}{\| u\|_{W^{1,p}(\Omega)}}=\infty.
\end{equation}
\end{lemma}

\begin{proof}
First of all, observe that
\begin{equation} \label{AA}
\langle \mathcal{A}(u),u\rangle\geq b_2\|\nabla u\|^p_{L^p(\Omega)}
-\| a_2\|_{L^1(\Omega)}.
\end{equation}
It is easy to prove that, for $a>b$ and $p>1$, there are positive
constants $C_1$, $C_2$, $C_3$, and $C_4$ (independent of $a$, $b$)
such that $(a-b)^{p-1}a\geq C_1|a|^p-C_2|b|^{p-1}|a|$ and
$(a-b)^{p-1}b\leq C_3|a|^{p-1}|b|-C_4|b|^p$. Then
\begin{equation} \label{BB}
\begin{aligned}
\langle \mathcal{B}(u),u\rangle
&=\int_{\{ u>\overline{u}\}}\rho^{-p}(u-\overline{u})^{p-1}u\, dx
-\int_{\{ u<\underline{u}\}}\rho^{-p}(\underline{u}-u)^{p-1}u\, dx\\
&\geq \int_{\{ u>\overline{u}\}}\rho^{-p}(C_1|u|^p-C_2| \overline{u}|^{p-1}|u|)dx\\
&\quad +\int_{\{ u<\underline{u}\}}\rho^{-p}(C_4|u|^p-C_3|
 \underline{u}|^{p-1}|u|)dx\\
&\geq\min{\{ C_1,C_4\}}\| \rho^{-1}u\|^p_{L^p(\Omega)}-C_5\|
  \rho^{-1}u\|_{L^p(\Omega)},
\end{aligned}
\end{equation}
with $C_5:=C_2\| \rho^{-1}\overline{u}\|^{p-1}_{L^p(\Omega)}
+C_3\| \rho^{-1}\underline{u}\|^{p-1}_{L^p(\Omega)}$.
Also,
\begin{equation}
\label{FF}
\langle\mathcal{F}(u),u\rangle
\geq -\| a_3\|_{L^{p'}(\Omega)}\| \rho^{-1}u\|^p_{L^p(\Omega)}
\geq -\| a_3\|_{L^{p'}(\Omega)}\| u\|^p_{W^{1,p}(\Omega)}
\end{equation}
and
\begin{equation} \label{GG}
\begin{aligned}
\langle\mathcal{G}(u),u\rangle &\geq -\int_{\partial\Omega}[|a_4(x)|+|b_3(x)|(|\underline{u}(x)|^{p-1}
+|\overline{u}(x)|^{p-1})]|u|\, d\sigma\\
&\geq -\| |a_4|+|b_3|(|\underline{u}|^{p-1}+|\overline{u}|^{p-1})\|_{L^{p'}(\partial\Omega)}\| u\|_{L^p(\partial\Omega)}\\
&\geq -C_6\| |a_4|+|b_3|(|\underline{u}|^{p-1}+|\overline{u}|^{p-1})\|_{L^{p'}(\partial\Omega)}\| u\|_{W^{1,p}(\Omega)},
\end{aligned}
\end{equation}
where the last inequality follows from the trace theorem.
Combining \eqref{AA}, \eqref{BB}, \eqref{FF}, and \eqref{GG}, we get
\[
\langle \Gamma (u),u\rangle\geq C_7\| u\|_{W^{1,p}(\Omega)}^p-C_8\| u\|_{W^{1,p}(\Omega)}-C_9,
\quad\forall u\in W^{1,p}(\Omega),
\]
with $C_7$, $C_8$, $C_9>0$. Because $p>1$, this estimate implies \eqref{coercive}.
\end{proof}

 Fix an integer $n_0>\max_{x\in\partial\Omega}|x|$. For any $n\geq
n_0$, we set $\Omega_n=\{x\in\Omega:|x|<n\}$ and introduce the
space $W_n:=\{u\in W^{1,p}(\Omega_n): u=0\ \text{ on $|x|=n$}\}$.
Notice that we can consider that $W_n\subset W^{1,p}(\Omega)$ by
setting, for all $w\in W_n$, $w(x)=0$ whenever $x\in \Omega$ with
$|x|>n$ (which is possible since $w=0$ on $|x|=n$). For each
$n\geq n_0$, let $i_n:W_n\to W^{1,p}(\Omega)$ denote the inclusion
map and $i_n^*:W^{1,p}(\Omega)^*\to W_n^*$ its adjoint operator.
Fix $n\geq n_0$ and introduce the nonlinear operator
$\Gamma_{n}:W_n\to W_n^*$ by
\[
\Gamma_{n}:=i_n^*\Gamma i_n=i_n^*\mathcal{A}i_n+
i_n^*\mathcal{B}i_n+i_n^*\mathcal{F}i_n+i_n^*\mathcal{G}i_n.
\]

\begin{lemma} \label{et}
For every $n\geq n_0$, the equation
$\Gamma_{n}(u)=0$ has at least a solution (in $W_n$).
\end{lemma}

\begin{proof} The operator $\Gamma_{n}:W_n\to W_n^*$ is pseudomonotone
because it is the sum of the strictly monotone operator
$i_n^*\mathcal{A}i_n$ and the completely continuous operators
$i_n^*\mathcal{B}i_n$, $i_n^*\mathcal{F}i_n$,
$i_n^*\mathcal{G}i_n$ (which is true because the domain $\Omega_n$
is bounded). The operator $\Gamma_{n}$ is also bounded by
Lemma~\ref{boundedness} and the boundedness of the operators
$i_n$ and $i_n^*$. Moreover, from Lemma~\ref{coercivity},
we see that $\Gamma_{n}$ is coercive. The application of the abstract
surjectivity result (see \cite[Theorem 27.A]{Z}) completes the proof.
\end{proof}

\subsection{Proof of Theorem~\ref{result}}

Lemma~\ref{et} ensures that there exists $u_n\in W_n$ such that
\begin{equation} \label{11}
\begin{aligned}
&\int_{\Omega_n}A(x,\nabla u_n)\cdot\nabla v\, dx
+ \int_{\Omega_n}b(x,u_n)v\, dx\\
&-\int_{\Omega_n}F(x,Tu_n)v\, dx-\int_{\partial\Omega}f(x,Tu_n)v\,
d\sigma =0
\end{aligned}
\end{equation}
for all $v\in W_n$. Setting $v=u_n$ in \eqref{11} and using the
coercivity of the operator $\Gamma_{n}$ lead to the
conclusion that the sequence $\{u_n\}$ is bounded in
$W^{1,p}(\Omega)$.

Thus, up to a subsequence, we may suppose that $u_n\rightharpoonup u$ in
$W^{1,p}(\Omega)$, $u_n\to u$ in $L^p_{\rm loc}(\Omega)$ and a.e.
in $\Omega$ and $\nabla u_n\to \nabla u$ in $L^p_{\rm
loc}(\Omega,\mathbb{R}^N)$, for some $u\in W^{1,p}(\Omega)$. Let
$v\in C^\infty_0(\mathbb{R}^N)\cap W^{1,p}(\Omega)$. We note that
$v\in W_n$ for $n$ sufficiently large, so we can make use of
\eqref{11} which gives
\begin{equation} \label{12}
\begin{aligned}
\int_{{\rm supp} (v)}A(x,\nabla u_n)\cdot\nabla v\, dx+ \int_{{\rm supp} (v)}b(x,u_n)v\, dx\\
-\int_{{\rm supp} (v)}F(x,Tu_n)v\,
dx-\int_{\partial\Omega}f(x,Tu_n)v\, d\sigma =0.
\end{aligned}
\end{equation}
We may pass to the limit in \eqref{12} as $n\to\infty$. Since
$C^\infty_0(\mathbb{R}^N)\cap W^{1,p}(\Omega)$ is dense in
$W^{1,p}(\Omega)$, we arrive at $\Gamma u=0$. Now it suffices to
invoke Lemma~\ref{existence} for concluding that $u$ is a weak
solution of problem \eqref{quasi}--\eqref{quasi_bc} with
$\underline{u}(x)\leq u(x)\leq \overline{u}(x)$ a.e. in $\Omega$.

\begin{remark} \rm
One can show the uniqueness of the solution by
assuming additional conditions, such as  $F(x,\cdot)$ and $f(x,\cdot)$
are nonincreasing on the interval
$[\underline{u}(x),\overline{u}(x)]$ for a.e. $x\in\Omega$. Let $u_1, u_2\in
W^{1,p}(\Omega)$ be two weak solutions to
\eqref{quasi}--\eqref{quasi_bc} belonging to the ordered interval
$[\underline{u},\overline{u}]$. Then we can write
\begin{align*}
&\int_{\Omega}(A(x,\nabla u_1)-A(x,\nabla
u_2))\cdot\nabla (u_1-u_2)^+\, dx\\
&=\int_{\Omega}(F(x,u_1)-F(x,u_2)(u_1-u_2)^+\,
dx+\int_{\partial\Omega}(f(x,u_1)-f(x,u_2))(u_1-u_2)^+\, d\sigma.
\end{align*}
In view of our hypothesis and since the operator $A(x,\cdot)$ is
strictly monotone, we derive that $u_1\leq u_2$ (and similarly that $u_2\leq u_1$) a.e. in $\Omega$,
and so $u_1=u_2$ a.e. in $\Omega$.
\end{remark}


\section{Application to the Initial Data Problem in General Relativity}
\label{sec3}

In this section, we indicate an example where we apply
Theorem~\ref{result} to the existence of the conformal factor in
general relativity. We mention that  this section contains just an
example of aplication of Theorem~\ref{result}; it is in no way
intended to give a deep or extensive analysis of the complicated
initial data problem in general relativity. The interested reader
can find important advances on various aspects of this subject in
\cite{CIP,Dain,I,IM,HNT,HPP,Ma,Ma2,Maz,Ta,Tj}, among many others.

In Subsection~\ref{YorkL}, we briefly review York-Lichnerowicz's
formalism for decomposing the constraint equations. We then
discuss the existence of the conformal factor under certain
assumptions. Finally, in Subsection~\ref{Nbh}, we present an
elementary proof for the uniqueness in the case of multiple black
holes.

\subsection{York-Lichnerowicz conformal decomposition method}
\label{YorkL}

In general relativity, spacetime is a 4-dimensional manifold  of
events endowed with a pseudo-Riemannian metric $g_{\alpha \beta}$.
Einstein's equations $G_{\alpha \beta}=8\pi T_{\alpha \beta}$
connect the spacetime curvature represented by the Einstein tensor
$G_{\alpha \beta }$ with the stress-energy tensor $T_{\alpha \beta
}$. In fact, these are equations for geometries, that is, their
solutions are equivalent classes under spacetime diffeomorphisms
of metric tensors. To break this diffeomorphism invariance,
Einstein's equations must first be transformed into a system
having a well-posed Cauchy problem. That is, the spacetime is
foliated and each slice $\Sigma_t$ is characterized by its
intrinsic geometry $\gamma_{ij}$ and extrinsic curvature $K_{ij}$,
which is essentially the ``velocity'' of $\gamma_{ij}$ in the unit
normal direction to the slice. Subsequent slices are connected via
the lapse function $N$ and shift vector $\beta^i$ corresponding to
the Arnowitt--Deser--Misner (ADM) 3+1 formulation \cite{ADM} of
the line element
$ds^2=-N^2dt^2+\gamma_{ij}(dx^i+\beta^idt)(dx^j+\beta^jdt)$. This
decomposition allows one to express six of the ten components of
Einstein's equations in vacuum ($T_{\alpha\beta}=0$) as a
constrained system of evolution equations for the metric
$\gamma_{ij}$ and the extrinsic curvature $K_{ij}$ (repeated
subscript-superscript indices means summation):
\begin{gather}\nonumber
\dot{\gamma}_{ij} = -2NK_{ij} + 2 \nabla_{(i}\beta_{j)},
\\ \nonumber
\dot{K}_{ij} =
N(R_{ij}+K_l^lK_{ij}-2K_{il}K_j^l)+\beta^l\nabla_l K_{ij}
+K_{il}\nabla_j\beta^l + K_{lj}\nabla_i\beta^l-\nabla_i\nabla_j N,
\\ \label{ADM3}
R_i^i + (K_i^i)^2-K_{ij}K^{ij}=0,
\\ \label{ADM4}
\nabla^jK_{ij}-\nabla_iK_j^j=0,
\end{gather}
where we use a dot to denote time differentiation and $\nabla_j$
for the covariant derivative
associated to $\gamma_{ij}$. The spatial Ricci tensor
$R_{ij}$ has components given by second order spatial differential operators applied to
the spatial metric components $\gamma_{ij}$.
Indices are raised and traces taken with respect to the spatial metric
$\gamma_{ij}$, and parenthesized
indices are used to denote the symmetric part of a tensor (e.g.,
$\nabla_{(i}\beta_{j)}:=(\nabla_i\beta_j+\nabla_j\beta_i)/2$).


To evolve Einstein's equations in the standard ADM 3+1
formulation,  one needs to specify the 3-metric $\gamma_{ij}$ and
the extrinsic curvature $K_{ij}$ on the initial time slice
$\Sigma_0$. This is a difficult task, as these quantities must
satisfy the constraint equations \eqref{ADM3} and \eqref{ADM4}. We
outline here the conformal decomposition method of
York-Lichnerowicz (see \cite{CT,Tj,Y,Y2,YP}) for the vacuum
constraint equations. The base of the method consists of
specifying the physical data only up to conformal equivalence,
under the assumption that the trace of $K_{ij}$,
$K_i^i:=\gamma^{ij}K_{ij}$, is given and fixed. In essence, this
means that we look for a metric $\gamma_{ij}$ conformally related
to a given metric $\hat{\gamma}_{ij}$ by
$\gamma_{ij}=\psi^4\hat{\gamma}_{ij}$, where the conformal factor
$\psi$ is a strictly positive function to be determined. We will
denote by $\hat{\gamma}^{ij}$, $\hat{\nabla}_j$, and $\hat{R}$ the
inverse metric, covariant derivative operator, and scalar
curvature associated to the metric $\hat{\gamma}_{ij}$. We now
relate these to quantities based on the original metric
$\gamma_{ij}$. The inverse metric $\hat{\gamma}^{ij}$ and the
covariant derivative $\hat{\nabla}_j$ of scalars are easy:
$\gamma^{ij}= \psi^{-4}\hat{\gamma}^{ij}$ and
$\nabla_jK=\hat{\nabla}_jK$ and
$\nabla^jK=\psi^{-4}\hat{\nabla}^jK$ for any scalar function $K$.
For the covariant derivative of tensors and for the scalar
curvature, we need to relate the Christoffel symbols
$\hat{\Gamma}_{ij}^k$ formed with respect to $\hat{\gamma}^{ij}$
to the Christoffel symbols $\Gamma_{ij}^k$ formed with respect to
$\gamma^{ij}$. By direct calculation
\[
\Gamma_{jk}^i=\frac{1}{2}\gamma^{il}(\frac{\partial\gamma_{lj}}{\partial x^k}+
\frac{\partial\gamma_{lk}}{\partial x^j}-\frac{\partial\gamma_{jk}}{\partial x^l})=
\hat{\Gamma}_{jk}^i+2\psi^{-1}(\frac{\partial\psi}{\partial x^k}\delta_j^i+\frac{\partial\psi}{\partial x^j}\delta_k^i
-\frac{\partial\psi}{\partial x^l}\hat{\gamma}_{jk}\hat{\gamma}^{il}),
\]
and so
\[
\Gamma_{jk}^j=\hat{\Gamma}_{jk}^j+6\psi^{-1}\frac{\partial\psi }{\partial x^k}.
\]
Now, let us relate the extrinsic curvature $K^{ij}$ corresponding
to $\gamma_{ij}$ to a given symmetric $(2,0)$ tensor
$\hat{K}^{ij}$ by $K^{ij}=\psi^{-s}\hat{K}^{ij}$ for some $s$.
Then, by direct calculation,
\begin{align*}
\nabla_jK^{ij}
&=\frac{\partial K^{ij}}{\partial x^j}+\Gamma_{jl}^jK^{il}
+\Gamma_{jl}^iK^{lj}\\
&= \psi^{-s}\hat{\nabla}_j\hat{K}^{ij}-2\psi^{-s-1}
 \frac{\partial\psi}{\partial x^m}\hat{\gamma}^{im}\hat{K}
+(10-s)\psi^{-s-1}\frac{\partial\psi}{\partial x^l}\hat{K}^{il},
\end{align*}
where $\hat{K}=\hat{\gamma}_{ij}\hat{K}^{ij}$. This motivates the
choice $s=10$. Moreover, we choose the tensor $\hat{K}^{ij}$ to be
trace-free, i.e., $\hat{K}=0$. Then, the zero trace is preserved,
i.e., $K^{ij}$ is trace-free, and
$\nabla_jK^{ij}=\psi^{-10}\hat{\nabla}_j\hat{K}^{ij}$. The scalar
curvatures $R=\gamma_{ij}R^{ij}$ and
$\hat{R}=\hat{\gamma}_{ij}\hat{R}^{ij}$ are related by
$R=\psi^{-4}\hat{R}-8\psi^{-5}\hat{\Delta}\psi$, where
$\hat{\Delta}\psi:=\hat{\gamma}_{ij}\hat{\nabla}^i\hat{\nabla}^j\psi$
is the Laplacian of $\psi$ with respect to the metric
$\hat{\gamma}_{ij}$.

If we choose $\hat{\gamma}_{ij}$ to be the flat metric
$\hat{\gamma}_{ij}:=\delta_{ij}$, then the momentum constraints
\eqref{ADM4} are linear, decoupled from the Hamiltonian constraint
\eqref{ADM3} (as a consequence of the  assumption $\hat{K}=0$),
and solutions $\hat{K}_{ij}$ to them can be determined
analytically (see \cite{K,KSY,MY,Tj,Y,Y2,YP}, among others).
Moreover, the Hamiltonian constraint equation reduces to the
relatively simple semilinear elliptic equation
\begin{equation}
\label{eq:hame}
-\Delta \psi =\hat{H}\psi^{-7},
\end{equation}
where $\Delta :=\delta_{ij}\partial^i\partial^j$ is the usual  3D
Laplacian and $\hat{H}:=\frac{1}{8}\hat{K}^{ij}\hat{K}_{ij}$ is a
positive function. It is also necessary to specify the domain on
which this equation will be solved, and the boundary conditions
that will be applied.  In the case of multiple black holes, our
goal is to solve equation \eqref{eq:hame} in the exterior domain
$\Omega :=\{x\in \mathbf R^3:\, | x-O_i|>R_i,\, i=\overline{1,N}\}
$, where $O_i$, respectively $R_i,\, i=1,2,\dots,N$, are the
centers, respectively the radii, of the disjoint black holes.
Because we are interested in asymptotically flat spacetimes, we
would like that the conformal factor approach unity as the
distance from any sources approaches infinity:
\begin{equation}
\label{eq:bci} \psi (x)\to 1,\quad \text{as }|x|\to \infty .
\end{equation}
Also, we invoke an inner boundary condition (see \cite{CT,Tj,Y},
and references therein)
\begin{equation}
\label{eq:bc} \frac{\partial\psi}{\partial n}+\frac{1}{2R_i}\psi
=0 \quad \text{on }\partial B(O_i,\, R_i), \;  i=1,2,\dots,N,
\end{equation}
where the normal $n$ to $\partial B(O_i,R_i)$ points \emph{into}
the domain $\Omega$.

Let $u:=\psi -1$. For $\psi$ to be a solution of
\eqref{eq:hame}--\eqref{eq:bc}, $u$ must satisfy the following boundary
value problem in the exterior domain $\Omega$:
\begin{gather}
\label{hamet} -\Delta u =\hat{H}(1+u)^{-7}\quad \text{in
}\Omega,\\ \label{bcit} u(x)\to 0\quad \text{ as }|x|\to \infty,\\
\label{bct} \frac{\partial u}{\partial n}=-\frac{1}{2R_i}(1+u)
\quad \text{on }\partial B(O_i,\, R_i),\ i=1,2,\dots,N.
\end{gather}

\begin{theorem}
Suppose that $\rho \hat H\in L^2(\Omega)$. Then there exists at
least one (weak) solution $u\in W^{1,2}(\Omega)$ to
\eqref{hamet}--\eqref{bct}.
\end{theorem}

\begin{proof}
Observe that one can now apply Theorem~\ref{result} to the
boundary-value problem \eqref{hamet}--\eqref{bct} if a pair of
sub- and supersolution $\underline{u}$ and $\overline{u}$ can be
found. It is easy to see that $\underline{u}:\equiv 0$ is a
subsolution to \eqref{hamet}--\eqref{bct}. Furthermore, the
solution $\overline{u}\in W^{1,2}(\Omega)$ of the following
Dirichlet boundary-value problem (whose existence is guarateed by
\cite[Theorem 2.5.14]{Nedelec})
\[
-\Delta\overline{u}(x)=\hat H(x)\quad \text{in }\Omega,\quad
\overline{u}(x)=0\quad\text{ on }\partial\Omega,
\]
is a supersolution to \eqref{hamet}--\eqref{bct}. Moreover, by the
maximum principle one obtains $\overline{u}>0$ in  $\Omega$. Then,
by Theorem~\ref{result} it follows that there exists a weak
solution $u\in W^{1,2}(\Omega)$, with $(\underline{u}\equiv )0\leq
u\leq\overline{u}$, to the boundary-value problem
\eqref{hamet}--\eqref{bct}. In fact, by the maximum principle
again, $u$ is strictly positive in $\Omega$. In addition, since
$u\in W^{1,2}(\Omega)$, we also have that $u(x)\to 0$, as
$|x|\to\infty$, a.e. in $\Omega$.
\end{proof}


\subsection{The uniqueness in the general case of multiple black holes}
\label{Nbh} In 1989 York \cite{Y} proved that the solution for the
boundary value  problem \eqref{eq:hame}, \eqref{eq:bci}, and
\eqref{eq:bc} is locally unique, that is, he proved that no other
solutions lie in the neighborhood of a given solution, but this
does not preclude the existence of other solutions which are
``significantly different." Here the normal $n$ to $\partial
\Omega$ points into the domain $\Omega$, and this interferes with
an usual existence and uniqueness analysis for the problem. That
is, even though \eqref{eq:bc} looks like a Robin boundary
condition, it has the ``wrong'' sign between its two terms.
Therefore, as observed in \cite{Y}, one cannot give a standard
uniqueness argument for the problem \eqref{eq:hame},
\eqref{eq:bci}, and \eqref{eq:bc}. In what follows we give a
simple proof for uniqueness in the case of multiple black-holes;
it has some points in common with the proof pointed out by York in
\cite{Y}.

\begin{theorem}
There exists at most one solution to the elliptic exterior
boundary-value problem \eqref{eq:hame},
\eqref{eq:bci}, and \eqref{eq:bc}.
\end{theorem}

\begin{proof}
Arguing by contradiction, suppose that we have two distinct
solutions for \eqref{eq:hame}, \eqref{eq:bci}, and \eqref{eq:bc}.
Denote by $u$ and $v$ these two solutions. For each $i=1,\dots,
N$, by passing to spheric coordinates with respect to $O_i$, we
define a related function
\[
\tilde{u}_i(r,\theta,\phi )=\frac{R_i}{r}u(\overline{r},\theta,\phi),
\]
where $\overline{r}=R_i^2/r$, $0<r\leq R_i$. Note that
$\tilde{u}_i(R_i,\theta,\phi )=u(R_i,\theta,\phi )$.
Moreover, the first derivatives of $u$ and $\tilde{u}$ agree
at $r=R_i$ (we need only check the radial derivatives)
\[
\frac{\partial \tilde{u}_i}{\partial r}(r,\theta,\phi )
=-\frac{R_i}{r^2}u(\overline{r},\theta,\phi)-
\frac{R_i^3}{r^3}\frac{\partial u}{\partial r}(\overline{r},\theta,\phi),
\]
and so
\begin{equation}\label{eq:frd1}
\frac{\partial \tilde{u}_i}{\partial r}(R_i,\theta,\phi )
=-\frac{1}{R_i}u(R_i,\theta,\phi)-
\frac{\partial u}{\partial r}(R_i,\theta,\phi)
=\frac{\partial u}{\partial r}(R_i,\theta,\phi ),
\end{equation}
where the last equality in \eqref{eq:frd1} follows from the
boundary condition \eqref{eq:bc}.

Likewise, one finds that the second derivatives of $u$
and $\tilde{u}_i$ also match at $r=R_i$.
\[
\frac{\partial^2 \tilde{u}_i}{\partial r^2}(r,\theta,\phi )=\frac{2R_i}{r^3}u(\overline{r},\theta,\phi)+
\frac{4R_i^3}{r^4}\frac{\partial u}{\partial r}(\overline{r},\theta,\phi)+
\frac{R_i^5}{r^5}\frac{\partial^2 u}{\partial r^2}(\overline{r},\theta,\phi),
\]
and so
\begin{equation}
\label{eq:frd2}
\frac{\partial^2 \tilde{u}_i}{\partial r^2}(R_i,\theta,\phi )=\frac{4}{R_i}
\Big (\frac{\partial u}{\partial r}(R_i,\theta,\phi)+\frac{1}{2R_i}u(R_i,\theta,\phi)\Big )+
\frac{\partial^2 u}{\partial r^2}(R_i,\theta,\phi),
\end{equation}
where the first term of the right-hand side of \eqref{eq:frd2}
vanishes because of the boundary condition \eqref{eq:bc}.

Furthermore, simple computations show that
\begin{equation}
\label{deltadelta}
\Delta\tilde{u}_i(r,\theta,\phi)=\frac{R_i^5}{r^5}\Delta u(\overline{r},\theta,\phi).
\end{equation}
Hence we can extend $u$ as follows
\[
U(x)=\begin{cases}
u(x) &\text{for }x\in\overline{\Omega}\\
\tilde{u}_i(x) &\text{for }x\in J_i(\Omega)\subset B(O_i,R_i),\
i=1,2,\dots,N,
\end{cases}
\]
where
\[
J_i(x)=\frac{R_i^2}{|x-O_i|^2}(x-O_i)+O_i,
\]
for all $x\neq O_i$, $i=\overline{1,N}$. Observe that $U$ is  in
$C^2(\tilde{\Omega})$, $\tilde{\Omega}:=\Omega\cup J_1(\Omega)\cup
J_2(\Omega)\ldots\cup J_N(\Omega)$, and (as a consequence of
\eqref{deltadelta}) it satisfies the following differential
equation in the open set $\tilde{\Omega}$
\[
-\Delta U=\tilde{H}U^{-7},
\]
where
\[
\tilde{H}(x)=\begin{cases}
\hat{H}(x) &\text{for }x\in\overline{\Omega}\\
R_i^{12}|x-O_i|^{-12}\hat{H}(J_i^{-1}(x)) &\text{for }x\in
J_i(\Omega),\, i=1,2,\dots,N.
\end{cases}
\]

Doing the same for $v$, we get its extension $V$ in
$\tilde{\Omega}$. Without restricting generality, we can assume
$U(x)>V(x)$ in a nonzero measure subset of $\tilde\Omega$. Let
$w(x)=\ln{|U(x)/V(x)|}$. Since both $u$ and $v$ tend to $1$ as
$|x|\to \infty$ and by the construction of $U$ and $V$, it follows
that $\lim_{|x|\to\infty} |U(x)/V(x)|=1$ and $\lim_{x\to O_i}
|U(x)/V(x)|=1$, $i=1,2,\ldots, N$. Therefore,  there exists $x_0$
in the closure of the set $\tilde{\Omega}$ such that
$w(x_0)=\sup_{x\in\tilde{\Omega}}w(x)$. First, let us prove that
$x_0$ must belong to $\partial\tilde{\Omega}$. Arguing by
contradiction, assume that $x_0$ belongs to the interior of
$\tilde{\Omega}$. Then, from $\nabla w(x_0)=0$, it follows that
\[
\frac{1}{U(x_0)}\nabla U(x_0)=\frac{1}{V(x_0)}\nabla V(x_0),
\]
and so
\begin{equation} \label{eq:exp10}
\begin{aligned}
\Delta w(x_0)
&=\frac{1}{U(x_0)}\Delta
U(x_0)-\frac{1}{V(x_0)}\Delta V(x_0)\\
&\quad + \frac{1}{U(x_0)^2}|\nabla U(x_0)|^2
 -\frac{1}{V(x_0)^2}|\nabla V(x_0)|^2\\
&=-\tilde{H}(x_0)\Big (\frac{1}{U(x_0)^8}-\frac{1}{V(x_0)^8}\Big )>0,
\end{aligned}
\end{equation}
which is impossible. This forces $x_0$ to belong to
$\partial\tilde{\Omega}$.

Suppose that $x_0\in J_i(\partial B(O_j,R_j))$ for some $i$ and $j$,
with $i\neq j$. Then, for
$\tilde{x}_0:=J_i^{-1}(x_0)\in \partial B(O_j,R_j)$ we have
\[
w(\tilde{x}_0)=\ln{|U(\tilde{x}_0)/V(\tilde{x}_0)|}=\ln{|u(\tilde{x}_0)/v(\tilde{x}_0)|}=
\ln{|\tilde{u}_i(x_0)/\tilde{v}_i(x_0)|}=w(x_0),
\]
and so $w(\tilde{x}_0)=\sup_{x\in\tilde{\Omega}}w(x)$.
Since $\tilde{x}_0$ is an interior point of $\tilde{\Omega}$,
we get the same contradiction as in \eqref{eq:exp10}.
\end{proof}

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