\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
Seventh Mississippi State - UAB Conference on Differential Equations and
Computational Simulations,
{\em Electronic Journal of Differential Equations},
Conf. 17 (2009),  pp. 255--265.\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} \setcounter{page}{255}
\title[\hfilneg EJDE-2009/Conf/17 \hfil Existence of solutions]
{Existence of solutions for thermoelastic semiconductor equations}

\author[X. Wu\hfil EJDE/Conf/17 \hfilneg]
{Xiaoqin Wu}

\address{Xiaoqin Wu \newline
 Department of Mathematics, Computer and Information Sciences\\
Mississippi Valley State University\\
Itta Bena, MS 38941, USA}
\email{xpaul\_wu@yahoo.com}

\thanks{Published April 15, 2009.}
\subjclass[2000]{35M10, 35Q99}
\keywords{Thermoelastic semiconductor equations; existence}

\begin{abstract}
 We study a  model for the semiconductor problem that consists
 of a system of dynamic thermoelasticity equations of displacement
 and semiconductor equations. This problem arises from the
 observation that semiconductor devices are too often cracked and
 broken because of the thermal stresses. Since the heat source
 generated by Joule heating is quadratic in the gradient of the
 electrical potential, this causes some problem even in analysis.
 We establish the existence theorem of a weak solution. The proof
 is based on time retarding.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{definition}{Definition}[section]
\newtheorem{corollary}[theorem]{Corollary}
\newtheorem{lemma}{Lemma}[section]

\section{Introduction}

Semiconductors are electrical devices which are extensively used in
industrial world and in our daily life. The so-called
``Semiconductor Problem'' is a system of a stationary charge
conservation equation of electrical current and two parabolic equations of
electrons and holes. That is,
\begin{equation} \label{e1.1}
\begin{gathered}
-\mathop{\rm div}(\sigma\nabla\varphi)=p-n+f\\
n_t-\mathop{\rm div}(d_n \nabla n-\mu_n \sigma n\nabla\varphi)=g(n,p)(1-np)\\
p_t-\mathop{\rm div}(d_p\nabla p+ \mu_p \sigma
p\nabla\varphi)=g(n,p)(1-np)
\end{gathered}
\end{equation}
 where $\varphi$ represents the electrostatic potential, $n$
and $p$ the densities of  electrons and holes, $\sigma$ the
electrical conductivity, $d_n$ and $d_p$ the diffusion
coefficients, $\mu_n$ and $\mu_p$ the mobilities of electrons and
holes, respectively, $f$ the net impurity, $g(n,p)(1-np)$ the
general rate of recombination-generation. This model, which
appeared in the 1950's, has, since then, received much attention
(see \cite{A_A_R:1, B_F, R:1, YIN:1}).

It is a common phenomenon that electrical devices produce heat or temperature. 
One of the main reasons for considering the thermoelastic semiconductor problem 
is the observation that these devices are too often cracked and broken
because of the thermal stresses. However, the literature on this problem
has not dealt with the thermoelastic aspects of the process, only with
the thermal and electrical conductions.

In this paper we fill in this gap and consider a new model for the
thermoelastic semiconductor. The thermoelastic behavior is taken into
account, resulting in a fully coupled system of equations for the
temperature, electrical potential and elastic displacements. This model
consists of an elliptic equation of charge conservation of electrical
current,  three hyperbolic equations of displacement of the device,
a parabolic equation of the energy caused by Joule's heating, and two parabolic 
equations of the densities of electrons and holes.  For
the sake of simplicity, we assume that the material constitutive
behavior can be adequately described by linear thermoelasticity.
The nonlinearity resides in the electrical conductivity. Moreover, Joule's 
heating introduces a source term in the heat equation that is quadratic in
the gradient of the electrical potential. This feature makes
the problem interesting also from the mathematical point of view.
In this paper we establish the existence of a weak solution for the problem.


This paper is organized as follows. We present the
classical model of thermoelastic semiconductor in Section \ref{sec2} where
we explain in the combined process. The formulation of a weak solution
for this model is presented in Section \ref{sec3} together with the
assumptions on the data. The statement of our main result
is given in Theorem \ref{sec3:thm1}. The proof of the existence of a weak
solution is presented in Section \ref{sec4}. It is based on a sequence of
time retarded problems. The basic idea is the following. First we give a prior
estimates, and then construct a sequence of solutions of approximate problems.
By passing to the limits of the sequence, we will obtain a
weak solution.

\section{A Model of Thermoelastic Semiconductor Problem}
\label{sec2}

Let $\Omega\subset\mathbb{R}^N$ ($N\ge 2$) be a bounded domain with smooth
boundary $\Gamma=\partial\Omega$, representing the isothermal
reference configuration of the thermoelastic body, the semiconductor
in our case. We assume that $\Gamma$ is divided into two
relatively open parts $\Gamma_D$ and $\Gamma_N$ such that
$\Gamma_D\cap\Gamma_N=\emptyset$ and $\overline{\Gamma}_D\cup
\overline{\Gamma}_N=\Gamma$. We denote by $\nu=(\nu_1,
\dots, \nu_N)$ the outward unit normal to $\Gamma$. We assume that
the body is held fixed on $\Gamma_D$, and the temperature and
potential are prescribed there. On $\Gamma_N$ the body is free,
electrically insulted and exchanging heat with the environment. We
choose the Dirichlet conditions on $\Gamma_D$ for the three fields
for the sake of simplicity. We use $\theta$ to represent the
temperature field, $\varphi$ the electrical potential and
$u=(u_1, \dots, u_N)$ the
displacement field. Let $T>0$ and set $\Omega_T=\Omega\times(0, T)$.

The behavior of the system is governed by the energy equation, the
equation of charge conservation and the equations of linear
elasticity. In a non-dimensional form we may write the system
(see, e.g., \cite{A_C:1, C_C:1, D_L:1, H_R_S:1, YIN:1}) as
\begin{equation} \label{SemiEls}
\begin{gathered}
-\mathop{\rm div}(\sigma(\theta)\nabla\varphi)=p-n+f,\\
\frac{\partial n}{\partial t}-\mathop{\rm div}(d_n\nabla n-\mu_n
\sigma(\theta)n\nabla\varphi)=g(n,p)(1-np),\\
\frac{\partial p}{\partial t}-\mathop{\rm div}(d_p\nabla p+\mu_p
\sigma(\theta)p\nabla\varphi)=g(n,p)(1-np),\\
\frac{\partial\theta}{\partial t}-\frac{\partial}{\partial
x_j}\Big(k_{ij}(\theta)\frac{\partial \theta}{\partial x_i}\Big)
=\sigma(\theta) | \nabla \varphi |^2-m_{ij}\frac{\partial^2 u_i}{\partial t\partial x_j},\\
\rho \frac{\partial^2 u_i}{\partial t^2}-\frac{\partial}{\partial
x_j}\Big(a_{ijkl}\frac{\partial u_k}{\partial
x_l}-m_{ij}\theta\Big)=f_i.
\end{gathered}
\end{equation}
Here and below, $i, j, k, l=1, \dots, N$ and summation over
repeated indices is employed. The density $\rho>0$ is a constant;
$K=\{k_{ij}\}$ and $M=\{m_{ij}\}$ are the heat conduction and
thermal expansion tensors, respectively, and $A=\{a_{ijkl}\}$ is
the elasticity tensor; $\mathbf{f}=(f_1, \dots, f_N)$ represents
the density of body force. Finally, $\sigma=\sigma(\theta)$ is
the temperature-dependent electrical conductivity.

The first equation of \eqref{SemiEls} represents the charge conservation
of the electrical potential. The second and third ones represent
the exchange of the densities of electrons and holes of the semiconductor.
 The fourth one represents the heat transfer equation in terms of the
deformation of the semiconductor and the energy, produced by the
so-called Joule heating
\[
J=\sigma(\theta) | \nabla \varphi |^2
\]
generated by the electrical current for the temperature $\theta$.
The last one of \eqref{SemiEls} is the dynamic thermoelasticity equations
of displacement of the semiconductor.

To complete the classical formulation of the problem we have to specify
the initial and boundary conditions. We set
\begin{equation} \label{IniCon}
\begin{gathered}
\varphi=\varphi_b, \ n=n_b, \ p=p_b, \ u=0, \
 \theta=\theta_b, \ \text{on }\Gamma_D\times(0,T), \\
\frac{\partial\varphi}{\partial \nu}=0, \
\frac{\partial n}{\partial \nu}=0, \
\frac{\partial p}{\partial \nu}=0, \
\frac{\partial u_i}{\partial \nu}=0, \ i=1, \dots, N, \
\text{on }\Gamma_N\times(0,T), \\
-k_{ij}\frac{\partial \theta}{\partial
x_i}\nu_j=h(\theta-\theta_a),\ \text{on }\Gamma_N\times(0,T), \\
n=n_0, \ p=p_0, \ u=u_0, \ u_t=u_1, \
 \theta=\theta_0, \ \text{in }\Omega\times\{t=0\},
\end{gathered}
\end{equation}
where $n_0, p_0$ are the initial densities of electrons and holes,
respectively, $u_0, u_1$ the initial displacements and velocities,
respectively, $\theta_0$ the initial temperature, $n_b$, $p_b$
are the density on $\Gamma_D$ respectively, $\theta_b$ the temperature and
$\varphi_b$ the potential there, $\theta_a$ the ambient
temperature near $\Gamma_N$, and $h$ the heat exchange coefficient.

Our goal for this ``thermoelastic semiconductor'' problem is:
\begin{center}
Find $\{\varphi, n, p, \theta, u\}$ such that
\eqref{SemiEls}-\eqref{IniCon} are satisfied.
\end{center}
The precise assumptions on the data and the weak formulation are given
in the next section.

We note that, if (the electrical conductivity) $\sigma=0$ at large
temperature, the first equation of \eqref{SemiEls} for $\varphi$
degenerates and the heating term in the fourth equation of \eqref{SemiEls}
vanishes and  This degeneracy makes it necessary to consider a capacity
solution (\cite{XU:1,XU:2}) to this model.
Recently, Wu and Xu (\cite{W_X}) consider a model of thermoelastic
thermistor problem with the degenerate electrical conductivity and
obtain the existence of its capacity solutions.
The authors use time retardation to construct an approximate model
whose solution is easily to be obtained and whose limit is the
solution of the original model. The method used in this paper is
similar to the one in that paper. We must note that when
$\rho\partial^2u_i/\partial t^2$ may be omitted;
i.e., small $\rho$ or small accelerations, the resulting problem is
quasi-static and we will consider in future.

\section{Weak Formulation and Main Result}
\label{sec3}

We present a weak formation for our model, the assumptions
on the problem data and the statement of our existence results.
For simplicity we extend $n_b, p_b, \theta_b$ to functions defined
on $\overline{\Omega}_T$, and denote it by $n_b, p_b, \theta_b$.
This means that they have to satisfy a compatibility condition
\begin{gather*}
n_b,  p_b,  \theta_b\in H^1(\Omega_T), \\
\mathop{\rm ess\,sup}_{(\Gamma_D\times(0,T))\cup(\Omega\times{0})}{|n_b|,\
|p_b|, \ |\theta_b|}<\infty,\\
\varphi_b\in L^2(0,T; H^1(\Omega))\cap L^\infty(\Omega_T).
\end{gather*}
First, we introduce the following function spaces:
\begin{gather*}
V_0=H^1_D(\Omega)=\{w\in H^1(\Omega): w=0\text{  on  }\Gamma_D\}, \
 U_0=H^1_D(\Omega)^N
\end{gather*}
and denote by $V_0'$ and $U_0'$ their dual spaces, respectively.
Finally, we assume that $\rho>0$ is constant and that
\begin{gather*}
u_0(x)=(u_{01}, \dots, u_{0N})\in U_0, \\
u_1(x)=(u_{11}, \dots, u_{1N})\in (L^2(\Omega))^N, \\
f=(f_1, \dots, f_N)\in (L^2(\Omega_T))^N, \ h\in (0,\infty), \\
a_{ijkl},  \frac{\partial}{\partial t}a_{ijkl}\in
L^\infty(\Omega_T), a_{ijkl}=a_{jikl}=a_{klij}, \\
a_{ijkl}\eta_{ij}\eta_{kl}\ge
\lambda|\eta|^2=\lambda\sum_{i,j=1}^N\eta_{ij}^2, \ \forall
\eta=(\eta_{ij}),\\
\eta_{ij}=\eta_{ji},  \lambda>0, \\
m_{ij},  \frac{\partial}{\partial t}m_{ij}\in W^{1,
\infty}(\Omega_T), \ m_{ij}=m_{ji}, \\
k_{ij}\in L^\infty(\Omega_T), \  k_{ij}=k_{ji}, \\
k_{ij}\xi_i\xi_j\ge\lambda_1|\xi|^2, \ \forall \xi=(\xi_{ij}),
\lambda_1>0,\\
0<M_1\le\sigma(s)\le M_2, \text{where $M_1, M_2$ are constants},\\
d_n, d_p, \mu_n, \mu_p \text{ are positive constants.}
\end{gather*}
This completes the assumptions. Now we give the definition of weak solutions.

\begin{definition} \label{Def:weak} \rm
$\{\varphi, n, p, \theta, u,v\}$ is said to
be a weak solution of problem
\eqref{SemiEls}-\eqref{IniCon} if $\{\varphi, n, p, \theta, u,v\}$ satisfies
\begin{gather*}
\varphi-\varphi_b\in L^\infty(0,T; V_0), \
n-n_b\in L^\infty(0,T;V_0)\cap \in L^2(0,T;V_0), \\
p-p_b\in L^\infty(0,T;V_0)\cap \in L^2(0,T;V_0), \
\theta-\theta_b\in L^2(0,T; V_0), \\
n, p, \varphi\in L^\infty(\Omega_T),\
n_t\in L^2(0,T; V_0'), \
p_t\in L^2(0,T; V_0'), \
\theta_t\in L^2(0,T; V_0'), \\
u\in L^\infty(0,T; U_0), \
v\in L^\infty(0,T; L^2(\Omega)^N), \
v_{t}\in L^2(0,T; U_0'), \\
n(x, 0)=n_0, \ p(x,0)=p_0, \ \theta(x,0)=\theta_0, \\
 u(x, 0)=u_0, \ v(x, 0)=u_1, x\in\Omega,
\end{gather*}
such that, for all $\eta\in V_0, \gamma\in V_0\cap L^\infty(\Omega), w\in U_0$,
there hold
\begin{equation} \label{WeakSolution}
\begin{gathered}
\int_{\Omega}\sigma(\theta)\nabla\varphi\nabla\eta dx
 =\int_{\Omega}(n-p+f)\eta dx,
 \\
\langle n_t,\eta\rangle +\int_{\Omega}(d_n\nabla n-\mu_n \sigma(\theta)
n\nabla\varphi)\nabla\eta dx=\int_{\Omega}g(n,p)(1-np)\eta dx,
\\
\langle p_t,\eta\rangle +\int_{\Omega}(d_p\nabla p+\mu_p
\sigma(\theta)p\nabla\varphi)\nabla \eta dx=\int_{\Omega}g(n,p)(1-np)\eta dx,
\\
\begin{aligned}
&\langle \theta_t,\gamma\rangle +\int_{\Omega}k_{ij}(\theta)
\frac{\partial\theta}{\partial x_i}\frac{\partial \gamma}{\partial x_j}dx
+\int_{\Gamma_N}h(\theta-\theta_b)\gamma\,dS
\\
&=\int_{\Omega}\sigma(\theta)|\nabla\varphi|^2\gamma dx
+\int_{\Omega}m_{ij}\frac{\partial v_i}{\partial x_j}\gamma dx\,,
\end{aligned}\\
\langle v_{t},w\rangle +\int_{\Omega}\Big(a_{ijkl}
\frac{\partial u_k}{\partial x_l}-m_{ij}\theta\Big)
\frac{\partial w_i}{\partial x_j}dx=\int_{\Omega}fw\,dx, \\
v=u_t,
\end{gathered}
\end{equation}
where $\langle \cdot,\cdot\rangle $ denotes the duality pairing between
$V_0$ and $V_0'$ or $U_0$ and $U_0'$.
\end{definition}

We note that if $\varphi\in L^2(0,T;H^1(\Omega))$, then
\begin{align*}
\int_{\Omega}\mathop{\rm div}(\sigma(\theta)\varphi\nabla\varphi)\xi\,dx
&=\int_{\Omega}\mathop{\rm div}(\sigma(\theta)\nabla\varphi\cdot\varphi)
 \xi\,dx\\
&=\int_{\Omega}\sigma(\theta)|\nabla\varphi|^2\xi\,dx
 +\int_{\Omega}\mathop{\rm div}(\sigma(\theta)\nabla\varphi)\varphi\xi\,dx\\
&=\int_{\Omega}\sigma(\theta)|\nabla\varphi|^2\xi\,dx
 +\int_{\Omega}(n-p+f)\varphi\xi\,dx
\end{align*}
for all $\xi\in V_0$. Thus
\[
\sigma(\theta)|\nabla\varphi|^2=\mathop{\rm div}(\sigma(\theta)
 \varphi\nabla\varphi)-(n-p+f)\varphi
\]
in the sense of distributions. Hence the forth equation
of (\ref{WeakSolution}) can be written as
\begin{align*}
&\langle \theta_t,\gamma\rangle +\int_{\Omega}k_{ij}(\theta)
 \frac{\partial\theta}{\partial x_i}\frac{\partial
  \gamma}{\partial x_j}dx+\int_{\Gamma_N}h(\theta-\theta_b)\gamma\,dS\\
&=-\int_{\Omega}\sigma(\theta)\varphi\nabla\varphi\nabla\gamma dx
 -\int_{\Omega}\varphi(n-p+f)\gamma dx
 +\int_{\Omega}m_{ij}\frac{\partial v_i}{\partial x_j}\gamma dx.
\end{align*}

\begin{theorem} \label{sec3:thm1}
The problem stated above has a solution.
\end{theorem}

Formally, we may obtain a priori estimates by multiplying the
first equation of \eqref{SemiEls} by $\varphi-\varphi_b$, the
 second equation by $n-n_b$, the third by $p-p_b$, the forth by
$\theta-\theta_b$, the fifth by $\partial u_i/\partial t$, and
integrating over $\Omega$. For the necessary calculations to be valid,
$u$ has to be sufficiently regular. To achieve this we construct an
approximation scheme in which $\theta, n, p, u$ and $\varphi$
possess the needed regularities. This is based on a retardation scheme
in the time variable. The approximate problems are considered next.

\section{Approximate Problems and Proof of Theorem \ref{sec3:thm1}}
\label{sec4}

In this section we use the time-retardation method to construct a
sequence of approximate problems that will lead us to the proof of
existence for our problem. To do that, for fixed function $g$
defined in $[0,T]$ and $m>0$ , let $\varepsilon=\frac{T}{m}$ and define the
time-retarded function $g_\varepsilon$ of $g$ by
\[
g_\varepsilon=\begin{cases}
g(t-\varepsilon) &\text{if } t>\varepsilon,\\
g_0 &\text{if } t\in[0,\varepsilon],
\end{cases}
\]
where $g_0$ will be given. Consider the following approximation problem:
for all $\psi\in V_0, \gamma\in V_0\cap L^\infty(\Omega), w\in U_0$
\begin{equation} \label{ApprProblem}
\begin{gathered}
\int_{\Omega}\sigma(\theta^\varepsilon_\varepsilon)\nabla\varphi^\varepsilon\nabla\psi dx
 =\int_{\Omega}(p^\varepsilon-n^\varepsilon+f)\psi dx,
 \\
\langle n^\varepsilon_t,\psi\rangle +\int_{\Omega}(d_n\nabla n^\varepsilon
-\mu_n\sigma(\theta^\varepsilon_\varepsilon)n^\varepsilon\nabla\varphi^\varepsilon)\nabla\psi dx
=\int_{\Omega}g(n^\varepsilon,p^\varepsilon)(1-n^\varepsilon p^\varepsilon)\psi dx,
\\
\langle p^\varepsilon,\psi\rangle +\int_{\Omega}(d_p\nabla p^\varepsilon
+\mu_p\sigma(\theta^\varepsilon_\varepsilon)p^\varepsilon\nabla\varphi^\varepsilon)\nabla \psi dx
=\int_{\Omega}g(n^\varepsilon,p^\varepsilon)(1-n^\varepsilon p^\varepsilon)\psi dx,
\\
\begin{aligned}
&\langle \theta^\varepsilon,\gamma\rangle +\int_{\Omega}k_{ij}
 (\theta_\varepsilon^\varepsilon)\frac{\partial \theta^\varepsilon}{\partial x_i}
  \frac{\partial\gamma}{\partial x_j}dx+\int_{\Gamma_N}
  h(\theta^\varepsilon-\theta_b)\gamma\,dS\\
&=-\int_{\Omega}\sigma(\theta^\varepsilon_\varepsilon)\varphi^\varepsilon\nabla
 \varphi^\varepsilon\nabla\gamma dx  -\int_{\Omega}\varphi^\varepsilon(n^\varepsilon-p^\varepsilon
 +f)\gamma dx-\int_{\Omega}m_{ij}
 \frac{\partial v_i^\varepsilon}{\partial x_j}\gamma dx,
\end{aligned}
\\
\rho \langle v_t^\varepsilon,w\rangle +\int_{\Omega}a_{ijkl}
\frac{\partial u_k^\varepsilon}{\partial x_l}\frac{\partial
w_i}{\partial x_j}dx-\int_{\Omega}m_{ij}\theta^\varepsilon
\frac{\partial w_i}{\partial x_j}dx=\int_{\Omega}f_iw_i dx,
\\
v^\varepsilon=u_t^\varepsilon
\end{gathered}
\end{equation}
with the following boundary conditions:
\begin{gather*}
\varphi^\varepsilon=\varphi_b, \ n^\varepsilon=n_b, \ p^\varepsilon=p_b, \ u^\varepsilon=0,
\ \theta=\theta_b, \ \text{on }\Gamma_D\times(0,T),
\\
\frac{\partial\varphi^\varepsilon}{\partial \nu}=0, \
\frac{\partial n^\varepsilon}{\partial \nu}=0, \
\frac{\partial p^\varepsilon}{\partial \nu}=0, \
\frac{\partial u_i^\varepsilon}{\partial \nu}=0, \ i=1, \dots, N,
 \text{ on  }\Gamma_N\times(0,T),
 \\
-k_{ij}\frac{\partial \theta^\varepsilon}{\partial
x_i}\nu_j=h(\theta^\varepsilon-\theta_a), \ \text{on }\Gamma_N\times(0,T), \\
n^\varepsilon=n_0, \ p^\varepsilon=p_0, \ u^\varepsilon=u_0, \ v^\varepsilon=u_1, \
 \theta^\varepsilon=\theta_0, \ \text{in  }\Omega\times\{t=0\},
\end{gather*}
Here, according to the definition above,
 $$
 \theta^\varepsilon_\varepsilon=\theta^\varepsilon(t-\varepsilon)=\theta_0, \ \text{for }t\in[0,\varepsilon]
$$
is given. With $\sigma(\theta^\varepsilon_\varepsilon)$ given and the fact that $\sigma$ is
bounded between positive constants, the first three equations
of \eqref{ApprProblem} are the system of standard elliptic and
parabolic equations of semiconductor devices. The existence and
uniqueness of the solutions of these three equations in $[0,\varepsilon]$
are well known (e.g., see \cite{YIN:1}). Once we obtain
$(\varphi^\varepsilon, n^\varepsilon, p^\varepsilon)$, the rest three equations of \eqref{ApprProblem}
are standard linear thermoelasticity equations whose existence and
uniqueness of the solution $(\theta^\varepsilon,u^\varepsilon,v^\varepsilon)$ in $[0,\varepsilon]$ are also well 
known (e.g., see \cite{R_R:1}). We proceed inductively on each time
interval $[k\varepsilon,(k+1)\varepsilon]$ for $0\le k\le m$ to obtain the unique
solution of \eqref{ApprProblem} in $[0,T]$.

To take limit as $\varepsilon\to 0$ in \eqref{ApprProblem} we need some
a priori estimates. The following result is cited from (\cite{YIN:1}).

\begin{lemma}
\label{lemma1}
There is a constant $C$ independent of $\varepsilon$ such that
\begin{gather*}
 0\le n^\varepsilon, \ p^\varepsilon\le C, \
\|\varphi^{\varepsilon}\|_{L^\infty(\Omega_T)}\le C, \
\|\varphi^\varepsilon\|_{H^1(\Omega)}\le C, \\
\|n^\varepsilon\|_{L^2(0,T;H^1(\Omega))}+\|p^\varepsilon\|_{L^2(0,T;H^1(\Omega))}\le C.
\end{gather*}
\end{lemma}

With the estimates of this lemma and using the same method in
\cite{R_R:1}, we have the following a priori estimate results for the
last two equations of \eqref{ApprProblem}.

\begin{lemma}\label{lemma2}
The following estimate holds
\begin{align*}
&\sup_{0\le t\le T}\|\theta^{\varepsilon}(t)\|_{L^2}^2+\int_0^T
\|\nabla \theta^{\varepsilon}(\tau)\|_{L^2}^2d\tau
+\int_0^T\int_{\Gamma_N}h|\theta^{\varepsilon}-\theta_b|^2\,ds\\
&+\sup_{0\le t\le T}\|u^{\varepsilon}(x,t)\|^2_{U_0}+\sup_{0\le t\le T}
\|v^{\varepsilon}(x,t)\|_{L^2}^2\,dx \le C,
\end{align*}
where $C$ is a positive constant that depends on the data but
is independent of $m$.
\end{lemma}

\begin{proof}
Using $\theta^\varepsilon-\theta_b$ as a test function in the forth equation of
\eqref{ApprProblem}, we have
\begin{align*}
&\int_{\Omega}\frac{\partial\theta^\varepsilon}{\partial t}(\theta^\varepsilon-\theta_b)dx
 +\int_{\Omega}k_{ij}(\theta_\varepsilon^\varepsilon)\frac{\partial\theta^\varepsilon}{\partial x_i}
 \frac{\partial(\theta^\varepsilon-\theta_b)}{\partial x_j}dx
 +\int_{\Gamma_N}h|\theta^{\varepsilon}-\theta_b|^2\,ds\\
&=-\int_{\Omega}\sigma(\theta_\varepsilon^\varepsilon)\varphi^\varepsilon\nabla\varphi^\varepsilon\nabla
 (\theta^\varepsilon-\theta_b)dx-\int_{\Omega}\varphi^\varepsilon(n^\varepsilon-p^\varepsilon+f)(\theta^\varepsilon
 -\theta_b)dx\\
&\quad -\int_{\Omega}m_{ij}\frac{\partial v_i^\varepsilon}{\partial x_j}
 (\theta^\varepsilon-\theta_b)dx,
\end{align*}
from which we derive
\begin{align*}
&\frac{1}{2}\frac{d}{dt}\|\theta^\varepsilon-\theta_b\|_{L^2}^2dx
 +\int_{\Omega}k_{ij}(\theta_\varepsilon^\varepsilon)\frac{\partial (\theta^\varepsilon-\theta_b)}
 {\partial x_i}\frac{\partial(\theta^\varepsilon-\theta_b)}{\partial x_j}dx
 +\int_{\Gamma_N}h|\theta^{\varepsilon}-\theta_b|^2\,ds\\
&=- \int_{\Omega}\frac{\partial \theta_b}{\partial t}(\theta^\varepsilon
  -\theta_b)dx- \int_{\Omega}k_{ij}(\theta_\varepsilon^\varepsilon)
  \frac{\partial \theta_b}{\partial x_i}\frac{\partial(\theta^\varepsilon-\theta_b)}
  {\partial x_j}dx\\
&\quad -\int_{\Omega}\sigma(\theta_\varepsilon^\varepsilon)\varphi^\varepsilon\nabla\varphi^\varepsilon
  \nabla(\theta^\varepsilon-\theta_b)dx-\int_{\Omega}\varphi^\varepsilon(n^\varepsilon-p^\varepsilon
  +f)(\theta^\varepsilon-\theta_b)dx\\
&\quad -\int_{\Omega}m_{ij}\frac{\partial v_i^\varepsilon}{\partial x_j}(\theta^\varepsilon
 -\theta_b)dx\\
&\le C\int_{\Omega}|\theta^\varepsilon-\theta_b|dx+\frac{1}{2}\int_{\Omega}k_{ij}
 (\theta_\varepsilon^\varepsilon)\frac{\partial \theta_b}{\partial x_i}
 \frac{\partial \theta_b}{\partial x_j}dx
 +\frac{1}{2}\int_{\Omega}k_{ij}(\theta_\varepsilon^\varepsilon)\frac{\partial(\theta^\varepsilon
 -\theta_b)}{\partial x_i}\frac{\partial(\theta^\varepsilon-\theta_b)}
 {\partial x_j}dx\\
&\quad -\int_{\Omega}\sigma(\theta_\varepsilon^\varepsilon)\varphi^\varepsilon\nabla\varphi^\varepsilon
 \nabla(\theta-\theta_b)dx-\int_{\Omega}\varphi^\varepsilon(n^\varepsilon-p^\varepsilon+f)
 (\theta^\varepsilon-\theta_b)dx\\
&\quad -\int_{\Omega}m_{ij}\frac{\partial v_i^\varepsilon}{\partial x_j}(\theta^\varepsilon
 -\theta_b)dx.
\end{align*}
With the estimates in Lemma \ref{lemma1} and by the Poincar\'e inequality,
 we have
\begin{align*}
&\frac{d}{dt}\|\theta^\varepsilon-\theta_b\|_{L^2}^2+C_1\|\nabla(\theta^\varepsilon
 -\theta_b)\|^2_{L^2}+\int_{\Gamma_N}h|\theta^{\varepsilon}-\theta_b|^2\,ds\\
&\le C_2-\int_{\Omega}m_{ij}\frac{\partial v_i^\varepsilon}{\partial x_j}(\theta^\varepsilon
 -\theta_b)dx,
\end{align*}
Using $v_i$ as a test function in the fifth equation of \eqref{ApprProblem}, we have
\[
\frac{1}{2}\rho\frac{d}{dt}\|v\|_{L^2}^2+\int_{\Omega}a_{ijkl}
\frac{\partial u_k^\varepsilon}{\partial x_l}\frac{\partial v_i^\varepsilon}{\partial x_j}dx
-\int_{\Omega}m_{ij}\theta^\varepsilon \frac{\partial v_i^\varepsilon}{\partial x_j}dx
=\int_{\Omega}f_iv_idx
\]
Noting that $v_i^\varepsilon=\frac{\partial u^\varepsilon_i}{\partial t}$, we have
\begin{align*}
&\frac{1}{2}\rho\frac{d}{dt}\|v\|_{L^2}^2+\frac{1}{2}\frac{d}{dt}
 \int_{\Omega}a_{ijkl}\frac{\partial u_k^\varepsilon}{\partial x_l}
 \frac{\partial u_i^\varepsilon}{\partial x_j}dx\\
&=\frac{1}{2}\int_{\Omega}\frac{\partial a_{ijkl}}{\partial t}
 \frac{\partial u_k^\varepsilon}{\partial x_l}\frac{\partial u_i^\varepsilon}{\partial x_j}dx
 +\int_{\Omega}m_{ij}\theta^\varepsilon \frac{\partial v_i^\varepsilon}{\partial x_j}dx
 +\int_{\Omega}f_iv_idx\\
&\le C+C\|\nabla u^\varepsilon\|_{L^2}^2+\int_{\Omega}m_{ij}\theta^\varepsilon
 \frac{\partial v_i^\varepsilon}{\partial x_j}dx+C\|v\|^2_{L^2}.
\end{align*}
Integrating by parts and adding the above two estimates we obtain
\begin{align*}
&\frac{d}{dt}\Big(\|\theta^\varepsilon-\theta_b\|_{L^2}^2+\rho\|v\|_{L^2}^2
+\int_{\Omega}a_{ijkl}\frac{\partial u_k^\varepsilon}{\partial x_l}
\frac{\partial u_i^\varepsilon}{\partial x_j}dx\Big)\\
&+C_1\|\nabla(\theta^\varepsilon-\theta_b)\|^2_{L^2}+\int_{\Gamma_N}h|\theta^{\varepsilon}-\theta_b|^2\,ds\\
&\le C+C\|v^\varepsilon\|_{L^2}^2+C\|\nabla u^\varepsilon\|^2_{L^2}
\end{align*}
The assumption on $a_{ijkl}$ and the Gronwall inequality derive the
desired estimates.
\end{proof}


To use the energy estimates in Lemmas \ref{lemma1}-\ref{lemma2} to
extract convergence subsequences of
$\{\varphi^\varepsilon\}, \{n^\varepsilon\}, \{p^\varepsilon\}, \{\theta^{\varepsilon}\}, \{u^\varepsilon\}$
and $\{v^{\varepsilon}\}$, we need the following lemma.

\begin{lemma} \label{lemma3}
Let $B_0, B, B_1$ be Banach spaces with $B_0\subset B\subset B_1$;
assume $B_0\hookrightarrow B$ is compact and $B\hookrightarrow B_1$
is continuous. Let $1<p<\infty$, $1<q<\infty$, let $B_0$
and $B_1$ be reflexive, and define
\[
W\equiv\{u\in L^p(0,T;B_0), \frac{du}{dt}\in L^q(0,T;B_1)\}.
 \]
Then the inclusion $W\hookrightarrow L^p(0,T;B)$ is compact.
\end{lemma}

The Proof of Theorem \ref{sec3:thm1} follows from the following lemmas.

\begin{lemma} \label{lemma4}
There holds
$\theta^\varepsilon\to\theta$ strongly in
$L^2(0,T;L^2(\Omega))\equiv L^2(\Omega_T)$
as $\varepsilon\to 0$.
\end{lemma}

\begin{proof}
From Lemmas \ref{lemma1}-\ref{lemma2}, there are subsequences,
 still denoted by the original ones, such that
\begin{gather*}
\theta^\varepsilon\to\theta \ \text{weakly$^*$ in  }L^\infty(0,T;L^2(\Omega)),\\
\theta^\varepsilon\to\theta \ \text{weakly in  }L^2(0,T;H^1(\Omega)),\\
\frac{d\theta^\varepsilon}{dt}\to\frac{d\theta}{dt} \ \text{weakly in  }
L^2(0,T;H^1(\Omega)'),
\end{gather*}
as $\varepsilon\to 0$. By Lemma \ref{lemma3},
\[ 
\theta^\varepsilon\to\theta \quad \text{strongly in }L^2(0,T;L^2(\Omega))
\equiv L^2(\Omega_T), 
\]
and hence
$\theta^\varepsilon\to\theta$ a.e. in  $\Omega_T$
as $\varepsilon\to 0$. Noting that 
$\theta^\varepsilon_\varepsilon(t)=\theta^\varepsilon(t-\varepsilon)$, 
we also have
$\theta^\varepsilon_\varepsilon\to\theta$ a.e. in  $\Omega_T$.
\end{proof}

Using this lemma, we can extract convergence subsequences of
$\{\varphi^\varepsilon\}$, $\{v^\varepsilon\}$ and $\{u^\varepsilon\}$ in suitable spaces.

\begin{lemma}\label{lemma5}
There is a subsequence of $\{\varphi^\varepsilon\}$, still denoted by
$\{\varphi^\varepsilon\}$, such that
$\varphi^\varepsilon\to \varphi$ strongly in $H^1(\Omega)$
as $\varepsilon\to 0$.
\end{lemma}

\begin{proof}
Since $\{\varphi^\varepsilon\}$ is bounded in $L^\infty(0,T;H^1(\Omega))$,
there is a subsequence of $\{\varphi^\varepsilon\}$, still denoted by
$\{\varphi^\varepsilon\}$, such that
\[
\varphi^\varepsilon\to \varphi \quad \text{weakly* in  }L^\infty(0,T;H^1(\Omega)).
\]
By Sobolev's embedding theorem
\[
\varphi^\varepsilon\to \varphi \quad \text{strongly in }L^2(\Omega).
\]
Using $\varphi^\varepsilon-\varphi$ as a test function in the first equation
of \eqref{ApprProblem} to get
\[
\int_{\Omega}\sigma(\theta^\varepsilon_\varepsilon)\nabla\varphi^\varepsilon
\nabla(\varphi^\varepsilon-\varphi)dx
=\int_{\Omega}(n^\varepsilon-p^\varepsilon+f)(\varphi^\varepsilon
-\varphi)dx
\]
from which, by the assumption of $\sigma$, we obtain
\begin{align*}
&\int_{\Omega}|\nabla(\varphi^\varepsilon-\varphi)|^2dx\\
&\le C\int_{\Omega}(n^\varepsilon-p^\varepsilon+f)(\varphi^\varepsilon-\varphi)dx
  -C\int_{\Omega}\sigma(\theta^\varepsilon_\varepsilon)\nabla\varphi\nabla(\varphi^\varepsilon-\varphi)dx \\
&\le C\int_{\Omega}|\varphi^\varepsilon-\varphi|dx
  -C\int_{\Omega}(\sigma(\theta^\varepsilon_\varepsilon)-\sigma(\theta))\nabla\varphi\nabla(\varphi^\varepsilon-\varphi)dx\\
&\quad -C\int_{\Omega}\sigma(\theta)\nabla\varphi\nabla(\varphi^\varepsilon-\varphi)dx.
\end{align*}
Note that
\begin{align*}
&\big|\int_{\Omega}(\sigma(\theta^\varepsilon_\varepsilon)-\sigma(\theta))\nabla
 \varphi\nabla(\varphi^\varepsilon-\varphi)dx\big|\\
&\le \Big(\int_{\Omega}|\sigma(\theta^\varepsilon_\varepsilon)-\sigma(\theta)|^2
  |\nabla\varphi|^2dx\Big)^{1/2}
 \Big(\int_{\Omega}|\nabla(\varphi^\varepsilon-\varphi)|^2dx\Big)^{1/2}.
\end{align*}
Since
\[
|\sigma(\theta^\varepsilon_\varepsilon)-\sigma(\theta)||\nabla\varphi|
\le C|\nabla\varphi|
\]
we have $|\sigma(\theta^\varepsilon_\varepsilon)
-\sigma(\theta)||\nabla\varphi|\in L^2(\Omega)$. 
Thus by Lebsegue's Convergence Theorem, we derive
\[
\int_{\Omega}|\nabla(\varphi^\varepsilon-\varphi)|^2dx \to 0 \quad
\text{as  }\varepsilon\to 0.
\]
This implies that $\varphi^\varepsilon\to\varphi$ strongly 
in $H^1(\Omega)$ as $\varepsilon\to 0$.
\end{proof}

With the help of Lemmas \ref{lemma4} and \ref{lemma5}, it is easy
to obtain the following corollary.

\begin{corollary}\label{cor1}
As $\varepsilon\to 0$, the first equation of \eqref{ApprProblem} becomes the
first equation of \eqref{Def:weak}.
\end{corollary}

\begin{lemma} \label{lemma6}
There holds
$n^\varepsilon\to n, p^\varepsilon\to p$ weakly in $L^2(0,T;H^1(\Omega))$ and
strongly in $L^2(0,T;L^2(\Omega))$.
\end{lemma}

\begin{proof}
From Lemmas \ref{lemma1}-\ref{lemma2}, there are subsequences,
still denoted by the original ones, such that
\begin{gather*}
n^\varepsilon\to n, p^\varepsilon\to p \ \text{weakly$^*$ in  }L^\infty(0,T;L^2(\Omega)),\\
n^\varepsilon\to n, p^\varepsilon\to p \ \text{weakly in }L^2(0,T;H^1(\Omega)),\\
\frac{d n^\varepsilon}{dt}\to\frac{d n}{dt}, \frac{d p^\varepsilon}{dt}\to\frac{d p}{dt}, \
\text{weakly in  }L^2(0,T;H^1(\Omega)').
\end{gather*}
By Lemma \ref{lemma3},
\[
n^\varepsilon\to n, p^\varepsilon\to p \ \text{strongly in }
L^2(0,T;L^2(\Omega))\equiv L^2(\Omega_T),
\]
and hence
$n^\varepsilon\to n$ and  $p^\varepsilon\to p$ a.e. in $\Omega_T$.
\end{proof}

With the help of Lemmas \ref{lemma4}-\ref{lemma6}, we obtain

\begin{corollary} \label{cor2}
As $\varepsilon\to 0$, the second and third equations of \eqref{ApprProblem}
go to the second and third equations of \eqref{Def:weak}, respectively.
\end{corollary}

\begin{lemma} \label{lemma7}
There hold:
\begin{gather*}
v^\varepsilon\to v\quad\text{weakly* in } L^\infty(0,T;L^2(\Omega)), \\
\frac{\partial v^\varepsilon}{\partial t}\to \frac{\partial v}{\partial t}\quad
\text{weakly in } L^2(0,T;H^1(\Omega)'), \\
 u^\varepsilon \to u \quad \text{weakly* in  }L^\infty(0,T;H^1(\Omega)).
 \end{gather*}
\end{lemma}

\begin{proof}
 From Lemma \ref{lemma2}, we conclude that there exist subsequences,
still denoted by the original ones, such that
\[
 v^\varepsilon\to v\quad \text{weakly* in  }L^\infty(0,T;L^2(\Omega)),
\ u^\varepsilon \to u\quad \text{weakly* in }L^\infty(0,T;V_0).
\]
Thus
\[
\frac{\partial v^\varepsilon}{\partial t}\to\frac{\partial v}{\partial t} \quad
\text{weakly in  }  L^2(0,T;H^1(\Omega)').
\]
\end{proof}

With the help of Lemmas \ref{lemma4}-\ref{lemma7}, we obtain

\begin{corollary} \label{cor3}
As $\varepsilon\to 0$, the fourth, fifth and sixth equations of
\eqref{ApprProblem} go to the fourth, fifth and sixth equations
of \eqref{Def:weak}, respectively.
\end{corollary}

Collecting the results in Corollaries \ref{cor1}-\ref{cor3}, we have 
the proof of Theorem \ref{sec3:thm1}.


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\end{document}