\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2012 (2012), No. 73, pp. 1--9.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2012 Texas State University - San Marcos.}
\vspace{9mm}}

\begin{document}
\title[\hfilneg EJDE-2012/73\hfil Decay results for viscoelastic diffusion equations]
{Decay results for viscoelastic diffusion equations in absence of
instantaneous elasticity}

\author[M. Kafini \hfil EJDE-2012/73\hfilneg]
{Mohammad Kafini}  % in alphabetical order

\address{Mohammad Kafini \newline
Department of Mathematics and Statistics\\
KFUPM, Dhahran 31261\\
Saudi Arabia}
\email{mkafini@kfupm.edu.sa}

\thanks{Submitted December 18, 2011. Published May 10, 2012.}
\subjclass[2000]{35B05, 35L05, 35L15, 35L70}
\keywords{Diffusion equation; instantaneous
elasticity; exponential decay; \hfill\break\indent 
relaxation function; viscoelastic}

\begin{abstract}
 We study the diffusion equation in the absence of instantaneous elasticity
 \begin{equation*}
 u_t-\int_0^{t}g(t-\tau )\Delta u(\tau )\,d\tau =0,\quad (x,t)\in \Omega
 \times (0,+\infty ),
 \end{equation*}
 where $\Omega \subset \mathbb{R}^n$, subjected to nonlinear
 boundary conditions. We prove that if the relaxation function
 $g$ decays  exponentially, then the solutions is exponential stable.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\allowdisplaybreaks

\section{Introduction}

  A diffusion equation in the absence of instantaneous
elasticity has the form
\begin{equation} \label{e1}
u_t-\int_0^{t}g(t-\tau )\Delta u(\tau )\,d\tau =0,\quad (x,t)\in \Omega
\times (0,+\infty ).
\end{equation}
When the fluid is enclosed in a region $\Omega \subset \mathbb{R}^n$ the above equation is supplemented by conditions at
$\partial \Omega $, the boundary of $\Omega $. For instance, one can
consider the nonlinear boundary condition:
\begin{equation} \label{e2}
\partial _{\nu }u+f(u)=0,\quad \partial \Omega \times (0,+\infty ).
\end{equation}
Let us assume that
\begin{equation} \label{e3}
u(x,0)=u_0(x),\quad x\in \Omega .
\end{equation}
Denoting
\begin{equation*}
(g\ast \varphi )(t)=\int_0^{t}g(t-s)\varphi (s)\,ds
\end{equation*}
and differentiating equation \eqref{e1}, with respect to $t$, we arrive at the
Volterra equation
\begin{equation} \label{e4}
\frac{1}{g(0)}u_{tt}=\Delta u+\frac{1}{g(0)}(g'\ast \Delta u).
\end{equation}

Considering the Volterra inverse operator we obtain
\begin{equation} \label{e5}
u_{tt}-g(0)\Delta u+k\ast u_{tt}=0,
\end{equation}
where the resolvent kernel satisfies
\begin{equation*}
k+\frac{1}{g(0)}g'\ast k=-\frac{1}{g(0)}g'.
\end{equation*}
 Thus \eqref{e5} becomes
\begin{equation} \label{e6}
u_{tt}-g(0)\Delta u+k(0)u_t-k(t)u_t(0)+k'\ast u_t=0.
\end{equation}

Reciprocally, supposing in a natural way that $u_t(0)=0$, the identity \eqref{e6}
implies \eqref{e1}. Since we are interested in relaxation functions of exponential
type and \eqref{e6} involves the resolvent kernel $k$, we want to know if $k$ has
the same properties. The following lemma answers this question. Let $h$ be a
relaxation function and $k$ its resolvent kernel; that is,
\begin{equation} \label{e7}
k(t)-k\ast h(t)=h(t).
\end{equation}

 \begin{lemma}[\cite{m1,r1,r2}] \label{lem1.1}
 If $h$ is a positive continuous function, then $k$ is also  a positive
continuous function. Moreover, if there exist   positive
constants $c_0<\gamma$, such that
\begin{equation*}
h(t)\leq c_0e^{-\gamma t},
\end{equation*}
then the function $k$ satisfies
\begin{equation*}
k(t)\leq \frac{c_0(\gamma -\epsilon )}{\gamma -\epsilon -c_0}
e^{-\epsilon t},
\end{equation*}
for all $0<\epsilon <\gamma -c_0$.
\end{lemma}

\begin{proof}
 Note that $k(0)=h(0)>0$. Now, we take
\begin{equation*}
t_0=\text{inf}\{t\in \mathbb{R}^{+}:k(t)=0\},
\end{equation*}
so $k(t)>0$ for all  $t\in [ 0,t_0[$. If $t_0\in \mathbb{R}^{+}$,
from equation \eqref{e7} we obtain that $-k\ast h(t_0)=h(t_0)$
but this is contradictory.  Therefore, $k(t)>0$ for all
$t\in \mathbb{R}^{+}$. Now, let us fix $\epsilon $, such that
$0<\epsilon <\gamma -c_0$ and denote
\begin{equation*}
k_{\epsilon }(t):=e^{\epsilon t}k(t),\quad
h_{\epsilon }(t):=e^{\epsilon t}h(t).
\end{equation*}
Multiplying equation \eqref{e7} by $e^{\epsilon t}$ we obtain
\begin{equation*}
k_{\epsilon }(t)=h_{\epsilon }(t)+k_{\epsilon }\ast h_{\epsilon }(t),
\end{equation*}
hence
\begin{align*}
\underset{s\in [ 0,t]}{\sup }k_{\epsilon }(s) 
&\leq \sup h_{\epsilon }(s)
+\Big\{ \int_0^{\infty }c_0e^{(\epsilon -\gamma )s}ds\Big\}
\sup_{s\in [ 0,t]} k_{\epsilon }(s) \\
&\leq c_0+\frac{c_0}{( \gamma -\epsilon ) }\sup_{s\in[ 0,t]} k_{\epsilon }(s).
\end{align*}
Therefore,
\begin{equation*}
k_{\epsilon }(t)\leq \frac{c_0(\gamma -\epsilon )}{\gamma -\epsilon -c_0},
\end{equation*}
 which is the desired result.
\end{proof}

 Thanks to Lemma \ref{lem1.1}, we can use equation \eqref{e6} instead of \eqref{e1}.

Usually when $g$ is such that $\operatorname{Re}(\hat{g})>0$ 
($\hat{g}$ is the Fourier transform of $g$), we can, by the Laplace transformation,
 reduce equation \eqref{e1} to an elliptic problem. 
By the variational method, we can resolve such
an equation (see Raynal \cite{r2}). In what follows we shall adopt a different
procedure in order to establish the well-posedness of problem \eqref{e1}.

So, from the above comments, we can consider equation \eqref{e6}, instead of
equation \eqref{e1}, supplemented by the initial data \eqref{e3}, the compatibility
condition $u_t(0)=0$, and the  boundary conditions
\begin{equation} \label{e8}
\begin{gathered}
\partial _{\nu }u+\beta u_t+|u|^{\rho }u=0,\quad{on }\Gamma _1\times (0,\infty ) \\
u=0,\quad \Gamma _0\times (0,+\infty ),
\end{gathered}
\end{equation}
assuming that $k\in W^{2,1}(0,+\infty )$, $\beta >0$ and 
$0<\rho <2/(n-2)$ if $n\geq 3$ or $\rho >0$ if $n=1,2$.

We shall assume that $\Omega $ is a bounded domain of $\mathbb{R}^n$, 
$n\geq 1$, with a smooth boundary $\Gamma =\Gamma _0\cup \Gamma_1 $.
Here, $\Gamma _0\neq \emptyset $; $\Gamma _0$ and $\Gamma _1$
are closed and disjoint and $\nu $ represents the unit outward normal to 
$\Gamma $.

The variational formulation associated with problem \eqref{e6} is
\begin{align*}
&(u_{tt}(t),v)_{\Omega }-g(0)(\Delta u(t),v)_{\Omega}\\
&+k(0)(u_t(t),v)_{\Omega }+\int_0^{t}k'(t-\tau )(u'(\tau ),v)_{\Omega }\,d\tau 
+g(0)(f(u),v)_{\Gamma _1}=0,
\end{align*}
for all $v\in H_{\Gamma _0}^1(\Omega ):=\{u\in H^1(\Omega );u=0
\text{ on }\Gamma _0\}$.

We can easily obtain the existence and uniqueness of global \emph{regular
solutions} making use, for instance, of the Faedo-Galerkin method.

Evidently the additional term given by $\beta u_t$ plays an essential role
by allowing us to control the nonlinear term on the boundary. This is
strongly necessary because of Lopatinski condition is lost. Thus, it is
clear and it has been recognized a long time ago, that well-posedness theory
with semilinear boundary nonlinearity and finite energy solutions must rely
on and take advantage of the boundary dissipation. See, for instance,
Cavalcanti et al \cite{c2}, Lasiecka and Tataru \cite{l1} and references
therein.

However, from the physical point of view to have two dissipations, namely, 
$k(0)u_t$ (internal) and $\beta u_t$ (on the boundary) is too much to
establish the exponential decay. So, by considering the techniques 
employed in Lasiecka and Tataru \cite{l1} or in Cavalcanti, Cavalcanti,
and Soriano \cite{c2}, it is possible to obtain the existence of weak solutions
to \eqref{e6} subject to the boundary conditions
\begin{equation} \label{e9}
\partial _{\nu }u+|u|^{\rho }u=0,\quad
\text{on }\Gamma _1\times (0,\infty ).
\end{equation}
Unfortunately, because of the nonlinear boundary condition \eqref{e9}, the
uniqueness is lost.

Indeed, let $A$ be the operator whose domain is defined by
\begin{equation*}
D(A)=\left\{ (u,v)\in H_{\Gamma _0}^1(\Omega )\times H_{\Gamma
_0}^1(\Omega );u-\mathcal{N}[g_1(\gamma _0v)+f_1(\gamma _0u)]\in
D(-\Delta )\right\}
\end{equation*}
 and the operator by
\begin{equation*}
A\begin{pmatrix} u \\ v\end{pmatrix}
=\begin{pmatrix}
-v \\
\Delta (u-\mathcal{N}[g_1(\gamma _0v)+f_1(\gamma _0u)])
\end{pmatrix}.
\end{equation*}
We are assuming that
\begin{equation} \label{e10}
g_1(s)=\beta s,\quad f_1 \text{ is a Lipschitz continuous function on }
\mathbb{R},
\end{equation}
 and
\begin{align*}
D(-\Delta ) &= \{ v\in H_{\Gamma _0}^1(\Omega );\Delta v\in L^2(\Omega )\} \\
&= \big\{ v\in H_{\Gamma _0}^1(\Omega )\cap H^2(\Omega );\frac{
\partial v}{\partial \nu }=0\text{ on }\Gamma _1\big\} ,
\end{align*}
 and $\mathcal{N}:H^{s}(\Gamma _1)\to H_{\Gamma
_0}^{s+3/2}(\Omega )$, $s\in \mathbb{R}$, is the Neumann map
defined by
\begin{equation*}
\mathcal{N}p=q\Leftrightarrow 
\left\{
\begin{gathered}
-\Delta q=0\quad \text{in } \Omega \\
q=0\quad \text{on }\Gamma _0 \\
\frac{\partial q}{\partial \nu }=p\quad \text{on }\Gamma _1
\end{gathered}
\right.
\end{equation*}
We observe that
\begin{equation} \label{e11}
(u,v)\in D(A)\Leftrightarrow
\left\{
\begin{gathered}
(u,v)\in [ H_{\Gamma _0}^1(\Omega )] ^2, \\
u-\mathcal{N}[g_1(\gamma _0v)+f_1(\gamma _0u)]\in H_{\Gamma_0}^1(\Omega ), \\
\Delta (u-\mathcal{N}[g_1(\gamma _0v)+f_1(\gamma _0u)])\in L^2(\Omega ).
\end{gathered}
\right.
\end{equation}

By the nonlinear semigroup theory  \cite[Theorem 2.1]{l1}, 
 the operator $A$ is $\omega$-accretive on the space
 $E:=H_{\Gamma_0}^1(\Omega )\times L^2(\Omega )$, for some $\omega $ suitably large.
Moreover, $A+\omega I$ is maximal monotone and
\begin{equation} \label{e12}
D(A)\text{ is dense in }H_{\Gamma _0}^1(\Omega )\times L^2(\Omega ).
\end{equation}

Let us assume that $\{ u^{0},u^1\} \in H_{\Gamma _0}^1(\Omega )\times L^2(\Omega )$
 and consider, in view of \eqref{e12},
 $\{ u_{\mu }^{0},u_{\mu }^1\} \subset D(A)$ such that
\begin{equation} \label{e13}
u_{\mu }^{0}\to u^{0}\text{ in }H_{\Gamma _0}^1(\Omega )\quad
\text{and}\quad u_{\mu }^1\to u^1\text{ in }L^2(\Omega )\quad
\text{as }\mu \to +\infty .
\end{equation}
Thus, $\{ u_{\mu }^{0},u_{\mu }^1\}$ satisfies, for all 
$\mu \in \mathbb{N}$ the compatibility conditions
\begin{equation*}
\frac{\partial u_{\mu }^{0}}{\partial \nu }+\frac{1}{\mu }u_{\mu}^1
+f_{1,\mu }(u_{\mu }^{0})=0,
\end{equation*}
 where $\beta $ is chosen equal to $1/\mu$ and 
$f_{1,\mu }(s)$ is the sequance of Lipschitz continuous (truncated) 
functions defined by
\begin{equation} \label{e14}
f_{1,\mu }(s):=\begin{cases}
|s| ^{\rho }s,\quad | s| <\mu \\
|\mu| ^{\rho }\mu ,\quad s\geq \mu \\
|-\mu| ^{\rho }(-\mu ),\quad s\leq -\mu .
\end{cases}
\end{equation}
Initially, we consider regular solutions to the auxiliary problem
\begin{equation} \label{e15}
\begin{gathered}
u_{tt}^n-\alpha \Delta u^n+k(0)u_t^n+\int_0^{t}k'(t-s)u_t^n(x,s)ds=0
\quad \text{in }\Omega \times (0,+\infty ) \\
u^n(x,t)=0,\quad x\in \Gamma _0 \\
\frac{\partial u^n}{\partial \nu }+\frac{1}{n}u_t^n+f_{1,n}(u^n)=0
\quad \text{on }\Gamma _1\times (0,+\infty ) \\
u^n(x,0)=u_0^n(x),\quad u_t^n(x,0)=u_1^n(x),\quad x\in \Omega .
\end{gathered}
\end{equation}
We obtain a sequence of regular solutions to problem \eqref{e15} which will
converge, as $n$ approaches infinity, to a desired weak solution
 ($\{u^{0},u^1\}\in H_{\Gamma _0}^1(\Omega )\times L^2(\Omega )$). The
procedure described above can be followed \emph{verbatim} as considered in 
\cite{c1} and therefore will be omitted. It is important to be mentioned that
while problem \eqref{e15} possesses a unique solution, the uniqueness of the limit
problem, namely
\begin{equation} \label{e16}
\begin{gathered}
u_{tt}-\alpha \Delta u+k(0)u_t+\int_0^{t}k'(t-s)u_t(x,s)ds=0\quad
\text{in }\Omega \times (0,+\infty ) \\
u(x,t)=0,\quad x\in \Gamma _0 \\
\frac{\partial u}{\partial \nu }+| u| ^{\rho }u=0\quad
\text{on }\Gamma _1\times (0,+\infty ) \\
u(x,0)=u_0(x),\quad u_t(x,0)=u_1(x),\quad x\in \Omega .
\end{gathered}
\end{equation}
is lost because of the nonlinear boundary term $| u|^{\rho }u$.
 Of course for Dirichlet or Neumann homogeneous boundary
conditions the uniqueness is recovered.

The main task of this work,  is to prove the exponential
stability of problem \eqref{e15}. Namely, we would like to have
\begin{equation} \label{e17}
E_{n}(t)\leq CE_{n}(0)e^{-\omega \,t},
\end{equation}
where $E_{n}(t)$ is the energy associated with \eqref{e15} and the
constants $C$ and $\omega $ do not depend on $n$. So, using denseness
arguments as considered in \cite{c1,l1}, we can pass to the limit in
\eqref{e17}  to obtain the desired exponential decay rate for those
weak solutions that are limit of regular solutions of problem 
\eqref{e15}.
Evidently the procedure is valid for any weak solution if $u=0$ or
 $\partial_{\nu }u=0$ on $\Gamma $.

\section{Preliminaries}

In this section we present some material needed in the proof of our result.
We will us the following assumptions:
\begin{itemize}
\item[(G1)] $k',k''':[0,\infty )\to \mathbb{R}^{+}$ with $k(0)>0$.

\item[(G2)]  $k'':[0,\infty )\to \mathbb{R}^{-}$ with $k''(0)<0$.

\item[(G3)] There exist two positive constants $\zeta _1$ and
 $\zeta_2 $ such that
\begin{equation*}
k''\leq -\zeta _1k'\quad \text{and}\quad k'''\geq -\zeta _2k''.
\end{equation*}
\end{itemize}

An example of function $k$ satisfying
(G1)--(G3) is $k(t)=a-e^{-bt}$, where $a>1$, $b>0$.

 \begin{lemma}[Poincar\'e] \label{lem2.1}
There exists a positive constant $\beta (\Omega )$ such that
\begin{equation*}
| u| _2^2\leq \beta | \nabla u|_2^2,\quad \forall u\in H_{\Gamma _0}^1(\Omega ).
\end{equation*}
\end{lemma}

Our main task is concerned with the asymptotic behavior of solutions to the
 problem
\begin{equation} \label{e18}
\begin{gathered}
u_{tt}-\alpha \Delta u+k(0)u_t+\int_0^{t}k'(t-s)u_t(x,s)ds=0,\quad x\in \Omega ,
\;t>0, \\
u(x,t)=0,\quad x\in \Gamma _0, \\
\frac{\partial u}{\partial \nu }+\frac{1}{n}u_t+b|
u| ^{\rho }u=0\quad \text{ on }\Gamma _1, \\
u(x,0)=u_0(x),\quad u_t(x,0)=u_1(x),\quad x\in \Omega .
\end{gathered}
\end{equation}
where $\Omega $ is a bounded domain in $\mathbb{R}^n$ with a
smooth boundary $\partial \Omega =\Gamma _0\cup \Gamma _1$, $\alpha >0$
and $k(t)\in C^{3}(\mathbb{R}^{+})$ satisfying {\rm (G1)--(G3)}. Once
 exponential stability for \eqref{e18} is established,
then the same technique is used for viscoelastic diffusion problem
\begin{equation} \label{e19}
\begin{gathered}
u_t-\int_0^{t}g(t-\tau )\Delta u(\tau )\,d\tau =0,\quad x\in \Omega ,\; t>0, \\
u(x,t)=0,\quad x\in \Gamma _0, \\
\frac{\partial u}{\partial \nu }+b| u| ^{\rho }u=0
\quad \text{on }\Gamma _1, \\
u(x,0)=u_0(x),\quad u_t(x,0)=0,\quad x\in \Omega ,
\end{gathered}
\end{equation}
obtained by denseness arguments, having in mind the comments established in
section 1. Of course this is not true for all weak solutions of \eqref{e19} unless
we have $u=0$ or $\partial _{\nu }u=0$ on $\Gamma $.

After integrating by parts the last term in \eqref{e18}, we obtain
\begin{equation} \label{e20}
\begin{gathered}
u_{tt}-\alpha \Delta u+k(0)u_t+k'(0)u(t)-k'(t)u_0 \\
+\int_0^{t}k''(t-s)u(x,s)ds=0,\quad x\in \Omega ,
\; t>0, \\
u(x,t)=0,\quad x\in \Gamma _0, \\
\frac{\partial u}{\partial \nu }+\frac{1}{n}u_t+b|u| ^{\rho }u=0
\quad \text{on }\Gamma _1, \\
u(x,0)=u_0(x),\quad u_t(x,0)=u_1(x),\quad x\in \Omega .
\end{gathered}
\end{equation}

 The modified energy functional associated with \eqref{e20} is
\begin{align*}
E(t) &= \frac{1}{2}\int_{\Omega }u_t^2dx+\frac{\alpha }{2}\int_{\Omega
}| \nabla u| ^2dx+\frac{1}{2}k'(t)\int_{\Omega
}\left( u(x,t)-u_0(x)\right) ^2dx \\
&\quad -\frac{1}{2}\int_{\Omega }\int_0^{t}k''(t-s)\left(
u(x,s)-u(x,t)\right) ^2\,ds\,dx
+\frac{\alpha b}{\rho +2}\int_{\Gamma_1}| u| ^{\rho +2}dx.
\end{align*}

\section{Decay of solutions}

 In this section we state and prove our main result. For this
purpose, we set
\begin{equation} \label{e21}
F(t)=E(t)+\varepsilon \varphi (t),\quad t\geq 0,
\end{equation}
where $\varepsilon $ is a positive constant and
\begin{equation} \label{e22}
\varphi (t)=\int_{\Omega }u_tu\,dx+\frac{k(0)}{2}\int_{\Omega }u^2dx+\frac{
\alpha }{2n}\int_{\Gamma _1}u^2dx,
\end{equation}

 \begin{lemma} \label{lem3.1}
The modified energy satisfies,
along the solution of \eqref{e20},
\begin{align*}
E'(t) &= -k(0)\int_{\Omega }u_t^2dx+\frac{1}{2}k''(t)\int_{\Omega }\left( u(x,t)-u_0(x)\right) ^2\,ds\,dx \\
&\quad -\frac{1}{2}\int_{\Omega }\int_0^{t}k^{'''}(t-s)
\left( u(x,s)-u(x,t)\right) ^2\,ds\,dx-\frac{\alpha }{n}\int_{\Gamma
_1}| u_t| ^2dx\leq 0.
\end{align*}
\end{lemma}

\begin{proof}
Multiplying \eqref{e20} by $u_t$ and integrating
over $\Omega $, using integration by parts, hypotheses (G1) and (G2) and
some manipulations as in \cite{c1} , we obtain the
result for any regular solution. This result remains valid for any
``limit weak'' solution (not for all weak
solutions) by a simple denseness argument.
\end{proof}

 \begin{lemma} \label{lem3.2}
 For $\varepsilon >0$ small enough, we have
\begin{equation*}
| F(t)-E(t)| \leq \varepsilon \lambda E(t),\quad t\geq 0,
\end{equation*}
where $\lambda $ is a constant independent of $\varepsilon $
 and $n$.
\end{lemma}

\begin{proof} 
Using the Poincar\'{e} and the Cauchy-Schwarz
inequalities, we obtain
\begin{align*}
| \varepsilon \varphi (t)| 
&\leq \frac{\varepsilon }{2}
\int_{\Omega }u_t^2dx+\frac{\varepsilon }{2}( 1+k(0))
\int_{\Omega }u^2dx++\frac{\varepsilon \alpha }{2n}\int_{\Gamma
_1}u^2dx \\
&\leq \frac{\varepsilon }{2}\int_{\Omega }u_t^2dx+\frac{\varepsilon
\left( 1+k(0)+\frac{\alpha }{n}\right) \beta }{2}\int_{\Omega }|
\nabla u| ^2dx \\
&\leq \frac{\varepsilon }{2}\int_{\Omega }u_t^2dx+\frac{\varepsilon
\left( 1+k(0)+\alpha \right) \beta }{2}\int_{\Omega }| \nabla
u| ^2dx\leq \lambda \varepsilon E(t),
\end{align*}
where $\beta $ is the Poincar\'{e} constant and
\begin{equation*}
\lambda =\max \left\{ 1,\frac{\left( 1+k(0)+\alpha \right) \beta }{\alpha }
\right\} .
\end{equation*}
Then from \eqref{e21}, it follows that
\begin{equation} \label{e23}
| F(t)-E(t)| \leq \varepsilon \lambda E(t),\quad t\geq 0.
\end{equation}
\end{proof}

 \begin{lemma} \label{lem3.3}
Under  assumptions{\rm  (G1)--(G2)}, the
functional $\varphi (t)$ satisfies,  along the solution of
\eqref{e20} and for any $\delta >0$,
\begin{equation} \label{e24}
\begin{aligned}
\varphi '(t) 
&\leq \int_{\Omega }u_t^2dx-\left( \alpha -\delta
\beta [ k'(t)+1]\right) \int_{\Omega }| \nabla
u| ^2dx-\alpha b\int_{\Gamma _1}| u| ^{\rho +2}dx \\
&\quad -\frac{k'(0)}{4\delta }\int_{\Omega }\int_0^{t}k''(t-s)
 \left( u(s)-u(t)\right) ^2\,ds\,dx+\frac{k'(t)}{4\delta }
\int_{\Omega }\left( u(t)-u_0(x)\right) ^2dx.  
\end{aligned}
\end{equation}
\end{lemma}

\begin{proof} 
Differentiation of \eqref{e22}, using \eqref{e20},
yields
\begin{equation} \label{e25}
\begin{split}
\varphi '(t)
&= \int_{\Omega }u_t^2dx-\alpha \int_{\Omega }| \nabla u| ^2dx-k'(0)
\int_{\Omega}u^2dx-\alpha b\int_{\Gamma _1}| u| ^{\rho +2}dx
 \\
&\quad +k'(t)\int_{\Omega }u_0(x)u(t)dx-\int_{\Omega}u(t)\int_0^{t}
k''(t-s)u(s)\,ds\,dx.
\end{split}
\end{equation}
 Using Young's, Cauchy-Schwarz's, Poincar\'{e}'s and H
\"{o}lder's inequalities, the last two terms in \eqref{e25} can be estimated as
follows
\begin{equation} \label{e26}
\begin{aligned}
&k'(t)\int_{\Omega }u_0(x)u(t)dx \\
&= k'(t)\int_{\Omega}\left( u_0(x)-u(t)+u(t)\right) u(t)dx   \\
&= k'(t)\int_{\Omega }\left( u_0(x)-u(t)\right) u(t)dx+k'(t)\int_{\Omega }u^2(t)dx \\
&\leq \frac{k'(t)}{4\delta }\int_{\Omega }\left(u(t)-u_0(x)\right) ^2dx
+\delta k'(t)\int_{\Omega }u^2(t)dx+k'(t)\int_{\Omega }u^2dx   \\
&\leq \frac{k'(t)}{4\delta }\int_{\Omega }\left(u(t)-u_0(x)\right) ^2dx
+\left( \delta +1\right) k'(t)\int_{\Omega }u^2dx
\end{aligned}
\end{equation}
 and
\begin{equation} \label{e27}
\begin{aligned}
&-\int_{\Omega }u(t)\int_0^{t}k''(t-s)u(s)\,ds\,dx
 \\
&= -\int_{\Omega }u(t)\int_0^{t}k''(t-s)[ \big(
u(s)-u(t)\big) +u(t)] \,ds\,dx   \\
&= -\int_{\Omega }u(t)\int_0^{t}k''(t-s)\left(
u(s)-u(t)\right) \,ds\,dx-\int_{\Omega }u^2(t)\int_0^{t}k''(t-s)\,ds\,dx \\
&\leq \delta \int_{\Omega }u^2(t)dx+\frac{1}{4\delta }\int_{\Omega
}\Big( \int_0^{t}k''(t-s)\left( u(s)-u(t)\right) ds\Big)^2dx\\
&\quad -\int_{\Omega }u^2(t)\int_0^{t}k''(t-s)\,ds\,dx
\\
&\leq \delta \int_{\Omega }u^2(t)dx+\frac{k'(0)}{4\delta }
\int_{\Omega }\int_0^{t}-k''(t-s)\left( u(s)-u(t)\right)
^2\,ds\,dx\\
&\quad +k'(0)\int_{\Omega }u^2dx-k'(t)\int_{\Omega}u^2dx  
 \\
&\leq -\frac{k'(0)}{4\delta }\int_{\Omega }\int_0^{t}k''(t-s)
\left( u(s)-u(t)\right) ^2\,ds\,dx+[ \delta +k'(0)-k'(t)]
 \int_{\Omega }u^2dx.
\end{aligned}
\end{equation}
 Combining \eqref{e25}-\eqref{e27}, the result in \eqref{e24} follows.
\end{proof}

At this point, we state and prove our main result.

 \begin{theorem} \label{thm3.1}
Assume that {\rm (G1)--(G3)} hold, and let 
$(u_0,u_1)\in H_{\Gamma _0}^1(\Omega )\times L^2(\Omega )$.
Then, there exist two positive constants $C$ and $\omega$,
independent of $n$, such that the limit weak solution of \eqref{e20}
 satisfies, for all $t\geq 0$,
\begin{equation*}
E(t)\leq CE(0)e^{-\omega t}.
\end{equation*}
\end{theorem}

\begin{proof} 
Using Lemmas  \ref{lem3.1} and \ref{lem3.3},  we have
\begin{equation} \label{e28}
\begin{aligned}
F'(t)
&= E'(t)+\varepsilon \varphi '(t) \\
&\leq -\left( k(0)-\varepsilon \right) \int_{\Omega
}u_t^2dx-\varepsilon \left( \alpha -\delta \beta [ k'(t)+1]\right)
 \int_{\Omega }| \nabla u| ^2dx   \\
&\quad -\varepsilon \frac{k'(0)}{4\delta }\int_{\Omega
}\int_0^{t}k''(t-s)\left( u(s)-u(t)\right) ^2\,ds\,dx \\
&\quad -\frac{1}{2}\int_{\Omega }\int_0^{t}k'''(t-s)\left(
u(s)-u(t)\right) ^2\,ds\,dx-\varepsilon \alpha b\int_{\Gamma _1}|
u| ^{\rho +2}dx   \\
&\quad +\left( \frac{k''(t)}{2}+\varepsilon \frac{k'(t)}{
4\delta }\right) \int_{\Omega }\left( u(t)-u_0(x)\right) ^2dx-\frac{
\alpha }{n}\int_{\Gamma _1}| u_t| ^2dx.
\end{aligned}
\end{equation}
 Using (G3), \eqref{e28}, and $k'(t)\leq k'(0)$, and
dropping the last term, we arrive at
\begin{equation} \label{e29}
\begin{aligned}
F'(t)
&\leq -\left( k(0)-\varepsilon \right) \int_{\Omega
}u_t^2dx-\varepsilon \left( \alpha -\delta \beta [ k'(0)+1]\right)
\int_{\Omega }| \nabla u| ^2dx   \\
&\quad +\left( \frac{\zeta _2}{2}-\varepsilon \frac{k'(0)}{4\delta }
\right) \int_{\Omega }\int_0^{t}k''(t-s)\left(
u(s)-u(t)\right) ^2\,ds\,dx   \\
&\quad -k'(t)\left( \frac{\zeta _1}{2}-\varepsilon \frac{1}{4\delta }
\right) \int_{\Omega }\left( u(t)-u_0(x)\right) ^2dx-\varepsilon \alpha
\int_{\Gamma _1}| u| ^{\rho +2}dx.
\end{aligned}
\end{equation}
 Now, we choose $\delta $ such that
\begin{equation*}
\delta <\frac{\alpha }{\beta \left( k'(0)+1\right) }.
\end{equation*}

 Whence $\delta $ is fixed, we select $\varepsilon $ satisfying
\begin{equation*}
\varepsilon <\min \{ k(0),\frac{2\delta \zeta _2}{k'(0)}
,2\delta \zeta _1,\frac{1}{\lambda }\} ,
\end{equation*}
hence \eqref{e29} yields, for some $c>0$,
\begin{equation} \label{e30}
F'(t)\leq -cE(t),\quad \forall t\geq 0.
\end{equation}
Also \eqref{e23} leads to
\begin{equation*}
( 1-\lambda \varepsilon ) E(t)\leq F(t)\leq ( 1+\lambda
\varepsilon ) E(t),\quad \forall t\geq 0.
\end{equation*}
 Consequently, for any $0<\gamma \leq $ $1-\lambda
\varepsilon $, we have
\begin{equation} \label{e31}
\gamma E(t)\leq F(t)\leq \left( 2-\gamma \right) E(t),\quad \forall t\geq 0.
\end{equation}
Inserting \eqref{e31} in \eqref{e30}, we obtain
\begin{equation*}
F'(t)\leq -\frac{c}{2-\gamma }F(t)=-\omega F(t),\quad \forall
t\geq 0,
\end{equation*}
 where $\omega =\frac{c}{2-\gamma }$.
 A direct integration yields
\begin{equation*}
F(t)\leq F(0)e^{-\omega t},\quad \forall t\geq 0.
\end{equation*}
 Using \eqref{e31} again gives
\begin{equation*}
E(t)\leq \frac{1}{\gamma }F(t)\leq \frac{1}{\gamma }F(0)e^{-\omega t}\leq
\frac{2-\gamma }{\gamma }E(0)e^{-\omega t}=CE(0)e^{-\omega t},\quad \forall
t\geq 0.
\end{equation*}
This completes the proof.
\end{proof}

 \subsection*{Acknowledgments}
The author wants  to express his
sincere thanks to King Fahd University of Petroleum and Minerals for its
support.

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