
\documentclass[reqno]{amsart}

\AtBeginDocument{{\noindent\small
{\em Electronic Journal of Differential Equations},
Vol. 2005(2005), No. 09, pp. 1--16.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu  (login: ftp)}
\thanks{\copyright 2005 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2005/09\hfil Nonlinear Neumann problems]
{Nonlinear Neumann problems on bounded Lipschitz domains}
\author[A. Siai \hfil EJDE-2005/09\hfilneg]{Abdelmajid Siai}

\address{Abdelmajid Siai \hfill\break 
Institut Pr\'{e}paratoire aux \'{E}tudes
d'Ing\'{e}nieurs de Nabeul - 8050, Nabeul, Tunisie}
\email{abdelmejid.s@gnet.tn}

\date{}
\thanks{Submitted December 29, 2004. Published January 12, 2005.}
\thanks{Partially supported by DGRST and DAAD}
\subjclass[2000]{35J60, 35J70, 47J05}
\keywords{Nonlinear Neumann problem; m-completely accretive operator}

\begin{abstract}
 We prove existence and uniqueness, up to a constant, of an entropy solution
 to the nonlinear and non homogeneous Neumann problem
 \begin{gather*}
  -\mathop{\rm div}[ \mathbf{a}(.,\nabla u)] +\beta (u)=f 
  \quad\mbox{ in } \Omega \\
  \frac{\partial u}{\partial \nu _{\mathbf{a}}}+\gamma (\tau u)=g \quad
  \mbox{on } \partial \Omega\,.
 \end{gather*}
 Our approach is based essentially on the theory of m-accretive operators in
 Banach spaces, and in order preserving properties.
\end{abstract}

\maketitle

\numberwithin{equation}{section} 
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma} 
\newtheorem{Definition}[theorem]{Definition} 
\allowdisplaybreaks


\section{Introduction}

Let $\Omega $ be a connected open bounded set in $\mathbb{R}^{N}$, 
$N\geq 3$, with a connected Lipschitz boundary $\partial \Omega $. 
Let $(f,g)\in L^{1}(\Omega )\times L^{1}(\partial \Omega )$ 
satisfy the condition 
$\int_{\Omega }f(y)dy+\int_{\partial \Omega }g(y)d\sigma (y)=0$ which is
necessary and sufficient for solving classical Neumann problem in smooth
bounded domains \cite{F}. Let $\mathbf{a}(x,\xi )$ be an operator of
Leray-Lions type, in the sense that $(x,\xi )\mapsto \mathbf{a}(x,\xi )$ is
a Carath\'{e}odory function from $\Omega \times \mathbb{R}^{N}$ to 
$\mathbb{R}^{N}$, $\langle \mathbf{a}(x,\xi _{1})-\mathbf{a}(x,\xi _{2}),
\xi _{1}-\xi_{2}\rangle >0$, if $\xi _{1}\neq \xi _{2}$ 
and there exist some constants $p>1$, $C_{1}$, $C_{2}>0$ and a function 
$h_{0}\in L^{p^{\prime }}(\Omega )$,
$p^{\prime }=\frac{p}{p-1}$, such that $\langle \mathbf{a}(x,\xi ),\xi
\rangle \geq C_{1}|\xi |^{p}$ and $|\mathbf{a}(x,\xi )|\leq
C_{2}(h_{0}(x)+|\xi |^{p-1})$, for a.e. $x\in \Omega $ and all $\xi \in
\mathbb{R}^{N}$, (see \cite{LL}). We discuss existence and uniqueness of a
solution $u$ for the nonlinear and non homogeneous Neumann problem
\begin{equation}
\begin{gathered} -\mathop{\rm div}[ \mathbf{a}(.,\nabla u)] +\beta (u)=f
\quad \mbox{in }\Omega \\ \frac{\partial u}{\partial \nu
_{\mathbf{a}}}+\gamma (\tau u)=g \quad\mbox{ on } \partial \Omega ,
\end{gathered}  \label{1}
\end{equation}
The trace $\tau u$ on $\partial \Omega $ is taken in the sense of 
\cite{AMST}. The gradient $\nabla u$ is defined by mean of truncating, in the sense of
\cite{BBGGPV}, $\nabla u=DT_{k}u$ on every set $\{|u|\leq k\}$, $k>0$, where
$T_{k}(r)=\max \{-k,\min (k,r)\}$, $r\in \mathbb{R}$. The normal derivative 
$\frac{\partial u}{\partial \nu _{\mathbf{a}}}$ related to the operator 
$\mathbf{a}$ may be interpreted as the trace of the inner product in 
$\mathbb{R}^{N}$ $\langle \mathbf{a}(.,\nabla u),\nu \rangle $, where $\nu $ 
is the outward normal derivative vector field. More precisely 
$\langle \mathbf{a}(.,DT_{k}u),\nu \rangle $ represents a.e. on 
$\partial \Omega $ an element
of the dual space of $W^{1-\frac{1}{p},p}(\partial \Omega )\cap L^{\infty
}(\partial \Omega )$ (see \cite{CaF}), but this interpretation is not
essential to our approach, since it does not appear explicitly in the
definitions, given later, for weak solutions as well as for entropy
solutions.

For a sake of simplicity, $\beta ,\gamma $ are taken as continuous non
decreasing real functions everywhere defined on $\mathbb{R}$, with 
$\beta(0)=\gamma (0)=0$. We may extend our approach to the case where 
$\beta $, $\gamma $ are maximal monotone graphs in $\mathbb{R}^{2}$ with some
compatibility conditions on their domains, as given in \cite{S1}.

We prove existence and uniqueness up to a constant, of an entropy solution 
$u $ to the problem \eqref{1}, in the sense that $u:\Omega \to \mathbb{R}$ is
measurable, $DT_{k}u\in L^{p}(\Omega )$, for every $k>0$, $\beta (u)\in
L^{1}(\Omega )$, $\gamma (\tau u)\in L^{1}(\partial \Omega )$, and for every
$\varphi \in \mathcal{C}_{0}^{\infty }(\mathbb{R}^{N})$, $u$ satisfies
\begin{equation}
\int_{\Omega }\langle \mathbf{a}(.,\nabla u),DT_{k}(u-\varphi )\rangle \leq
\int_{\Omega }( f-\beta (u)) T_{k}(u-\varphi )+\int_{\partial \Omega }(
g-\gamma (\tau u)) T_{k}(\tau u-\varphi).  \label{2}
\end{equation}
We cannot expect better result for uniqueness, since in the particular case
where $\beta =\gamma =0$, if $u$ is a solution, then it is so for $u+c$,
where $c$ is an arbitrary real constant.

Later on, for uniqueness, we will take in \eqref{2} the test function 
$\varphi$ in a class larger than $\mathcal{C}_{0}^{\infty }(\mathbb{R}^{N})$.

To the best of our knowledge, the Non homogeneous case $g\neq 0$, with a
double nonlinearity $\beta (u)$ and $\gamma (\tau u)$, even in the
Quasilinear case where $\mathop{\rm div}[\mathbf{a}(x,\nabla u)]=\Delta u$,
is new. The homogeneous case $g=0$ has been discussed by many authors. See
e.g. \cite{B}, \cite{BrS}. For the nonlinear problem, with particular 
$\beta$ and $\gamma $, we refer the reader to \cite{AMST} for the case 
$\beta (u)=u$, and to \cite{P} for $\beta =0$ and 
$\gamma (\tau u)=\lambda \tau u$. In
all these approaches, the boundary condition is a part of the definition of
the operator's domain. This is no longer possible in our situation. For this
reason, to investigate the non homogeneous quasilinear Neumann problem in a
half-space, we used in \cite{S1} a matrix operator $A$ on a product space.
This had been extended in \cite{S2} to the problem,
\begin{equation}
\begin{gathered} -\mathop{\rm div}[ \mathbf{a}(.,\nabla u)] +\beta
(u)=f\quad \mbox{in } \mathbb{R}^{N}\setminus \partial \Omega \\ \big[
\frac{\partial u}{\partial \nu _{\mathbf{a}}}\big] +\gamma (\tau
u)=g\quad\mbox{on } \partial \Omega \\ [ u] =0 \quad \mbox{on } \partial
\Omega \,. \end{gathered}  \label{3}
\end{equation}
Where $\Omega $ is given as previously, 
$[\frac{\partial u}{\partial \nu _{\mathbf{a}}}] $ and $[u] $ are 
respectively the jump of the normal
derivative $\frac{\partial u}{\partial \nu _{\mathbf{a}}}$ and of the trace 
$\tau u$ across $\partial \Omega $.

In the present, $X_{1}=L^{1}(\Omega )\times L^{1}(\partial \Omega )$ and $A$
is an operator related to the problem
\begin{equation}
\begin{gathered} -\mathop{\rm div}[ \mathbf{a}(.,\nabla u)] =f\quad \text{in
}\Omega \\ \frac{\partial u}{\partial \nu _{\mathbf{a}}}=g\quad \text{on
}\partial \Omega , \end{gathered}  \label{4}
\end{equation}
in the sense that $A(u,\tau u)=(f,g)$, if $u$ is an entropy solution to %
\eqref{4}. $A_{1}$ is the restriction of $A$ to $X_{1}$.

Our approach is based essentially on the theory of m-accretive operators in
Banach spaces and the following order preserving properties:

If $F_{i}=(f_{i},g_{i})\in L^{1}(\Omega )\times L^{1}(\partial \Omega )$, 
$i=1,2$, satisfy the conditions $\int_{\Omega }f_{i}(y)dy+\int_{\partial
\Omega }g_{i}(y)d\sigma (y)=0$, $A(u_{i},\tau u_{i})=(f_{i},g_{i})$ and 
$\varphi =\mathop{\rm sign}_{0}(u_{1}-u_{2})$ and 
$\psi =\mathop{\rm sign}_{0}(\tau u_{1}-\tau u_{2})$, then
\begin{equation}
\int_{\Omega }(f_{1}-f_{2})\varphi +\int_{\Omega \cap \{ u_{1}=u_{2}\} }|
f_{1}-f_{2}| +\int_{\partial \Omega }(g_{1}-g_{2})\psi +\int_{\partial
\Omega \cap \{ \tau u_{1}=\tau u_{2}\} }| g_{1}-g_{2}| \geq 0  \label{5}
\end{equation}
If in addition, $(u_{i},\tau u_{i})\in X_{1}$, $i=1,2$ and $A_{1}(u_{i},\tau
u_{i})=(f_{i},g_{i})$, then for every $\varphi \in \mathop{\rm sign}%
(u_{1}-u_{2}) $ and every $\psi \in \mathop{\rm sign}(\tau u_{1}-\tau u_{2})$, 
we have
\begin{equation}
\int_{\Omega }(f_{1}-f_{2})\varphi +\int_{\partial \Omega }(g_{1}-g_{2})\psi
\geq 0\text{,}  \label{6}
\end{equation}
where
\begin{equation*}
\mathop{\rm sign}(r)=
\begin{cases}
r/| r|  \quad  \mbox{if } \quad r\neq 0 \\
[-1,1]  \quad \mbox{if } \quad r=0,
\end{cases}
\quad \mathop{\rm sign _{0}}(r)=
\begin{cases}
r/|r|  \quad \mbox{if } \quad r\neq 0 \\
0  \quad \mbox{if } \quad  r=0.
\end{cases}
\end{equation*}
Note that the main difficulty of the problem here as well as in \cite{S2} is
that the domain of the operator $A$ in not necessary included in $%
L^{1}+L^{\infty }$.

The inequality \eqref{5} is applied to the proof of uniqueness for the
nonlinear perturbation $( \beta ( u) ,\gamma ( \tau u) ) $, in the problem %
\eqref{1} which leads to the uniqueness of the solution $u$ up to a
constant, while \eqref{6} is applied to the proof of existence of a solution
to \eqref{1}, and mainly when $\beta $ and $\gamma $ are possibly,
mulivalued maximal monotone graphs in $\mathbb{R}^{2}$.

Following \cite{B} and \cite{BrS}, the inequalities \eqref{5} and \eqref{6}
may be interpreted as properties of maximum principle type or order
preserving properties in the sense of \cite{BC} related to an operator whose
domain is not necessary included in $L^{1}(\Omega )$.

For the sequel, we proceed as follows: In Section 2, we collect some
properties of functional spaces and traces. In Section 3, we prove that
operator $A$ is one-to-one (modulo constants) and $A_{1}$ is m-completely
accretive on $X_{1}$. Section 4 is devoted to establish order preserving
properties \eqref{5} and \eqref{6}. In Section 5, we discuss existence and
uniqueness for the entropy solution to \eqref{1}.

\section{Preliminaries and notations}

Let $\mathcal{M}(\Omega )$ be the space of classes of Borel measurable real
valued functions on $\Omega $, equipped with the topology of the convergence
in measure
\begin{equation*}
d(f,g)=\int_{\Omega }\frac{| f-g| (x)}{1+| f-g| (x)}dx .
\end{equation*}
For $r>0$, we consider the functional $\mathcal{N}_{r}$ and the
Marcinkiewicz $\text{space }M^{r}(\Omega )$,
\begin{equation*}
\mathcal{N}_{r}(u)=\big[ \underset{\lambda >0}{\sup }\lambda ^{r}| \{ | u|
>\lambda \} | \big] ^{1/r}, \quad\mbox{if $u\in \mathcal{M}$ and }
M^{r}(\Omega )=\{u\in \mathcal{M}: \mathcal{N}_{r}(u)<\infty \}
\end{equation*}
If $r>1$ and $\mathcal{B}$ is the Borel family of subsets of $\Omega $ or 
$\partial \Omega $, then $\mathcal{N}_{r}$ is equivalent to the norm,
\begin{equation*}
\| u\| _{M^{r}}=\sup_{K\in \mathcal{B},\;|K| >0} \frac{1}{| K| ^{\frac{1}{
r^{\prime}}}}\int_{K}| u(x)| d\mu (x),\quad \frac{1}{r}+\frac{1}{r^{\prime}}=1.
\end{equation*}
$(M^{r}(\Omega ),\| \text{ }\| _{M^{r}})$, (respect: $(M^{r}(\partial \Omega
)$)$,\| \text{ }\| _{M^{r}})$, is a Banach space and the inclusion 
$M^{r}\subset L^{q}$ holds for all $r,q$, $1\leq q<r$. (see \cite{BBC}).

We recall from \cite{S2} that, for an arbitrary $r>0$, $\mathcal{N}%
_{r}(u+v)\leq 2^{1/r}[ \mathcal{N}_{r}(u)+\mathcal{N}_{r}(v)]$, if $0<q<r$,
then $u\in M^{r}$ if and only if $|u| ^{q}\in M^{\frac{r}{q}}$ and $M^{r}$
is closed subspace of $\mathcal{M}$. In particular $M^{r}$ is complete for
the topology of convergence in measure.

Following \cite{BBGGPV}, the gradient by mean of truncating $\nabla u$ is a
measurable function
\begin{equation}
V:\Omega \to \mathbb{R}^{N}\text{ such that }V=DT_{k}u,\quad \text{a.e. on }%
\Omega _{k}=\{ | u| \leq k\} ,\; k>0.  \label{7}
\end{equation}
and the set $\mathcal{T}^{1,p}(\Omega )$ is given by
\begin{equation*}
\mathcal{T}^{1,p}(\Omega )=\{u\in \mathcal{M}(\Omega )\text{, such that }
DT_{k}u\in L^{p}(\Omega )\text{, for every }k>0\}.
\end{equation*}
Note that in view of the identity $\mathbf{1}_{\{ | u|<k\} }\nabla u=DT_{k}u$, 
the notation $\nabla u$ becomes superfluous on the set $\{ | u| <k\} $,
where $T_{k}u=u $. For this reason $\mathbf{1}_{\{ | u| <k\} }\nabla u$ will
be noted simply $\mathbf{1}_{\{ | u| <k\} }Du$.

We apply also the sets $\mathcal{T}_{\mathrm{tr}}^{1,p}(\Omega )$ introduced
in \cite[Theorem 3.1]{AMST} as being the subset of functions in $\mathcal{T}%
^{1,p}(\Omega )$ for which a generalized notion of trace may be defined.
More precisely $u\in \mathcal{T}_{\mathrm{tr}}^{1,p}(\Omega)$ if $u\in
\mathcal{T}^{1,p}(\Omega )$ and there exist a sequence $( u_{n}) _{n}$ in 
$W^{1,p}(\Omega )$ and a measurable function $v$ on $\partial \Omega $ such
that
\begin{equation}
\begin{gathered} u_{n}\to u \quad\mbox{a.e. in }\Omega , \\ DT_{k}(u_{n})\to
DT_{k}(u)\quad\mbox{in } L^{1}(\Omega ), \\ (\tau u_{n})_{n}\to
v\quad\mbox{a.e. on }\partial \Omega \,. \end{gathered}  \label{8}
\end{equation}
Therefore, we set $\widetilde{\tau }u=v$ the trace of $u$. The operator 
$\tilde{\tau}$ satisfies the following properties

\begin{itemize}
\item[(i)]  If $u\in W^{1,p}(\Omega )$, then $\tau T_{k}u=T_{k}\tau u$, for
every $k>0$ and $\tilde{\tau}u=\tau u$ a.e. on $\partial \Omega $.

\item[(ii)]  If $u\in \mathcal{T}_{\mathrm{tr}}^{1,p}(\Omega )$, then $\tau(
T_{k}u) =T_{k}( \tilde{\tau}u) $, for all $k>0$.

\item[(iii)]  $\widetilde{\tau }(u-\varphi )=\widetilde{\tau }u-\tau \varphi
$, if $\varphi \in W^{1,p}(\Omega )$ and $u\in \mathcal{T}_{\mathrm{tr}%
}^{1,p}(\Omega )$.
\end{itemize}

In the sequel, $\widetilde{\tau }u$ is noted simply $\tau u$.

\begin{lemma} \label{lem2.1}
Let be given $\delta >0$ and $p$ such that $1<p<N$. If 
$p_{_{1}}=\frac{N(p-1)}{N-p}$, $p_{2}=\frac{N(p-1)}{N-1}$ and 
$u\in \mathcal{T}_{\text{tr}}^{1,p}(\Omega )$ such that the trace 
$\tau u\in L^{1}(\partial \Omega )$
and $u$ satisfies
\begin{equation}
\frac{1}{k}\int_{\{ | u| <k\} }| Du| ^{p}dx\leq \delta \text{, for
every }k>0,  \label{9}
\end{equation}
then we have
\begin{itemize}
\item[(i)] $u\in M^{p_{1}}(\Omega )$ and there exists a constant 
$C_{3}=C_{3}(N,p,\Omega ,\delta )$ such that
\begin{equation}
| \{ | u| >k\} | \leq C_{3}k^{-p_{1}}\quad \text{for every }k>0,
\label{10}
\end{equation}
\item[(ii)] $\nabla u\in M^{p_{2}}(\Omega )$ and there exists a constant
$C_{4}=C_{4}(N,p,\Omega ,\delta )$ such that
\begin{equation}
| \{ | \nabla u| >k\} | \leq C_{4}k^{-p_{2}},\quad
\text{for every }k>0.  \label{11}
\end{equation}
\end{itemize}
\end{lemma}

\begin{proof}
(i) We denote by $\overline{v}=\frac{1}{| \partial \Omega
| }\int_{\partial \Omega }v$ the mean of any measurable function
$v$, when it exits and we select $k_{0}>2| \overline{u}| $. If
$k\geq k_{0}$, then,
\begin{align*}
| \{ | u| \geq k\} |
&=| \{ |T_{k}u| =k\} | \\
&\leq | \{ | T_{k}u| +\frac{k}{2}\geq k+| \overline{u}| \} |\\
&\leq \big|\big\{ | T_{k}u| +\frac{k}{2}\geq k+| \overline{T_{k}u}| \big\} \big| \\
&\leq \big| \big\{ | T_{k}u-\overline{T_{k}u}| \geq \frac{k}{2}\big\} \big| \\
&\leq \big( \frac{2}{k}\| T_{k}u-\overline{T_{k}u}\| _{p^{\ast }}\big)
^{p^{\ast }},
\end{align*}
where $p^{\ast }=\frac{Np}{N-p}$.

The last estimation follows from H\"{o}lder inequality. Indeed if
$\Omega_{k}'=\{ | T_{k}u-\overline{T_{k}u}| \geq \frac{k}{2}\} $, then
\[
\frac{k}{2}| \Omega _{k}'| \leq \int_{\Omega_{k}'}| T_{k}u-\overline{T_{k}u}| 
\leq \| T_{k}u-\overline{T_{k}u}\| _{p^{\ast }}| \Omega _{k}'|
^{1-\frac{1}{p^{\ast }}}
\]
Then applying \cite[page 191]{Zi}, there exists a constant $C=C(N,p,\Omega )$
such that
\[
| \{ | u| \geq k\} | \leq C( \| DT_{k}u\| _{p}) ^{p^{\ast }}(
\frac{k}{2}) ^{-p^{\ast
}}\leq 2^{p^{\ast }}C\delta ^{\frac{p\ast }{p}}k^{\frac{p^{\ast }}{p}%
-p^{\ast }},\quad\text{if }k\geq k_{0}.
\]
Hence, \eqref{10} follows if we select for example, 
$C_{3}=\max \{2^{p^{\ast }}C\delta ^{\frac{p\ast
}{p}},k_{0}^{p_{1}}| \Omega | \}$.

\noindent (ii) The same proof of \cite[lemma 4.2]{BBGGPV} apply here, taking
into account that\ the constant $C_{4}$ depends on $\Omega $.
\end{proof}

\section{Accretive operators and entropy solutions}

We define the Banach spaces, $X_{r}=L^{r}(\Omega )\times L^{r}(\partial
\Omega )$, $r\geq 1$, $X_{\infty }=L^{\infty }( \Omega ) \times L^{\infty
}(\partial \Omega )$ and the measure space $\mathcal{X}=(\Omega \cup
\partial \Omega $, $\mathcal{B}_{\Omega }\cup \mathcal{B}_{\partial \Omega }$, 
$dx\oplus d\sigma )$.

For $( U,V) \in X_{r}\times X_{r^{\prime}}$, $\frac{1}{r}+\frac{1}{r^{\prime}%
}=1$, $U=( u_{1},u_{2}) $, $V=( v_{1},v_{2}) $, we use the notation
\begin{equation*}
UV=( u_{1}v_{1},u_{2}v_{2}) \quad \text{and}\quad \int_{\mathcal{X}}UV
=\int_{\Omega }u_{1}v_{1}+\int_{\partial \Omega }u_{2}v_{2}
\end{equation*}
The spaces $X_{r}$, $r\geq 1$, and $X_{\infty }$ are equipped respectively
with the norms
\begin{equation*}
\| F\| _{r}=\Big[ \int_{\mathcal{X}}( | f| ^{r},| g| ^{r}) \Big] ^{1/r}=
\Big[ \int_{\Omega }| f(x)|^{r}dx+\int_{\partial \Omega }| g(x)| ^{r}d\sigma
(x)\Big]^{1/r},
\end{equation*}
for $F=(f,g)\in X_{r}$ and
\begin{equation*}
\| F\| _{\infty }=\mathop{\rm ess\,sup}_{x\in \Omega } | f(x)| 
+\mathop{\rm ess\,sup}_{x\in \partial \Omega } | g(x)|,
\end{equation*}
for $F=(f,g)\in X_{\infty }$. Let us recall the classical sets
\begin{gather*}
\mathcal{P}_{0}=\{p:\mathbb{R}\to \mathbb{R}, p\text{ Lipschitz, odd, non
decreasing and }p^{\prime}\text{ has a compact support} \}, \\
\mathcal{J}_{0}=\{j:\mathbb{R}\to \mathbb{R}, j\text{ is convex, lower
semi-continuous, with }\min j=j(0)=0\}.
\end{gather*}

\begin{Definition} \rm
If $A_{1}$ is a mapping from $D(A_{1})\subset $ $X_{1}$ to $X_{1}$, then
$A_{1}$ is said to be is \textbf{m-accretive in } $X_{1}$, if the resolvent
$J_{\lambda }^{A_{1}}=( I+\lambda A_{1}) ^{-1}$ satisfies,
\[
J_{\lambda }^{A_{1}}\text{ is a contraction everywhere defined in $X_{1}$,
 for every }\lambda >0.
\]
\end{Definition}

$X_{1}=L^{1}(\mathcal{X})$ is a normal Banach space in the sense of
\cite[page 53]{BC}. If $U_{i}\in D(A_{1})$, $F_{i}\in X_{1}$, are given such
that, $A_{1}U_{i}=F_{i}$, $i=1,2$ and $p\in \mathcal{P}_{0}$, then
\begin{equation*}
(A_{1}U_{1}-A_{1}U_{2})p(U_{1}-U_{2})\in L^{1}(\mathcal{X}).
\end{equation*}
Therefore, the condition
\begin{equation*}
\int_{\mathcal{X}}( (A_{1}U_{1}-A_{1}U_{2})p(U_{1}-U_{2})) ^{+}
\geq \int_{\mathcal{X}}( (A_{1}U_{1}-A_{1}U_{2})p(U_{1}-U_{2})) ^{-}
\end{equation*}
is equivalent to
\begin{equation*}
\int_{\mathcal{X}}(A_{1}U_{1}-A_{1}U_{2})p(U_{1}-U_{2})\geq 0\text{,}
\end{equation*}
This leads to the next definition \cite[proposition 2.2]{BC}.

\begin{Definition} \rm
$A_{1}$ is \textbf{m-completely accretive} in $X_{1}$, if $A_{1}$
is m-accretive and verifies one of the following equivalent conditions,
\begin{equation}
\int_{\mathcal{X}}j(J_{\lambda }^{A_{1}}U_{1}-J_{\lambda }^{A_{1}}U_{2})\leq
\int_{\mathcal{X}}j(U_{1}-U_{2}),\text{ for all }U_{1},U_{2}\in X_{1}\text{,
}\lambda >0\text{ and }j\in \mathcal{J}_{0}.  \label{12}
\end{equation}

\begin{equation}
\int_{\mathcal{X}}(A_{1}U_{1}-A_{1}U_{2})p(U_{1}-U_{2})\geq 0\text{, for all
}U_{1},U_{2}\in D(A_{1})\text{ and }p\in \mathcal{P}_{0}.  \label{13}
\end{equation}
\end{Definition}

As a consequence, if $A_{1}( u_{i},\tau u_{i}) =( f_{i},g_{i}) $, $i=1,2$,
then by selecting $p(r)=mT_{\frac{1}{m}}( r) $ in \eqref{13}, 
$r\in \mathbb{R}$, and let $m\to +\infty $, we obtain the next 
particular order preserving property for $A_{1}$,
\begin{equation}
\int_{\Omega }(f_{1}-f_{2})\mathop{\rm sign}{}_{0}(u_{1}-u_{2})
+\int_{\partial \Omega }(g_{1}-g_{2})\mathop{\rm sign}{}_{0}(\tau u_{1}
-\tau u_{2})\geq 0  \label{14}
\end{equation}
If $A_{1}$ is m-completely accretive in $X_{1}$, we know from
\cite[proposition 3.7]{BC}, (see also \cite{B}), that the Yosida
approximation $A_{1,\lambda }=\dfrac{I-J_{\lambda }^{A_{1}}}{\lambda }
=A_{1}J_{\lambda }^{A_{1}}$ satisfies, for every $U\in D(A_{1})$,
\begin{equation}
A_{1,\lambda }\text{ is m-completely accretive, Lipschitz with coefficient }
\frac{2}{\lambda }\text{ and }\lim_{\lambda \downarrow 0}
A_{1,\lambda }U=A_{1}U.  \label{15}
\end{equation}
The operator $\mathbf{a}$ of Leray-Lions type is defined as follows,

\begin{enumerate}
\item[(H1)]  $\mathbf{a}:\Omega \times \mathbb{R}^{N}\to \mathbb{R}^{N}$, 
$(x,\xi )\mapsto \mathbf{a}(x,\xi )$ is a Carath\'{e}odory function in the
sense that, $\mathbf{a}$ is continuous in $\xi $, for almost every $x\in
\Omega $ and measurable in $x$ for every $\xi \in \mathbb{R}^{N}$.

\item[(H2)]  There exist $p$, $1<p<N$, and $C_{1}>0$, so that,
\begin{equation*}
\langle \mathbf{a}(x,\xi ),\xi \rangle \geq C_{1}| \xi | ^{p}, \text{ for a.e }
x\in \mathbb{R}^{N}\text{ and every }\xi \in \mathbb{R}^{N}.
\end{equation*}

\item[(H3)]  $\langle \mathbf{a}(x,\xi _{1})-\mathbf{a}(x,\xi _{2}),\xi
_{1}-\xi _{2}\rangle >0$, if $\xi _{1}\neq \xi _{2}$, for a.e. $x\in \Omega $.

\item[(H4)]  There exists some $h_{0}\in L^{p^{\prime}}(\Omega )$, 
$p'=\frac{p}{p-1}$ and $C_{2}>0$, such that,
\begin{equation*}
| \mathbf{a}(x,\xi )| \leq C_{2}(h_{0}(x)+| \xi | ^{p-1}),\text{ for a.e }
x\in \Omega \text{ and every }\xi \in \mathbb{R}^{N}.
\end{equation*}
\end{enumerate}

\begin{Definition}
If ${u}$ is any measurable function on $\Omega $, then $u$ is a weak
solution to the problem \eqref{4}, if $u\in \mathcal{T}_{\rm tr}^{1,p}(\Omega )$,
$\mathbf{a}(.,\nabla u)\in L^{1}(\Omega )$ and
for every $v\in \mathcal{C}_{0}^{\infty }(\mathbb{R}^{N})$,
\[
\int_{\Omega }\langle \mathbf{a}(.,\nabla u),Dv\rangle 
=\int_{\mathbb{R}^{N}}fv+\int_{\partial \Omega }g.\tau v, 
\]
\end{Definition}

It is well known, from \cite{Se}, that uniqueness of weak solutions for
degenerate elliptic equations, fails to be always true, then following \cite
{BBGGPV}, (see \cite{M}, for example, for another type of solutions, the
renormalized solutions).

\begin{Definition} \rm
$u$ is said to be an entropy solution to \eqref{4}, if $u\in
\mathcal{T}_{\rm tr}^{1,p}(\Omega )$ and $u$ satisfies,
\begin{equation}
\int_{\Omega }\mathbf{a}(.,Du)DT_{k}(u-\varphi )\leq \int_{\Omega
}fT_{k}(u-\varphi )+\int_{\partial \Omega }gT_{k}(\tau u-\varphi )
\label{16}
\end{equation}
for every $\varphi \in \mathcal{T}_{\rm tr}^{1,p}(\Omega )\cap L^{\infty
}(\Omega )$.
\end{Definition}

We notice that if we set $K=k+\| \varphi \| _{\infty }$, then $\{| u-\varphi
| \leq k\}\subset \{| u| \leq K\}$, thus $\mathbf{1}_{\{| u-\varphi | \leq
k\}}.\nabla u=\mathbf{1}_{\{| u-\varphi | \leq k\}}.DT_{K}u=\mathbf{1}_{\{|
u-\varphi | \leq k\}}.Du$, since $T_{K}u=u$ on the set $\{| u-\varphi | \leq
k\}$.

We can prove easily as in \cite{BBGGPV} that if $u$ is an entropy solution
of \eqref{4}, then $u$ is a weak solution.

To discuss uniqueness, for the problem \eqref{4}, the test functions $%
\varphi $ must be taken in a class, larger than $\mathcal{C}_{0}^{\infty }(%
\overline{\Omega })$ and that contains $T_{k}u$. In \cite{BBGGPV}, the class
$\mathcal{T}_{\text{0}}^{1,p}(\Omega )\cap L^{\infty }(\Omega )$ is well
adapted to the problem with Dirichlet condition on $\partial \Omega $. In
\cite{S2} this extension is obtained directly from \cite{BBGGPV}, in the
class $\mathcal{T}^{1,p}(\mathbb{R}^{N})\cap \mathcal{L}_{0}(\mathbb{R}
^{N})\cap L^{\infty }(\mathbb{R}^{N})$, 
since we have the identity 
$\mathcal{T}_{0}^{1,p}(\mathbb{R}^{N})\cap \mathcal{L}_{0}(\mathbb{R}^{N})
=\mathcal{T}^{1,p}(\mathbb{R}^{N})\cap \mathcal{L}_{0}(\mathbb{R}^{N})$, 
where 
$\mathcal{L}_{0}(\mathbb{R}^{N})=\{u\in \mathcal{M}(\mathbb{R}^{N})\text{ s.t. }| \{ |
u| >k\} | <+\infty, \text{ for every }k>0\}$. In the present, we need the
next lemma.

\begin{lemma} \label{lem3.1}
(i) If $\varphi \in \mathcal{T}_{\rm tr}^{1,p}(\Omega )\cap
L^{\infty }(\Omega )$, then, there exists a sequence $(\varphi _{n})_{n}$ in
$\mathcal{C}_{0}^{\infty }(\overline{\Omega })$, $n\in \mathbb{N}$, such
that $T_{k}(u-\varphi _{n})$ converges a.e. on $\Omega $ to
$T_{k}(u-\varphi )$, $\tau T_{k}(u-\varphi _{n})$ converges a.e. on
$\partial \Omega $ to $\tau T_{k}(u-\varphi )$ and $DT_{k}(u-\varphi _{n})$
converges weakly in $( L^{p}(\Omega )) ^{N}$ to $DT_{k}(u-\varphi)$, for every
$k>0$.

\noindent(ii)In particular, $u\in
\mathcal{T}_{\rm tr}^{1,p}(\Omega )$ is an entropy solution to
\eqref{4}, if and only if $u$
satisfies \eqref{16}, for every $\varphi \in \mathcal{T}_{\rm tr}^{1,p}(\Omega )
\cap L^{\infty }(\Omega )$.
\end{lemma}

\begin{proof}
(i) Let $(\theta _{n})_{n}$ a regularizing sequence in $\mathbb{R}^{N}$,
$\theta _{n}\in \mathcal{C}_{0}^{\infty }(\mathbb{R}^{N})$
and $\phi _{n,m}=( \varphi .\mathbf{1}_{B(0,m)}) \ast \theta_{n}$,
$m,n\in \mathbb{N}$. By the diagonal process, there exists
a sequence $\varphi _{n}$
that converges a.e. on $\Omega $ to $\varphi $. $T_{k}(u-\varphi )$ and
$T_{k}(u-\varphi _{n})$ are in $W^{1,1}(\Omega )$, we assume that
$T_{k}(u-\varphi _{n})$ converges a.e. on $\Omega $ to $T_{k}(u-\varphi )$
and the same type of convergence for the trace on $\partial \Omega $.

For the weak convergence of the sequence $DT_{k}(u-\varphi _{n})$, it is
sufficient to prove that
\[
\int_{\Omega }\langle DT_{k}(u-\varphi _{n}),\psi \rangle
\to \int_{\Omega }\langle DT_{k}(u-\varphi ),\psi \rangle
\text{, for every }\psi \in [ \mathcal{C}_{0}^{\infty }(\overline{%
\Omega })] ^{N}.
\]
By the divergence theorem, we have,
\[
\int_{\Omega }\mathop{\rm div}[ T_{k}(u-\varphi _{n})\psi ]
=\int_{\partial \Omega }T_{k}(u-\varphi _{n})(x)\langle \psi (x),\nu
(x)\rangle d\sigma (x)
\]
Where $\nu (x)$ is the outward normal vector in $x\in \partial \Omega $.
Thus,
\begin{align*}
&\int_{\Omega }\langle DT_{k}(u-\varphi _{n}),\psi \rangle\\
&=-\int_{\Omega }[ T_{k}(u-\varphi _{n})\mathop{\rm div}\psi ]
+\int_{\partial \Omega }T_{k}(u-\varphi _{n})(x)\langle \psi (x),\nu
(x)\rangle d\sigma (x)
\end{align*}
The lemma is proved by applying dominated convergence in the last two
integrals and then again the divergence theorem in the opposite sense.
Part (ii) is an immediate consequence of part (i).
\end{proof}

For the sequel, the operators $A$ and $A_{1}$ are given as follows,
\begin{equation}
\begin{aligned} &\mbox{$(u,\tau u)\in D(A)$, if 
$u\in \mathcal{T}_{\rm tr}^{1,p}(\Omega )$,
$\tau u\in L^{1}(\partial \Omega )$ and there exists} \\ 
&\mbox{$(f,g)\in X_{1}$ such that, $u$ is an entropy solution  for \eqref{4}.} \\ 
&A_{1} \mbox{is the restriction of $A$ to } X_{1}. 
\end{aligned}\label{17}
\end{equation}

\begin{theorem} \label{thm3.1}
(i) $A_{1}$ is m-completely accretive in $X_{1}$.\\
(ii) $A$ is one-to-one.
\end{theorem}

\begin{proof}
(i). In view of (H3) the inequality \eqref{13} is satisfied.
Hence, $A_{1}$ is completely accretive in $X_{1}$.
Now, we prove that $I+A_{1}$ is onto from $X_{1}$ to $X_{1}$.

\noindent \textbf{Step 1:} Construction of an approximate sequence.
First, we consider the reflexive Banach space
\[
E=W^{1,p}(\Omega )\times L^{p}(\partial \Omega ), \quad
\| U\|_{E}=( \| u\| _{W^{1,p}(\Omega )}^{p}+\| v\| _{L^{p}(\partial
\Omega )}^{p}) ^{1/p}.
\]
and we define a subspace $X_{0}$ and an operator $A_{0}$ as follows,
$X_{0}=\{(u,v)\in E: v=\tau u\}$, and
$U=(u,\tau u)\in X_{0}$ is a solution to $A_{0}(u,\tau u)=(f,g)\in E'$
if,
\[
\int_{\Omega }\langle \mathbf{a}(.,Du),Dv\rangle =\int_{\Omega
}fv+\int_{\partial \Omega }g.\tau v,\quad \text{ for every }
V=(v,\tau v)\in X_{0}.
\]
Next, we consider, the convex functional
\[
\Phi _{n}(u,v)=\frac{1}{2}\Big[ \int_{\Omega
}u^{2}(x)dx+\int_{\partial \Omega }v^{2}(x)d\sigma (x)\Big]
+\frac{1}{np}\int_{\Omega }| u| ^{p}dx\text{; }U=(u,v)\in X_{0},
\]
The real mapping $t\mapsto \langle A_{0}(u+tv),w\rangle $ is
continuous, for all $u,v,w\in E$, then $A_{0}$ is monotone and
Hemi-continuous (see \cite{Br}, \cite{Li}), thus it is Pseudo-monotone. It
is also coercive in the sense that
\[
\underset{\| U\| _{E}\to +\infty ,U\in X_{0}}{\lim }%
\dfrac{\langle A_{0}U,U\rangle +\Phi _{n}(U)}{\| U\|
_{E}}=+\infty .
\]
Let $F=(f,g)$ be given in $X_{1}$ and
$F_{n}=(f_{n},g_{n})=(T_{n}f,T_{n}g)$. Then $F_{n}\in X_{1}\cap
X_{\infty }\subset E'$, $\| f_{n}\| _{1}\leq \| f\| _{1}$
and $\| g_{n}\| _{1}\leq \| g\| _{1}$, $f_{n}$ converges to $f$ in
$L^{1}(\Omega ) $, and $g_{n}$ converges to $g$ in $L^{1}(\partial
\Omega )$. By \cite[corollary 30]{Br}, there exists $U_{n}\in
X_{0}$ that satisfies, for all $V\in X_{0}$,
\[
\Phi _{n}(V)-\Phi _{n}(U_{n})\geq \langle
F_{n}-A_{0}U_{n},V-U_{n}\rangle _{E'\times E}
\]
Thus, $F_{n}-A_{0}U_{n}=\partial \Phi _{n}(U_{n})\in E'$, $\partial
\Phi _{n}$ is the subdifferential of $\Phi _{n}$, $\partial \Phi _{n}$ is
univalued here. In other words, $U_{n}=(u_{n},\tau u_{n})\in X_{0}$ and 
$U_{n}$ satisfies,
\begin{equation}
\int_{\Omega }u_{n}v+\int_{\partial \Omega }\tau u_{n}\tau
v+\int_{\Omega }\langle \mathbf{a}(.,Du_{n}),Dv\rangle
+\frac{1}{n}\int_{\Omega }| u_{n}| ^{p-2}u_{n}v=\int_{\Omega
}f_{n}.v+\int_{\partial \Omega }g_{n}\tau v,  \label{18}
\end{equation}
for every $V=(v,\tau v)\in X_{0}$.

\noindent \textbf{Step 2:} we claim that the sequence $( \frac{1}{n}| u_{n}|
^{p-1}) _{n}$converges to $0$ in $L^{1}(\Omega )$.
If we take $v=T_{k}( u_{n}) $ in \eqref{18}, then $v\in W^{1,p}(\Omega )$,
and we obtain,
\begin{equation}
\frac{C_{1}}{k}\int_{\{ | u_{n}| <k\} }| Du_{n}| ^{p}\leq \|
F_{n}\| _{1}\leq \| F\| _{1} \label{19}
\end{equation}
We deduce from \eqref{10}, that $\big(| u_{n}|^{p-1}\big) _{n}$ is uniformly
bounded in the Marcinkiewicz space $M^{\frac{N}{N-1}}(\Omega )$ and then in
$L^{1}(\Omega )$. After passing to a subsequence, we assume that
$\frac{1}{n}| u_{n}|^{p-1}$ converges in $L^{1}(\Omega )$ and a.e. on
$\Omega $ to $0$.

\noindent\textbf{Step 3:} Convergence in measure of the sequence $( u_{n})_{n}$.
We consider the decomposition,
\[
\{ | u_{n}-u_{m}| >t\} \subset \{ | u_{n}|>k\} \cup \{ | u_{m}|
>k\} \cup \{ | u_{n}| \leq k,|u_{m}| \leq k,| u_{n}-u_{m}| >t\}
\]
Since $( u_{n}) _{n}$ is uniformly bounded in the Marcinkiewicz
space $M^{p_{1}}$, then, for every $\varepsilon >0$, there exists
$k_{0}$ such that $| \{ | u_{n}|>k\} | <\varepsilon $ and
$| \{ |u_{m}| >k\} |<\varepsilon $, if $k>k_{0}$. Next, if we select
some $k>k_{0}$, since $(T_{k}u_{n})_{n}$, is bounded in
$W^{1,p}\mathbb{(}\Omega \mathbb{)}$, we assume then, up to a subsequence,
 that $(T_{k}u_{n})_{n}$ is a Cauchy sequence in $L^{1}(\Omega )$ and in
measure. Then we have $| \{ | u_{n}| \leq k,| u_{m}| \leq k,|
u_{n}-u_{m}| >t\} | <\varepsilon $, if $m$, $n$ are sufficiently
large.

Hence, up to a subsequence, $( u_{n}) _{n}$ converges in measure
and a.e.  to some $u$ and $u\in M^{p_{1}}(\Omega )$.

\noindent\textbf{Step 4:} Convergence of the sequence $( Du_{n}) _{n}$.
If $k,l,t,\varepsilon $ are positive real numbers, we have the inclusions,
\begin{align*}
\{ | Du_{n}-Du_{m}| >t\} \subset
&\{ | u_{n}-u_{m}|>k\} \cup \{ | Du_{n}|>l\}
\cup \{ | Du_{m}| >l\}  \\
&\cup \{ | Du_{n}| \leq l,| Du_{m}| \leq l,| u_{n}-u_{m}|
\leq k,|Du_{n}-Du_{m}|>t\} .
\end{align*}
We proceed, first, with the last term in the previous inclusion

Let  a compact $\mathbf{K}$ and a function $\mu $  be given as
follows,
\begin{gather*}
\mathbf{K}=\{ (\xi ,\zeta )\in \mathbb{R}^{N}\times \mathbb{R}^{N}:
| \xi | \leq l,| \zeta | \leq l,| \xi -\zeta | \geq t\},\\
\mu (x)=\min_ {(\xi ,\zeta )\in \mathbf{K}}
\langle \mathbf{a}(x,\xi )-\mathbf{a}(x,\zeta ),\xi -\zeta \rangle
\end{gather*}
We derive from (H1) and (H3), that $\mu $ is
defined for a.e. $x\in \Omega $ and is positive. Thus
$| \{ \mu=0\} | =0$, and there exists $\eta >0$, such that for every
measurable subset $S$ of $\Omega $, if $\int_{S}\mu <\eta $, then
$| S| <\varepsilon $. By applying this last statement to,
\[
S=\{ | Du_{n}| \leq l,| Du_{m}| \leq l,| u_{n}-u_{m}| \leq k,|
Du_{n}-Du_{m}|>t\} ,
\]
Since,
\[
\int_{S}\mu \leq \int_{S}\langle \mathbf{a}(x,Du_{n})-\mathbf{a}(x,Du_{m}),
Du_{n}-Du_{m}\rangle \leq k\| F\| _{1},
\]
then $|S| <\varepsilon $, if $k$ is small enough.

Next, if $k$ is fixed small enough, from the step 3, we have,
$| \{ | u_{n}-u_{m}| >k\} | <\varepsilon $, if $m,n$ are
sufficiently large.

According to \eqref{19} and \eqref{11}, $( Du_{n}) _{n}$ is
uniformly bounded in the Marcinkiewicz space $M^{p_{2}}$,
$p_{2}=\frac{N(p-1)}{N-1}$. Hence $| \{ | Du_{n}|>l\} | <\varepsilon $ and
$| \{ | Du_{m}|>l\} | <\varepsilon$, for $l$ sufficiently large.

Then, we may assume that,
$Du_{n}$  converges in measure and a.e.  on $\Omega$, if
$n\to +\infty$  to some $V$  and $| V| \in M^{p_{2}}(\mathbb{R}^{N})$.

We claim that $u\in \mathcal{T}^{1,p}(\Omega )$ and $\nabla u=V$.
For a fixed $k>0$, on one hand $T_{k}u_{n}$ is converging to
$T_{k}u$ by dominated convergence, and therefore $DT_{k}u_{n}$ is
converging to $DT_{k}u$ in $\mathcal{D}'(\mathbb{R}^{N})$, on the other hand,
$( DT_{k}u_{n}) _{n}$ is bounded in $L^{p}(\Omega )$, thus, $DT_{k}u_{n}$
is converges weakly to a $V_{k}$ in $L^{p}$, therefore also in
$\mathcal{D}'(\mathbb{R}^{N})$. By uniqueness,
$DT_{k}u=V_{k}\in L^{p}(\Omega )$ and $DT_{k}u_{n}$ converges weakly in
$L^{p}(\Omega )$ to $DT_{k}u$. Consequently, $u\in \mathcal{T}^{1,p}(\Omega )$.

Next, we prove that
\begin{equation}
DT_{k}u_{n}\text{ converges in measure and a.e. on $\Omega$  to
$\nabla u$, as $n\to +\infty$ and $k\to +\infty$.} \label{20}
\end{equation}
Since $T_{k+\alpha }\circ T_{k}=T_{k}$, for every $k>0$ and
$\alpha >0$, then, by the same arguments as for $( Du_{n}) _{n}$,
we obtain from \eqref{20} that $( DT_{k}u_{n}) _{n}$ converges
in measure to some $v_{k}$, then claim that $(DT_{k}u_{n}) _{n}$
converges weakly to $v_{k}$, since that leads to $v_{k}=DT_{k}u$.

Indeed, if $\varepsilon >0$, and $\varphi \in L^{p'}(\Omega )$,
then for every $k>0$, we can select two positive constants $c_{k}$ and
$\eta >0$ such that, for every $n\in \mathbb{N}$ and every measurable subset
$S\subset \Omega $, we have
\[
\| DT_{k}u_{n}\| _{p}\leq c_{k},\quad\text{and}\quad
\| \varphi\| _{L^{p'}(S)}\leq \frac{\varepsilon }{4c_{k}},\quad
\text{if }| S| \leq \eta
\]
By Fatou lemma, we have $\| v_{k}\| _{p}\leq c_{k}$.
Next, if we set,
\[
\lambda =\frac{\varepsilon }{2| \Omega | ^{\frac{1}{p}}\| \varphi
\| _{L^{p'}(\Omega )}}, \quad
S_{\lambda }=\{ | DT_{k}u_{n}-v_{k}| >\lambda \}
\]
and $n_{0}$ such that $| S_{\lambda }| \leq \eta$  for $n\geq n_{0}$,
then
\begin{align*}
| \int_{\Omega }( DT_{k}u_{n}-v_{k}) \varphi |
&\leq \int_{S_{\lambda }}| DT_{k}u_{n}-v_{k}| | \varphi | +\int_{\Omega
\backslash S_{\lambda }}| DT_{k}u_{n}-v_{k}| |\varphi | \\
&\leq 2c_{k}\| \varphi \| _{L^{p'}(S_{\lambda })}+\lambda
| \Omega | ^{\frac{1}{p}}\| \varphi \| _{L^{p'}(\Omega )}\leq \varepsilon \,.
\end{align*}
Thus, $DT_{k}u_{n}$ converges in measure and a.e to $DT_{k}u$ , as
$n\to +\infty $. Consequently, for every $k>0$, there exists some
$n_{k}\in \mathbb{N}$, such that, $d(DT_{k}u_{n_{k}},DT_{k}u)\leq \frac{1}{k}$,
 where $d$ is the metric on $\mathcal{M}$. On the other hand,
\begin{equation}
d(DT_{k}u,\nabla u)=\int_{\Omega }\frac{| DT_{k}u-\nabla u| }{1+| DT_{k}u-\nabla u| }
\leq | \{| u| >k\}| \to 0,\quad\text{as }k\to +\infty .
\label{21}
\end{equation}
Therefore, we assume the subsequence $( DT_{k}u_{n_{k}}) _{k}$
converges in measure and a.e. to $\nabla u$, as $k\to +\infty $.

But for a.e. $x\in \Omega $, if $k>| u(x)| $ and $k'>|u(x)| $, we have
\begin{align*}
&| DT_{k}u_{n}(x)-DT_{k'}u_{m}(x)| \\
&\leq |DT_{k}u_{n}(x)-Du(x)| +| Du(x)-DT_{k'}u_{m}(x)| \\
&= | DT_{k}u_{n}(x)-DT_{k}u(x)| +| DT_{k'}u(x)-DT_{k'}u_{m}(x)|
\leq \varepsilon\,
\end{align*}
if $m$ and $n$ are sufficiently large,

At last by the same argument as in \eqref{21}, we conclude
that, up to a subsequence $DT_{k}u_{n}$ converges in measure and a.e. to
$Du_{n}$, if $k\to +\infty $. Since $( Du_{n}) _{n}$
converges in measure and a.e.  to $\nabla u$, we conclude that
$DT_{k}u_{n}$ converges in measure and a.e. to $\nabla u$, as
$n,k\to +\infty $. This completes the proof of \eqref{20}.

Applying classical arguments for Carath\'{e}odory functions, we assume that
the sequence $( \mathbf{a}(.,Du_{n})) _{n}$ converges in measure to
$\mathbf{a}(.,Du)$.
>From (H4) and the fact that $| Du_{n}| ^{p-1}$ a.e. uniformly bounded in
the Marcinkiewicz space $M^{\frac{N}{N-1}}(\Omega )$, we deduce that
$( \mathbf{a}(.,Du_{n})) _{n}$ is equi-integrable on $\Omega $. Hence,
$\mathbf{a}(.,Du_{n})$ converges in $L^{1}(\Omega )$ to $\mathbf{a}(.,Du)$.

\noindent\textbf{Step 5:} Convergence of the trace.
We prove that $(\tau u_{n})_{n}$ converges to some
$w\in \mathcal{M}(\partial \Omega )$, that
$u\in \mathcal{T}_{\rm tr}^{1,p}(\Omega )$ and $w=\tau u$, $d\sigma$ a.e.

Since the trace operator is completely continuous from
$W^{1,p}(\Omega )$ to $L^{p}(\partial \Omega )$,  we assume
that $T_{k}\tau u_{n}=\tau T_{k}u_{n}\to \tau T_{k}u$,
a.e.  on $S_{k}=\{x\in \partial \Omega $; $| T_{k}u| <k\}$, for
every $k>0$. Thus $\tau u_{n}$
converges a.e. to $w$ on $\partial \Omega $, $w=\tau T_{k}u$, a.e.  on
$S_{k}$, for every $k>0$.

On the other hand, $DT_{k}u_{n}$ converges weakly in $L^{p}$ and in measure
to $DT_{k}u$, we deduce also that $DT_{k}u_{n}$ converges to $DT_{k}u$ in
$L^{1}(\Omega )$.

We summarize, $DT_{k}u_{n}$ $DT_{k}u$, we deduce that $L^{1}(\Omega ).$%
\begin{gather*}
\mbox{$(u_{n})_{n}$ converges in measure to some $u$},\\
\mbox{$DT_{k}u_{n}$ converges to $DT_{k}u$ in $L^{1}(\Omega )$}, \\
\mbox{$\tau u_{n}$ converges a.e. to $w$ on $\partial \Omega $.}
\end{gather*}
We conclude, as defined in \eqref{8}, that
$u\in \mathcal{T}_{\text{tr}}^{1,p}(\Omega )$ and $\tau u=w$.

\noindent\textbf{Step 6:} It remains to prove that $u$ is an entropy solution to
\begin{gather*}
u-\mathop{\rm div}[ \mathbf{a}(.,Du)] =f \quad\mbox{in $\Omega $} \\
\tau u+\frac{\partial u}{\partial \nu _{\mathbf{a}}}=g\quad\mbox{on }
\partial \Omega
\end{gather*}
If $\varphi \in \mathcal{C}_{0}^{\infty }(\overline{\Omega })$, and
$v=T_{k}(u_{n}-\varphi )$ in \eqref{18}, then we have
\begin{align*}
&\int_{\Omega }\langle \mathbf{a}(.,Du_{n}),DT_{k}(u_{n}-\varphi )\rangle\\
&=\int_{\Omega }( f_{n}-u_{n}-\frac{1}{n}|
u_{n}| ^{p-2}u_{n}) T_{k}(u_{n}-\varphi )
+\int_{\partial \Omega }( g_{n}-\tau u_{n}) \tau
T_{k}(u_{n}-\varphi ),
\end{align*}
$u_{n}\to u$ a.e. on $\Omega $ and $\tau u_{n}\to \tau u$  a.e. on
$\partial \Omega $.

For the left member, we notice first that $D( u-\varphi ) =0$,
a.e. on the set $\{ | u-\varphi | =k\} $. Then
$DT_{k}(u_{n}-\varphi )=D(u_{n}-\varphi )\mathbf{1}_{\{ |
u_{n}-\varphi | <k\} }$ a.e. , and
$\langle \mathbf{a}(.,Du_{n}),DT_{k}(u_{n}-\varphi )\rangle $ 
converges a.e on
$\Omega $, to
$\langle \mathbf{a}(.,Du),Du-D\varphi )\rangle \mathbf{1}_{\{ | u-\varphi | <k\} }
=\langle \mathbf{a}(.,Du),DT_{k}( u-\varphi ) )\rangle $.
Next
\[
\lim_n \int_{\Omega \cap \{ | u-\varphi |<k\} }\langle \mathbf{a}
(.,Du_{n}),D\varphi \rangle \mathbf{1}_{\{ | u_{n}-\varphi | <k\} }
=\int_{\Omega \cap \{ | u-\varphi | <k\} }\langle \mathbf{a}(.,Du),D
\varphi \rangle
\]
On the other hand, $\langle \mathbf{a}(.,Du_{n}),DT_{k}u_{n}\rangle \geq 0$, 
a.e.
and $\mathbf{a}(.,Du_{n})$ converges in $L^{1}(\Omega )$. Therefore,
\begin{align*}
&\int_{\Omega }\langle \mathbf{a}(.,Du),DT_{k}(u-\varphi )\rangle\\
&=\int_{\Omega }\liminf_{n} \langle \mathbf{a}(.,Du_{n}),DT_{k}(u_{n}-\varphi )
\rangle  \\
&=\int_{\Omega \cap \{ | u_{n}-\varphi | <k\} }
\liminf_{n} \langle \mathbf{a}(.,Du_{n}),DT_{k}u_{n}
\rangle -\int_{\Omega \cap \{ | u_{n}-\varphi | <k\}}
\lim_{n}\langle \mathbf{a}(.,Du_{n}),D\varphi \rangle  \\
&\leq \liminf_{n}\int_{\Omega \cap \{ |u_{n}-\varphi | <k\} }\langle
 \mathbf{a}(.,Du_{n}),DT_{k}u_{n}\rangle
 -\lim_{n}\int_{\Omega \cap \{ | u_{n}-\varphi | <k\} }\langle \mathbf{a}
(.,Du_{n}),D\varphi \rangle  \\
&=\liminf_{n} \int_{\Omega }\langle \mathbf{a}
(.,Du_{n}),DT_{k}(u_{n}-\varphi )\rangle  \\
&\leq \liminf_{n}\int_{\Omega }( f_{n}-u_{n}
-\frac{1}{n}| u_{n}| ^{p-2}u_{n}) T_{k}(u_{n}-\varphi )\\
&\quad +\liminf_{n}\int_{\partial \Omega }( g_{n}-\tau u_{n})
T_{k}(\tau u_{n}-\tau \varphi ).
\end{align*}
By the Lebesgue theorem, we have
\[
\lim_{n}\int_{\Omega }f_{n}T_{k}(u_{n}-\varphi )
+\lim_{n} \int_{\partial \Omega } g_{n}\tau T_{k}(u_{n}-\varphi)
=\int_{\Omega }f T_{k}(u-\varphi )+\int_{\partial \Omega }
g\tau T_{k}(u-\varphi ).
\]
Next we prove that
\[
\liminf_{n} \int_{\Omega }\big( -u_{n}-\frac{1}{n}|
u_{n}| ^{p-2}u_{n}\big) T_{k}(u_{n}-\varphi )\leq \int_{\Omega }( -u)
T_{k}(u-\varphi ).
\]
In view of the fact that $( \frac{1}{n}| u_{n}| ^{p-2}u_{n}) $
converges to $0$ in $L^{1}(\Omega )$, we have
\begin{align*}
&\liminf_{n} \int_{\Omega }-u_{n}T_{k}(u_{n}-\varphi)\\
&\leq \limsup_{n} \int_{\Omega }-u_{n}T_{k}(u_{n}-\varphi)\\
&\leq \limsup_{n} \int_{\Omega }-(u_{n}-\varphi)T_{k}(u_{n}
-\varphi )-\lim_{n} \int_{\Omega }\varphi T_{k}(u_{n}-\varphi )) \\
&\leq \int_{\Omega }\limsup_{n} \big[ -(u_{n}-\varphi
)T_{k}(u_{n}-\varphi )\big]-\int_{\Omega }\varphi T_{k}(u-\varphi)\\
&=\int_{\Omega }-uT_{k}(u-\varphi ).
\end{align*}
In the same way, we have,
\[
\liminf_{n} \int_{\partial \Omega }-\tau u_{n}\tau
T_{k}(u_{n}-\varphi )\leq \int_{\partial \Omega }
-\tau u\tau T_{k}(u-\varphi).
\]
This completes the proof of (i).

\noindent(ii). If $u$ is an entropy solution to \eqref{4} with
data $F=(f,g)\in X_{1}$, and $h,k>0$, then by taking
$T_{k+h}(u-T_{k}u)$ as test functions in \eqref{18}, and
applying (H2), we obtain
\[
C_{1}\int_{\{ h\leq | u| \leq k+h\} }| Du| ^{p}\leq k\int_{\{
h\leq | u| \leq k+h\} }| f| +k\int_{\{ h\leq | \tau u| \leq k+h\}
}| g| \leq k\| F\| _{1}.
\]
In particular \eqref{9} while taking $h=0$.

We deduce, then from \eqref{11} and the condition $\tau u\in
L^{1}(\partial \Omega )$ in \eqref{17} that,
\begin{equation}
\lim_{h\to +\infty } \int_{\{ h\leq | u| \leq k+h\} }| Du| ^{p}=0. \label{22}
\end{equation}
Next, if $u_{1},u_{2}\in \mathcal{T}_{\rm tr}^{1,p}(\Omega )$
are two entropy solutions to \eqref{4} with the same data
$(f,g)$, by taking the same decomposition as in \cite{BBGGPV}, for
a fixed $k$,
\begin{gather*}
S_{1}( h) =\{ | u_{1}-u_{2}| \leq k\} \cap [ \{ | u_{1}|
<h\} \cup \{ |u_{2}| <h\} ]  \\
S_{2}( h) =\{ | u_{1}-u_{2}| \leq k\} \cap [ \{ | u_{1}|
\geq h\} \cup \{ | u_{2}| <h\} ]  \\
S_{2}'( h) =\{ | u_{1}-u_{2}| \leq k\} \cap [ \{ |
u_{2}| \geq h\} \cup \{ | u_{1}| <h\} ],
\end{gather*}
and selecting $\varphi =T_{h}u_{2}$ as test function in the equation related
to $u_{1}$, we have
\begin{align*}
&\int_{\{ | u_{1}-T_{h}u_{2}| \leq k\} \cap \{
| u_{2}| <h\} }\langle \mathbf{a}
(.,Du_{1}),Du_{1}-Du_{2}\rangle \\
&+\int_{\{ |u_{1}-T_{h}u_{2}| \leq k\} \cap \{ | u_{2}| \geq
h\} }\langle \mathbf{a}(.,Du_{1}),Du_{1}\rangle  \\
&\leq \int_{\Omega }fT_{k}(u_{1}-T_{h}u_{2})+\int_{\partial \Omega
}gT_{k}(\tau u_{1}-\tau T_{h}u_{2})
\end{align*}
Then, taking into account that
\begin{gather*}
\int_{\Omega }\langle \mathbf{a}(.,Du_{1}),Du_{1}\rangle
\mathbf{1}_{\{ | u_{1}-T_{h}u_{2}| \leq k\} }\mathbf{1}_{\{ | u_{2}| \geq h\} }
\geq 0,\\
\int_{S_{2}}\langle \mathbf{a}(.,Du_{1}),-Du_{2}\rangle \leq
\int_{S_{2}}\langle \mathbf{a}(.,Du_{1}),Du_{1}-Du_{2}\rangle,
\end{gather*}
we have
\begin{align*}
&\int_{S_{2}}\langle \mathbf{a}(.,Du_{1}),Du_{2}\rangle
+\int_{S_{1}}\langle \mathbf{a}(.,Du_{1}),Du_{1}-Du_{2}\rangle\\
&\leq \int_{\Omega }fT_{k}(u_{1}-T_{h}u_{2})+\int_{\partial \Omega
}gT_{k}(\tau u_{1}-\tau T_{h}u_{2})
\end{align*}
On the other hand, if $S_{3}=\{ h-k\leq | u_{2}| <h\} $ and
$S_{4}=\{ h\leq | u_{1}| \leq h+k\} $, then
\[
\big| \int_{S_{2}}\langle
\mathbf{a}(.,Du_{1}),-Du_{2}\rangle \big|
\leq C_{3}\| Du_{2}\|_{L^{p}(S_{3})}
\Big( \| h_{0}\| _{L^{p'}( S_{4}) }+\| |
Du_{1}| ^{p-1}\| _{L^{p'}( S_{4}) }\Big)
\]
With the help of \eqref{10} and \eqref{11} we conclude that
\begin{equation}
\lim_{h\to +\infty }\int_{S_{2}(h)}\langle \mathbf{a}
(.,Du_{1}),-Du_{2}\rangle =0.  \label{29}
\end{equation}
Next, we do the same for the equation related to $u_{2}$, with test function
$\varphi =T_{h}u_{1}$ an add the two inequalities:
\begin{align*}
&\liminf_{h\to +\infty } \int_{\Omega}\langle \mathbf{a}(.,Du_{1})
-\mathbf{a}(.,Du_{2}),Du_{1}-Du_{2}\rangle \mathbf{1}_{S_{1}( h) }\\
&+\lim_{h\to +\infty } \int_{_{S_{2}( h) }}\langle \mathbf{a}
(.,Du_{1}),-Du_{2}\rangle
+\lim_{h\to +\infty } \int_{S_{2}'( h)}\langle \mathbf{a}(.,Du_{2}),-Du_{1}\rangle\\
&\leq \lim_{h\to +\infty } \int_{\Omega }f[
T_{k}(u_{1}-T_{h}u_{2})+T_{k}(u_{2}-T_{h}u_{1})]  \\
&\quad +\lim_{h\to +\infty } \int_{\partial \Omega }g
[T_{k}(\tau u_{1}-\tau T_{h}u_{2})+T_{k}(\tau u_{2}-\tau T_{h}u_{1})].
\end{align*}
Then, by applying the Lebesgue dominated convergence on the right,
and Fatou lemma on the left, taking into account \eqref{29},
we obtain,
\[
\int_{\{ | u_{1}-u_{2}| <k\} }\langle \mathbf{a}%
(.,Du_{1})-\mathbf{a}(.,Du_{2}),Du_{1}-Du_{2}\rangle =0\text{, }k>0\,.
\]
It arises from (H3), that $Du_{1}=Du_{2}$, a.e. in $\Omega $.
\end{proof}

\section{An order preserving property}

\begin{theorem} \label{thm4.1}
(i) If $u_{1},u_{2}\in \mathcal{T}_{\rm tr}^{1,p}(\Omega )$ are entropy
solutions for
\begin{equation}
\begin{gathered}
-\mathop{\rm div} [ \mathbf{a}(.,Du_{i})] =f_{i}, \quad\mbox{in }\Omega  \\
\frac{\partial u_{i}}{\partial \nu _{a}}=g_{i}\quad\mbox{on } \partial \Omega,
\end{gathered} \label{23}
\end{equation}
$i=1,2$, and $\varphi =\mathop{\rm sign}_{0}(u_{1}-u_{2})$,
$\psi =\mathop{\rm sign}_{0}(\tau u_{1}-\tau u_{2})$,
then we have the following order preserving property:
\begin{equation}
\int_{\Omega \cap \{ u_{1}-u_{2}\} }| f_{1}-f_{2}| +\int_{\partial
\Omega \cap \{ \tau u_{1}-\tau u_{2}\} }| g_{1}-g_{2}|
+\int_{\Omega }(f_{1}-f_{2})\varphi +\int_{\partial \Omega
}(g_{1}-g_{2})\psi \geq 0  \label{24}
\end{equation}
(ii) If furthermore, $U_{i}=(u_{i},\tau u_{i})\in Dom(A_{1})$,
then for every $\varphi \in \mathop{\rm sign}(u_{1}-u_{2})$ and
$\psi \in \mathop{\rm sign}(\tau u_{1}-\tau u_{2})$, we have
\begin{equation}
\int_{\Omega }(f_{1}-f_{2})\varphi +\int_{\partial \Omega }(g_{1}-g_{2})\psi
\geq 0\,.  \label{25}
\end{equation}
\end{theorem}

\begin{proof}
(i) If $U_{i}=( u_{i},\tau u_{i}) \in D(A)$, is an
entropy solution for the problem \eqref{23} with data
$F_{i}=(f_{i},g_{i})\in X_{1}$, $i=1,2$, then from Theorem \ref{thm3.1}, 
there exist
$V_{i,n}=(v_{i,n},\tau v_{i,n})\in X_{1}$ such that $V_{i,n}$ is an entropy
solution for,
\begin{gather*}
\frac{1}{n}v_{n,i}-\mathop{\rm div} [ \mathbf{a}(.,Dv_{n,i})] =f_{i}
\quad\mbox{in } \Omega  \\
\frac{1}{n}\tau v_{n,i}+\frac{\partial v_{n,i}}{\partial \nu _{\mathbf{a}}}
=g_{i}\quad\mbox{on } \partial \Omega\,,\quad {n\in \mathbb{N}}.
\end{gather*}
 By taking $\varphi =0$ in the entropy condition and
applying (H2), we have
\[
\frac{C_{1}}{k}\int_{\{ | u_{n,i}| <k\} }| Dv_{n,i}| ^{p}\leq \big\|
F_{n,i}-\frac{1}{n}V_{n,i}\big\| _{1}\leq 2\| F_{i}\| _{1}
\]
Then applying the same proof as in the previous section, we assume then that
$( v_{n,i}) _{n}$ converges in measure and a.e.  to some
$w_{i}\in M^{p_{1}}(\Omega )$, $\tau v_{n,i}$ converges $d\sigma$ a.e. to
$\tau w_{i}$. Thus $( \frac{1}{n}v_{n,i}) _{n}$ and
$( \frac{1}{n}\tau v_{n,i}) _{n}$ converge a.e.  to $0$ and
$\mathbf{a}(.,Dv_{n,i})$ converges in $L^{1}(\Omega )$ to $\mathbf{a}(.,Dw_{i})$,
where $w_{i}$ is an entropy solution to the problem
\begin{gather*}
-\mathop{\rm div}[ \mathbf{a}(.,Dw_{i})] =f_{i}\quad\mbox{in }\Omega  \\
\frac{\partial w_{i}}{\partial \nu _{\mathbf{a}}}=g_{i}\quad\mbox{on }
\partial \Omega
\end{gather*}
Applying again Theorem \ref{thm3.1}, we have $Dw_{i}=Du_{i}$ a.e. Hence, there
exist some constants $c_{1}$, $c_{2}\in \mathbb{R}$, such that
 $w_{i}=u_{i}+c_{i}$. Consider, then the sequences
\begin{gather*}
u_{n,i}=v_{n,i}-c_{i},\quad
f_{n,i}=f_{i}-\frac{1}{n}u_{n,i}-\frac{1}{n}c_{i},\\
g_{n,i}=g_{i}-\frac{1}{n}\tau u_{n,i}-\frac{1}{n}c_{i}, \quad
\varphi _{n}=\mathop{\rm sign}{}_{0}(u_{n,1}-u_{n,2}),\\
\psi _{n}=\mathop{\rm sign}{}_{0}(\tau u_{n,1}-\tau u_{n,2}), \quad
i=1,2,\; n\in \mathbb{N}\,.
\end{gather*}
Then $u_{n,i}$ is an entropy solution to
\begin{gather*}
-\mathop{\rm div}[ \mathbf{a}(.,Du_{n,i})] =f_{n,i}\quad\mbox{in }\Omega  \\
\frac{\partial u_{n,i}}{\partial \nu _{\mathbf{a}}}=g_{n,i}\quad\mbox{on }
\partial \Omega, \quad
n\in \mathbb{N}.
\end{gather*}
Since $( u_{n,i},\tau u_{n,i}) \in X_{1}$,  from  \eqref{14}, we have
\[
\int_{\Omega }(f_{n,1}-f_{n,2})\varphi _{n}+\int_{\partial \Omega}(g_{n,1}-g_{n,2})
\psi _{n}\geq 0.
\]
After suppressing a negative part on the left, this leads to,
\[
\int_{\Omega }(f_{1}-f_{2})\varphi _{n}+\int_{\partial \Omega
}(g_{1}-g_{2})\psi _{n}-\frac{1}{n}(c_{1}-c_{2})\big[ \int_{\Omega }\varphi
_{n}+\int_{\partial \Omega }\psi _{n}\big] \geq 0.
\]
In particular,
\begin{equation}
\begin{aligned}
&\int_{\{ u_{1}=u_{2}\} }| f_{1}-f_{2}|
+\int_{\{\tau u_{1}=\tau u_{2}\} }| g_{1}-g_{2}|\\
&+\lim_{n\to +\infty } \int_{\{ u_{1}\neq u_{_{2}}\}}(f_{1}-f_{2})\varphi _{n}
+\lim_{n\to +\infty }\int_{\{ \tau u_{1}\neq \tau
u_{2}\} }(g_{1}-g_{2})\psi _{n}\geq 0
\end{aligned} \label{26}
\end{equation}
Since $( u_{n,i}) _{n}$ converges in measure and a.e.  to $u_{i}$
and $\tau u_{n,i}$ converges $d\sigma$ -a.e. to $\tau u_{i}$, then
we have
\begin{gather*}
\lim_{n\to +\infty } \varphi _{n}=\mathop{\rm sign}{}_{0}
(u_{1}-u_{2}) ,\quad \mbox{a.e. on the set }\{ u_{1}-u_{2}\neq 0\},\\
\lim_{n\to +\infty }\psi _{n}=\mathop{\rm sign}{}_{0}( \tau
u_{1}-\tau u_{2}), \quad\text{a.e. on the set}\{ \tau
u_{1}-\tau u_{2}\neq 0\} \,.
\end{gather*}
Then passing to the limit $n\to +\infty $ in \eqref{26}, we obtain \eqref{24}.

\noindent(ii) This is exactly the same as in \cite[theorem 4.1.(ii)]{S2},
while changing the integrals on $\mathbb{R}^{N}$ by integrals on $\Omega $.
\end{proof}

\section{Existence and uniqueness}

\begin{theorem} \label{thm5.1}
If $\beta ,\gamma $ are non decreasing continuous functions on $\mathbb{R}$
 such that $\beta (0)=\gamma (0)=0$ and $f\in L^{1}(\Omega )$,
 $g\in L^{1}(\partial \Omega )$, then there exists an entropy solution
 $u\in T_{\rm tr}^{1,p}(\Omega )$ to the problem
\begin{equation}
\begin{gathered}
-\mathop{\rm div}[ \mathbf{a}(.,Du)] +\beta (u)=f\quad\mbox{in }\Omega  \\
\frac{\partial u}{\partial \nu _{\mathbf{a}}}+\gamma (\tau u)=g\quad\mbox{on }
\partial \Omega
\end{gathered} \label{27}
\end{equation}
with, $(\beta (u),\gamma (\tau u))\in X_{1}$ and
$\| (\beta(u),\gamma (\tau u))\| _{1}\leq \| (f,g)\| _{1}$ and $u$ is
unique, up to an additive constant.
Furthermore, if $\beta $ or $\gamma $ is one-to-one, then the entropy
solution is unique.
\end{theorem}

\begin{proof}
Existence: Let $E$, and $X_{0}$, be the same spaces, and
$A_{0}$ the same operator on $X_{0}$ as in the proof of the
Theorem \ref{thm3.1}. Then we define the sequence $( \Phi _{n})_{n}$
of convex and lower semi-continuous functions in $X_{0}$, as follows:
\[
j_{\beta }(r)=\int_{0}^{r}\beta (s)ds, \quad
j_{\gamma }(r)=\int_{0}^{r}\gamma (s)ds\,
\]
 and for $U=(u,v)\in X_{0}$,
\[
\Phi _{n}(u,v)=\begin{cases}
\frac{1}{2}\big[ \int_{\Omega }j_{\beta }(u)+\int_{\partial
\Omega }j_{\gamma }(\tau u)\big] +\frac{1}{np}\int_{\Omega }| u|
^{p}dx ,\\
\qquad \mbox{if }j_{\beta }(u)\in L^{1}(\Omega )\mbox{ and }
j_{\gamma}(\tau u)\in L^{1}(\partial \Omega ) \\
+\infty \quad \mbox{otherwise.}
\end{cases}
\]
Let $F_{n}=(f_{n},g_{n})=(T_{n}f,T_{n}g)\in E'\cap X_{1}$. Applying
again, \cite[Corollary 30]{Br}, there exits $U_{n}=(u_{n},\tau u_{n})\in
X_{0}$, a solution for
\begin{equation}
\begin{aligned}
&\int_{\Omega }\langle a(.,Du_{n}),Dv\rangle
+\int_{\Omega }\beta (u_{n})v+\int_{\partial \Omega }\gamma (\tau u_{n}).\tau v\\
&+\frac{1}{n}\int_{\Omega }| u_{n}| ^{p-2}u_{n}.v
 +\frac{1}{n}\int_{\Omega }| u_{n}| ^{p-2}u_{n}.v\\
&=\int_{\Omega}f_{n}v+\int_{\partial \Omega }g_{n}v,\quad
\mbox{for all }V=(v,\tau v)\in X_{0}.
\end{aligned} \label{28}
\end{equation}
If $\tilde{F}_{n}=(f_{n}-\beta (u_{n})-\frac{1}{n}| u_{n}|^{p-2}u_{n},g_{n}
-\gamma (\tau u_{n}))$, then $\| \tilde{F}_{n}\|_{1}\leq 3\| F\| _{1}$.
Thus we obtain, as previously,
\[
C_{1}\int_{\{ h\leq | u| \leq k+h\} }| Du_{n}| ^{p}\leq 3k\| F\|_{1}.
\]
We assume that $(u_{n})_{n}$ converges in measure to some $u$, that
$\frac{1}{n}| u_{n}| ^{p-2}u_{n}$ converges to $0$ in $L^{1}(\Omega )$.
Then applying \eqref{24}, we have
\begin{align*}
&\int_{\Omega }| \beta (u_{n})-\beta (u_{m})| +\int_{\partial
\Omega }| \gamma (\tau u_{n})-\gamma (\tau u_{n})| \\
&\leq \frac{1}{n}\int_{\Omega }| u_{n}| ^{p-1}+\frac{1}{m}\int_{\Omega }|
u_{m}| ^{p-1}+\int_{\Omega }| f_{n}-f_{m}| +\int_{\partial \Omega }|
g_{n}-g_{m}|
\end{align*}
Hence, $(\beta (u_{n}),\gamma (\tau u_{n}))_{n}$ is a Cauchy sequence in
$X_{1}$.

The rest of the proof of existence and uniqueness up to a constant
of a solution for \eqref{1} and the entropy condition is the
same as for Theorem \ref{thm3.1}, and finally, by Fatou lemma, we have,
$\|(\beta (u),\gamma (\tau u))\| _{1}\leq \| (f,g)\| _{1}$.

\noindent Uniqueness: Applying again \eqref{24} we have
uniqueness for the nonlinear perturbation
$(\beta (u),\gamma (\tau u))$. Thus we have uniqueness up to a constant
for the solution $u$.
If $u_{1}$, $u_{2}$ are two entropy solutions and $u_{2}=u_{1}+c$, then,
$\tau u_{2}=\tau u_{1}+c$. Thus $c=0$, if $\beta $ or $\gamma $ is
one-to-one.
\end{proof}

\subsection*{Acknowledgement}
The author wants to thank Prof. C. E. Kenig, Prof. A. Boukhricha, and Prof.
W. Hansen for their assistance.

\begin{thebibliography}{99}
\bibitem{AMST}  F. Andreu, J. M. Maz\'{o}n, S. Sigura de Le\'{o}n, J.
Toledo; \textit{Quasi-linear elliptic and parabolic equations in $L^{1}$
with non-linear boundary conditions}, Adv. Math. Sci. Appl. \textbf{7}
(1997), 183-213. MR88f35079.

\bibitem{B}  P. B\'{e}nilan; \textit{Equations d'\'{e}volution dans un
espace de Banach quelconque et applications.} Th\`{e}se, Univ. Orsay. 1972.

\bibitem{BBGGPV}  P. B\'{e}nilan, L. Boccardo, T. Gallou\"{e}t, R. Gariepy,
M. Pierre, J. L. Vazquez; \textit{An }$L^{1}-$\textit{theory of existence
and uniqueness of solutions of nonlinear elliptic equations}, Ann. Scuola
Norm.Sup. Pisa Cl.Sci. (4) \textbf{22 }(1995), no. 2, 241-273.

\bibitem{BBC}  P. B\'{e}nilan, H. Br\'{e}zis, M. G. Crandall; \textit{A
semilinear equation in }$L^{1}$, Ann. scuola Norm. Sup. Pisa. Cl. Sci.
2(1975), 523-555.

\bibitem{BC}  P. B\'{e}nilan, M. G. Crandall; \textit{Completely accretive
operators, in Semigroup Theory and Evolution Equations} (Ph Clement et al.,
eds.), Marcel Dekker, 1991, pp. 41-76.

\bibitem{BG}  L. Boccardo, T. Gallou\"{e}t; \textit{Nonlinear elliptic
equations with right-hand side measures. Comm. Partial Differential Equations%
}, \textbf{17} (1992), 641-655.

\bibitem{Br}  H. Br\'{e}zis; \textit{Equations et inequations non
lin\'{e}aires dans les espaces vectoriels en dualit\'{e}}, Ann. Inst.
Fourier \textbf{18 }(1968), 115-175.

\bibitem{BrS}  H. Br\'{e}zis, W.Strauss; \textit{Semi-linear second order
elliptic equation in $L^{1}$}, J. Math. Soc. Japan, \textbf{25} (1973),
565-590.

\bibitem{CaF}  E. Casas, L. A. Fernandez; \textit{A Green Formula for
Quasilinear Elliptic Operators,} Journal of Mathematical Analysis an
Applications \textbf{142}, 62-73 (1989).

\bibitem{F}  G. B. Folland; \textit{Introduction to Partial Differential
Equation}, Priceton University Press, second edition, 1995.

\bibitem{Li}  J-L-Lions, \textit{Quelques m\'{e}thodes de r\'{e}solution des
probl\`{e}mes aux limites non lin\'{e}aires}, Dunod et Gautier-Villars,1969.

\bibitem{LL}  J. Leray, J. L. Lions; \textit{Quelques r\'{e}sultats de Vi\u{s%
}ik sur les probl\`{e}mes elliptiques non lin\'{e}aires par les m\'{e}thodes
de Minty-Browder, }Bull. Soc. Math. France \textbf{93}(1965), 97-107.

\bibitem{M}  F. Murat; \textit{Proceeding of the International conferences
on Nonlinear Analysis}, Besan\c{c}on, june 1994.

\bibitem{N}  J. Ne\v{c}as; \textit{Les m\'{e}thodes directes en Th\'{e}orie
des equations Elliptiques}, Masson etCie, Paris, 1967. MR37:3168.

\bibitem{P}  A. Prignet; \textit{probl\`{e}mes elliptiques et paraboliques
dans un cadre non variationnel}, Th\`{e}se 1996.

\bibitem{Se}  J. Serrin; \textit{Pathological solutions of elliptic
differential equations}, Ann. Scuola Norm. Pisa. Cl. Sci. (1964), 385-387.

\bibitem{S1}  A. Siai; \textit{On a Quasilinear Elliptic Partial
Differential Equation of Thomas-Fermi Type}, Bollettino U. M. I. (6) 
\textbf{4}B (1985), 685-707.

\bibitem{S2}  A. Siai; \textit{A Fully Nonlinear Non homogeneous Neumann
Problem}, (to appear in Potential analysis).

\bibitem{V}  J. L. Vazquez; \textit{Entropy solutions and the uniqueness
problem for nonlinear second-order elliptic equations}, Nonlinear partial
differential equations (A.Ben Kirane, J.P. Gossez, eds), vol. 343,
Addison-Wesley Longman, 1996, 179-203.

\bibitem{Zi}  W. P. Ziemer; \textit{Weakly differential functions, }
Graduate texts in Mathematics, vol. 120, Springer-verlag, 1989.
\end{thebibliography}

\end{document}