\documentclass[reqno]{amsart} \usepackage{hyperref} \AtBeginDocument{{\noindent\small \emph{Electronic Journal of Differential Equations}, Vol. 2016 (2016), No. 197, pp. 1--19.\newline ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu} \thanks{\copyright 2016 Texas State University.} \vspace{8mm}} \begin{document} \title[\hfilneg EJDE-2016/197\hfil Existence and multiplicity of solutions] {Existence and multiplicity of solutions for a Dirichlet problem involving perturbed $p(x)$-Laplacian operator} \author[A. Abdou, A. Marcos \hfil EJDE-2016/197\hfilneg] {Aboubacar Abdou, Aboubacar Marcos} \address{Aboubacar Abdou \newline Institut de Math\'ematiques et de Sciences Physiques, Universit\'e d'Abomey Calavi, 01 BP: 613 Porto-Novo, B\'enin} \email{aboubacar.abdou@imsp-uac.org, abdou.aboubacar@ymail.com} \address{Aboubacar Marcos \newline Institut de Math\'ematiques et de Sciences Physiques, Universit\'e d'Abomey Calavi, 01 BP: 613 Porto-Novo, B\'enin} \email{abmarcos@imsp-uac.org, abmarcos@yahoo.fr} \thanks{Submitted December 18, 2015. Published July 24, 2016.} \subjclass[2010]{35B38, 35J20, 35J60, 35J66, 58E05} \keywords{$p(x)$-Laplacian operator; generalized Lebesgue-Sobolev spaces; \hfill\break\indent critical point; Fountain theorem; dual Fountain theorem} \begin{abstract} In this article we study the existence of solutions for the Dirichlet problem \begin{gather*} -\operatorname{div}(| \nabla u |^{p(x)-2}\nabla u)+V(x)|u|^{q(x)-2}u =f(x,u)\quad \text{in }\Omega,\\ u=0\quad \text{on }\partial \Omega, \end{gather*} where $\Omega$ is a smooth bounded domain in $\mathbb{R}^N$, $V$ is a given function in a generalized Lebesgue space $L^{s(x)}(\Omega)$ and $f(x,u)$ is a Carath\'eodory function which satisfies some growth condition. Using variational arguments based on ``Fountain theorem" and ``Dual Fountain theorem", we shall prove under appropriate conditions on the above nonhomogeneous quasilinear problem the existence of two sequences of weak solutions for this problem. \end{abstract} \maketitle \numberwithin{equation}{section} \newtheorem{theorem}{Theorem}[section] \newtheorem{lemma}[theorem]{Lemma} \newtheorem{proposition}[theorem]{Proposition} \newtheorem{remark}[theorem]{Remark} \newtheorem{definition}[theorem]{Definition} \allowdisplaybreaks \section{Introduction} In this work we study the existence of multiple solutions for a nonlinear Dirichlet problem involving the $p(x)$-Laplacian operator, \begin{equation}\label{s} \begin{gathered} -\Delta_{p(x)}u+V(x)|u|^{q(x)-2}u=f(x,u) \quad \text{in } \Omega, \\ u=0 \quad \text{on } \partial \Omega, \end{gathered} \end{equation} where $\Omega \subset \mathbb{R}^N$ is a smooth bounded domain, $p,q,s:\overline {\Omega}\to \mathbb{R}$ are continuous functions, $V\in L^{s(x)}(\Omega)$ and $f(x,u)$ is a Carath\'eodory function. Here, the $p(x)$-Laplacian operator is given by $\Delta_{p(x)}u=\operatorname {div}(| \nabla u |^{p(x)-2} \nabla u)$, which is a generalization of the usual $p$-Laplacian operator. Nonlinear boundary value problems with variable exponent have received considerable attention in recent years. This is partly due to their frequent appearance in applications such as the modeling of electrorheological fluids \cite{TG,MR,ZK}, elastic mechanics, flow in porous media and image processing \cite{CL}, but these problems are very interesting from a purely mathematical point of view as well. The main interest in studying such problems arises from the presence of the $p(x)$-Laplacian operator which is a natural extension of the classical $p$-Laplacian operator $\operatorname {div}(| \nabla u |^{p-2}\nabla u)$ obtained in the case where $p(x)\equiv p$ is a positive constant. However, such generalizations are not trivial since the $p(x)$-Laplacian operator possesses a more complicated structure than the $p$-Laplacian operator, for example, it is inhomogeneous. Many authors have studied problems with variable exponent, we refer for example to the works in \cite{JY,FZ,FZH,FH,PSI1,PSI2,KK,LWZ} and references therein. When $p(x)\equiv p$ is a constant and $V\equiv0$, Dinca et al. \cite{GD}, using variational and topological methods, proved the existence and multiplicity of weak solutions for the following Dirichlet problem with $p$-Laplacian \[ -\Delta_pu=f(x,u)\text{ in } \Omega,\quad u=0 \text{ on }\partial \Omega, \] where $f(x,u)$ is a Carath\'eodory function which satisfies some growth condition. The main tool in their work was the well known ``Mountain Pass theorem" of Ambrosetti and Rabinowitz. Fan and Zhang \cite{FZH} studied the variable exponent case with $V\equiv0$ \[ -\Delta_{p(x)}u=f(x,u)\text{ in } \Omega,\quad u=0\text{ on }\partial \Omega, \] where $f(x,u)$ is a Carath\'eodory function which satisfies some subcritical growth condition. By the ``Mountain Pass lemma", the authors showed that the considered problem admits at least one nontrivial weak solution and, by the ``Fountain theorem", the infinite many pairs of weak solutions. In \cite{PSI1}, Ilia\c{s} considered the Dirichlet problem as in \cite{FZH} under some more general conditions on the Carath\'eodory function. Using ``Fountain theorem" and ``Dual Fountain theorem", the existence of two different sequences of weak solutions was proved. Chabrowski and Fu \cite{JY} established in the superlinear and sublinear cases the existence of nontrivial nonnegative weak solutions for the Dirichlet problem \[ -\operatorname {div}(a(x)| \nabla u |^{p(x)-2}\nabla u) +b(x)|u|^{p(x)-2}u=f(x,u)\text{ in } \Omega,\quad u=0\text{ on }\partial \Omega, \] where $\Omega$ is a bounded domain in $\mathbb{R}^N$, $a(x)$ and $b(x)$ are positive functions in $L^\infty(\Omega)$, the continuous function $p(x)$ satisfies $1
1 \text{ for every }
x\in \overline{\Omega} \}, \\
p^-=\min_{x\in \overline{\Omega}}p(x), \quad
p^+=\max_{x\in \overline{\Omega} }p(x), \quad
\text{for }p\in C_+(\overline{\Omega}),\\
M=\{ u:\Omega \to \mathbb{R} : u \text{ is a measurable real-valued
function} \}.
\end{gather*}
\begin{definition} \label{def2.1} \rm
The variable exponent Lebesgue space $L^{p(x)}(\Omega)$ is defined by
$$
L^{p(x)}(\Omega)=\big\{ u \in M: \int_\Omega | u |^{p(x)}dx <+\infty \big\},
$$
endowed with the so-called Luxemburg norm
$$
| u |_{p(x)}=\inf \big\{ \lambda>0: \int_\Omega | \frac{u}
{\lambda}|^{p(x)}dx \leq 1 \big\}.
$$
\end{definition}
\begin{remark} \label{rmk} \rm
Variable exponent Lebesgue spaces resemble to classical Lebesgue spaces in many
respects, they are separable Banach spaces and the H\"{o}lder inequality holds.
The inclusions between Lebesgue spaces are also naturally generalized, that is,
if $0 0,\quad \text{ for all }
u\neq v \in W_0^{1,p(x)}(\Omega).
$$
\item[(iii)] $-\Delta_{p(x)}:W_0^{1,p(x)}(\Omega)\to W^{-1,p'(x)}(\Omega)$ is
a mapping of type $(S_+)$, that is,
$$\text{ if } u_n \rightharpoonup u \text{ in }W_0^{1,p(x)}(\Omega)
\text{ and } \limsup_{n\to \infty}\langle -\Delta_{p(x)}u_n,u_n-u \rangle
\leq 0,$$
then $u_n\to u$ in $W_0^{1,p(x)}(\Omega)$.
\end{itemize}
\end{proposition}
\begin{proposition}[Chang \cite{KC}]\label{fcn}
The functional $\Psi:W_0^{1,p(x)}(\Omega)\to \mathbb{R}$ defined by
$$\Psi(u)=\int_\Omega \frac{1}{p(x)}|\nabla u|^{p(x)}dx$$
is continuously Fr\'echet differentiable and $\Psi'(u)=-\Delta_{p(x)}u$, for
all $u\in W_0^{1,p(x)}(\Omega)$.
\end{proposition}
We recall now some basic results concerning the Nemytskii operator. Note that,
if $f:\Omega \times \mathbb{R}\to \mathbb{R}$ is a Carath\'eodory
function and $u\in M$, then the function $N_fu:\Omega \to \mathbb{R}$
defined by $(N_fu)(x)=f(x,u(x))$ for $x\in \Omega$ is measurable in $\Omega$.
Thus, the Carath\'eodory function $f:\Omega \times \mathbb{R}\to \mathbb{R}$
generates an operator $N_f:M\to M$, which is called the Nemytskii operator.
The propositions below give the properties of $N_f$.
\begin{proposition}[Zhao and Fan \cite{ZF}]\label{cara1}
Suppose that $f:\Omega \times \mathbb{R}\to \mathbb{R}$ is a Carath\'eo\-dory
function and satisfies the growth condition
$$
|f(x,t)|\leq c|t|^{\frac{\alpha(x)}{\beta(x)}}+h(x),\quad \text{for every }x\in
\Omega,\ t\in \mathbb{R},
$$
where $\alpha,\beta \in C_+(\overline{\Omega})$, $c\geq 0$ is constant and
$h\in L^{\beta(x)}(\Omega)$. Then
$N_f(L^{\alpha(x)}(\Omega))\subseteq L^{\beta(x)}
(\Omega)$. Moreover, $N_f$ is continuous from $L^{\alpha(x)}(\Omega)$ into
$L^{\beta(x)}(\Omega)$ and maps bounded set into bounded set.
\end{proposition}
\begin{proposition}[Zhao and Fan \cite{ZF}]\label{cara2}
Suppose that $f:\Omega \times \mathbb{R}\to \mathbb{R}$ is a Carath\'eo\-dory
function and satisfies the growth condition
$$
|f(x,t)|\leq c|t|^{\alpha(x)-1}+h(x),\quad \text{for every }x\in \Omega,\; t\in
\mathbb{R},
$$
where $c\geq0$ is constant, $\alpha,\beta \in C_+(\overline{\Omega})$,
$h\in L^{\beta(x)}
(\Omega)$ with $\beta$ the conjugate exponent of $\alpha$, i.e., $\beta(x)=\frac{\alpha(x)}
{\alpha(x)-1}$. Let $F:\Omega \times \mathbb{R}\to \mathbb{R}$ defined by
$$F(x,t)=\int_0^tf(x,s)ds .$$
Then
\begin{itemize}
\item[(i)] $F$ is a Carath\'eodory function and there exist a constant
$c_1\geq0$ and $\sigma \in L^1(\Omega)$ such that
$$
|F(x,t)|\leq c_1|t|^{\alpha(x)}+\sigma(x),\quad \text{ for all }x\in \Omega,\
t\in \mathbb{R}.
$$
\item[(ii)] The functional $\Phi:L^{\alpha(x)}(\Omega)\to \mathbb{R}$
defined by $\Phi(u)=\int_\Omega F(x,u(x))dx$ is continuously Fr\'echet
differentiable and $\Phi'(u)=N_f(u),\text{ for all }u\in L^{\alpha(x)}(\Omega)$.
\end{itemize}
\end{proposition}
\begin{remark} \label{rmk2.16} \rm
In Proposition \ref{cara2} if we take $\alpha \in C_+(\overline{\Omega})$ with
$\alpha(x) 0$ such that
$$
0<\theta F(x,s) \leq sf(x,s) ,\quad \text{for }x\in \Omega,\; s\in \mathbb{R}
\text{ with } |s|\geq M,
$$
where $ F(x,s)=\int_0^sf(x,t)dt$.
\item[(A4)] $f(x,-t)=-f(x,t)$ for $x\in \Omega$, $s\in \mathbb{R}$.
\item[(A5)] $\beta^->p^+$.
\end{itemize}
\section{Proofs of main results and auxiliary results}
In this section, we investigate some auxiliary results which allow us to prove
our main results. Here and henceforth, we denote by $X$ the generalized Sobolev
space $W_0^{1,p(x)}(\Omega)$ equipped with the norm $\| \cdotp \|$, $X^*$
its dual space, $s'(x)$ the conjugate exponent of the function $s(x)$ and we
define a continuous function
$$
\alpha(x)=\frac{s(x)q(x)}{s(x)-q(x)}.
$$
By assumptions (A1), (A2) on the functions $p, q, s$ and $\beta$, a straightforward
computation gives
$$
q(x) 1$.
\end{remark}
By a solution of problem \eqref{s}, we mean a weak solution which satisfies
the following condition.
\begin{definition} \label{def3.2} \rm
We say that $u\in X$ is a weak solution of \eqref{s} if
\begin{equation}\label{WS}
\int_\Omega |\nabla u|^{p(x)-2}\nabla u \nabla vdx
+\int_\Omega V(x)|u|^{q(x)-2}uvdx
=\int_\Omega f(x,u)vdx,\ \forall \ v\in X.
\end{equation}
\end{definition}
Let us consider the Euler-Lagrange functional or the energy functional
$H:X\to \mathbb{R}$ associated with problem \eqref{s} defined by
$$
H(u)= \int_\Omega \frac{1}{p(x)} |\nabla u|^{p(x)}dx
+\int_\Omega \frac{V(x)} {q(x)}|u|^{q(x)}dx-\int_\Omega F(x,u)dx .
$$
Let us introduce the functionals $\Psi,J,\Phi:X\to \mathbb{R}$
defined by
$$
\Psi(u)= \int_\Omega \frac{1}{p(x)} |\nabla u|^{p(x)}dx,\quad
J(u)=\int_\Omega \frac{V(x)}{q(x)}|u|^{q(x)}dx, \quad
\Phi(u)=\int_\Omega F(x,u)dx.
$$
Then, the energy functional $H$ can be written as
$$
H(u):=\Psi(u)+J(u)-\Phi(u).
$$
The functional $J$ is well defined. Indeed, using H\"{o}lder inequality and
Proposition \ref{NR}, for all $u\in X$, we have
$$
|J(u)|\leq \frac{2}{q^-}|V|_{s(x)}||u|^{q(x)}|_{s'(x)}\leq \frac{2}{q^-}
|V|_{s(x)}\max \{|u|_{s'(x)q(x)}^{q^-},|u|_{s'(x)q(x)}^{q^+}\}.
$$
We have the following result concerning the regularity of the functional $H$.
\begin{proposition}\label{reg}
The functional $H \in C^1(X,\mathbb{R})$, i.e., $H$ is continuously Fr\'echet
differentiable. Moreover, $u \in X$ is a critical point
of $H$ if and only if $u$ is a weak solution of \eqref{s}.
\end{proposition}
\begin{proof}
By Proposition \ref{fcn} and Proposition \ref{cara2}, we know that $\Psi$
respectively $\Phi$ are of class $C^1(X,\mathbb{R})$ and their derivative
functions are given by
$$
\langle d\Psi(u),v \rangle=\int_\Omega |\nabla u|^{p(x)-2}\nabla u \nabla
vdx \text{ and } \langle d\Phi(u),v \rangle=\int_\Omega f(x,u)vdx,
$$
for all $u,v\in X$. It is also well known (see \cite{BK,KK}) that the functional
$J$ is of class $C^1(X,\mathbb{R})$ and its derivative is given by
$$
\langle dJ(u),v\rangle=\int_\Omega V(x)|u|^{q(x)-2}uvdx,\quad \text{for all }
u,v\in X.
$$
Therefore, the functional $H \in C^1(X,\mathbb{R})$ and its derivative function
is given by
$$
\langle dH(u),v \rangle=\int_\Omega |\nabla u|^{p(x)-2}\nabla u \nabla vdx+
\int_\Omega V(x)|u|^{q(x)-2}uvdx -\int_\Omega f(x,u)vdx,
$$
for all $u,v\in X$.
Now, let $u$ be a critical point of $H$, then we have $dH(u)=0_{X^*}$, which
implies that
$$
\langle dH(u),v \rangle=0,\text{ for all }v\in X.
$$
Consequently,
$$
\int_\Omega |\nabla u|^{p(x)-2}\nabla u\nabla vdx+\int_\Omega
V(x)|u|^{q(x)-2}uvdx=\int_\Omega f(x,u)vdx,\ \forall \ v\in X.
$$
It follows that $u$ is a weak solution of \eqref{s}. On the other
hand, if $u$ is a weak solution of \eqref{s}, by definition, we have
$$
\int_\Omega |\nabla u|^{p(x)-2}\nabla u\nabla vdx+\int_\Omega
V(x)|u|^{q(x)-2}uvdx=\int_\Omega f(x,u)vdx,\ \forall \ v\in X,
$$
which implies that
$$
\langle dH(u),v \rangle=0,\text{ for all }v\in X.
$$
So, $dH(u)=0_{X^*}$ and hence $u$ is a critical point of $H$.
The proof is complete.
\end{proof}
\begin{remark}[see \cite{JFZ}]\label{rem2} \rm
As the Sobolev space $X=W^{1,p(x)}_0(\Omega)$ is a reflexive and separable Banach
space, there exist $(e_n)_{n\in \mathbb{N}^*}\subseteq X$
and $(f_n)_{n\in \mathbb{N}^*}\subseteq X^*$ such that $f_n(e_m)=\delta_{nm}$ for
any $n,m\in \mathbb{N}^*$ and
$$
X=\overline{\operatorname{span}\{ e_n: n\in \mathbb{N}^*
\}},\quad X^*=\overline{\operatorname{span}\{ f_n: n\in \mathbb{N}^* \}}^{w^*}.
$$
\end{remark}
For $k\in \mathbb{N}^*$ denote by
$$
X_k=\operatorname{span}\{ e_k \},\ Y_k=\oplus_{j=1}^k X_j, \quad
Z_k=\overline{\oplus_k^\infty X_j}.
$$
\begin{definition} \label{def3.5} \rm
We say that
\begin{itemize}
\item[(1)] The $C^1$-functional $H$ satisfies the Palais-Smale condition (in short
$(PS)$ condition) if any sequence $(u_n)_{n\in \mathbb{N}}\subseteq X$ for which,
$(H(u_n))_{n\in \mathbb{N}}\subseteq \mathbb{R}$ is bounded and $dH(u_n)\to 0$
as $n\to \infty$, has a convergent subsequence.
\item[(2)] The $C^1$-functional $H$ satisfies the Palais-Smale condition at
the level $c$ (in short $(PS)_c$ condition) for $c\in \mathbb{R}$ if any sequence
$(u_n)_{n\in \mathbb{N}}\subseteq X$ for which, $H(u_n)\to c$ and $dH(u_n)\to 0$
as $n\to \infty$, has a convergent subsequence.
\item[(3)] The $C^1$-functional $H$ satisfies the $(PS)_c^*$ condition for
$c\in \mathbb{R}$ if any sequence $(u_n)_{n\in \mathbb{N}}\subseteq X$ for which,
$u_n\in Y_n$ for each $n\in \mathbb{N}$, $H(u_n)\to c$ and $d(H_{|Y_n})(u_n)\to 0$
as $n\to \infty$ with $Y_n,\ n\in \mathbb{N}$ as defined in Remark \ref{rem2},
has a subsequence convergent to a critical point of $H$.
\end{itemize}
\end{definition}
\begin{remark} \label{rmk3.6} \rm
It is easy to see that if $H$ satisfies the $(PS)$ condition, then $H$ satisfies the
$(PS)_c$ condition for every $c\in \mathbb{R}$.
\end{remark}
Now, we state our main results of this work.
\begin{theorem}\label{cr1}
Under assumptions {\rm (A1)--(A5)}, problem \eqref{s}
has a sequence of weak solutions $(\pm u_n)_{n\in \mathbb{N}}\subseteq X$ such that
$H(\pm u_n)\to +\infty$ as $n\to \infty$.
\end{theorem}
\begin{theorem}\label{cr2}
Under assumptions {\rm (A1)--(A5)}, problem \eqref{s}
has a sequence of weak solutions $(\pm u_n)_{n\in \mathbb{N}}\subseteq X$ such that
$H(\pm u_n)\leq0$ for each $n\in \mathbb{N}$ and $H(\pm u_n)\to 0$ as $n\to \infty$.
\end{theorem}
The proofs of these above results will be based on a variational approach, using the
critical points theory, we shall prove that the $C^1$-functional $H$ has two different
sequences of critical values. The main tools for this end are ``Fountain theorem"
and ``Dual Fountain theorem" (see Willem \cite[Theorem 6.5]{MW})
which we give below.
\begin{theorem}[``Fountain theorem", \cite{MW}] \label{FT}
Let $X$ be a reflexive and separable Banach space, $I\in C^1(X,\mathbb{R})$
be an even functional and the subspaces $X_k, Y_k, Z_k$ as defined in remark
\ref{rem2}. If for each $k\in \mathbb{N}^*$ there exist $\rho_k>r_k>0$ such that
\begin{itemize}
\item[(1)] $\inf_{x\in Z_k, \| x\|=r_k}I(x)\to \infty \text{ as }k\to \infty$,
\item[(2)] $\max_{x\in Y_k, \| x\|=\rho_k}I(x)\leq0$,
\item[(3)] $I$ satisfies the $(PS)_c$ condition for every $c>0$.
\end{itemize}
Then $I$ has a sequence of critical values tending to $+\infty$.
\end{theorem}
\begin{theorem}[Dual Fountain theorem \cite{MW}]\label{DFT}
Let $X$ be a reflexive and separable Banach space, $I\in C^1(X,\mathbb{R})$
be an even functional and the subspaces $X_k, Y_k, Z_k$ as defined in remark
\ref{rem2}. Assume that there is a $k_0\in \mathbb{N}^*$ such that for each
$k\in \mathbb{N}^*$, $k\geq k_0$,
there exist $\rho_k>r_k>0$ such that
\begin{itemize}
\item[(1)] $\inf_{x\in Z_k,\ \| x\|=\rho_k}I(x)\geq0$,
\item[(2)] $b_k=\max_{x\in Y_k,\ \| x\|=r_k}I(x)<0$,
\item[(3)] $d_k=\inf_{x\in Z_k,\ \| x\| \leq \rho_k}I(x)\to 0 \text{ as }k\to
\infty$,
\item[(4)] $I$ satisfies the $(PS)_c^*$ condition for every $c\in [d_{k_0},0)$.
\end{itemize}
Then H has a sequence of negative critical values converging to 0.
\end{theorem}
We first prove that the functional $H$ satisfies $(PS)$ and $(PS)_c^*$ conditions.
\begin{lemma}\label{lem1}
Under assumptions {\rm(A1)--(A3)}, the functional $H$ satisfies the
$(PS)$ condition.
\end{lemma}
\begin{proof}
Let $(u_n)_{n\in \mathbb{N}}\subseteq X$ be a $(PS)$ sequence for $H$, i.e.,
$(H(u_n))_{n\in \mathbb{N}}\subseteq \mathbb{R}$ is bounded and
$dH(u_n)\to 0\text{ as }n\to \infty$. Then, there exists a positive constant
$k\in \mathbb{R}$ such that
\begin{equation}\label{bound}
|H(u_n)|\leq k,\text{ for every }n\in \mathbb{N}.
\end{equation}
For $n\in \mathbb{N}$, we denote by
$\Omega_n=\{x\in \Omega : |u_n(x)|\geq M \}\text{ and }\Omega'_n=\Omega
\backslash \Omega_n$,
with $M$ as in assumption (A3). Without any loss of generality, we can suppose
that $M\geq1$. By Proposition \ref{cara2} (i), there exist $c_1\geq0$ and
$\sigma \in L^1(\Omega)$ such that
\[
F(x,u_n(x)) \leq c_1|u_n(x)|^{\beta(x)}+\sigma(x)
\leq c_1M^{\beta^+}+\sigma(x),
\]
for every $x\in \Omega'_n$. Hence,
\begin{equation}\label{ps1}
\begin{aligned}
\int_{\Omega'_n} F(x,u_n(x))dx
& \leq \int_{\Omega'_n}(c_1M^{\beta^+}+\sigma(x))dx \\
& \leq \int_\Omega (c_1M^{\beta^+}+\sigma(x))dx \\
& = c_1M^{\beta^+}\operatorname{meas}(\Omega)+\int_\Omega \sigma(x)dx=k_1.
\end{aligned}
\end{equation}
Using hypothesis (A3),
$$
F(x,u_n(x))\leq \frac{1}{\theta}f(x,u_n(x))u_n(x),\quad \text{for all }x\in \Omega_n,
$$
which gives
\begin{equation}\label{ps2}
\begin{aligned}
&\int_{\Omega_n} F(x,u_n(x))dx \\
&\leq \frac{1}{\theta}
\int_{\Omega_n}f(x,u_n(x))u_n(x)dx \\
& = \frac{1}{\theta}\Big(\int_{\Omega}f(x,u_n(x))u_n(x)dx-
\int_{\Omega'_n}f(x,u_n(x))u_n(x)dx \Big).
\end{aligned}
\end{equation}
Using the growth condition in (A2),
\begin{align*}
\big| \int_{\Omega'_n}f(x,u_n(x))u_n(x)dx \big|
& \leq \int_{\Omega'_n}
(c|u_n(x)|^{\beta(x)}+h(x)|u_n(x)|)dx \\
& \leq cM^{\beta^+}\operatorname{meas}(\Omega'_n)+M\int_{\Omega'_n} h(x)dx \\
& \leq cM^{\beta^+}\operatorname{meas}(\Omega)+M\int_{\Omega}|h(x)|dx=k_2,
\end{align*}
which yields
\begin{equation}\label{ps3}
-\frac{1}{\theta}\int_{\Omega'_n}f(x,u_n(x))u_n(x)dx\leq \frac{k_2}{\theta}.
\end{equation}
For $n\in \mathbb{N}$, using H\"{o}lder inequality, Proposition \ref{NR} and
inequality \ref{3cst}, we can deduce that
\begin{equation}\label{ps4}
\begin{aligned}
\int_\Omega |V(x)||u_n|^{q(x)}dx
& \leq 2|V|_{s(x)}
\max \{|u_n|_{s'(x)q(x)}^{q^-},|u_n|_{s'(x)q(x)}^{q^+}\} \\
& \leq 2|V|_{s(x)}\max \{C^{q^-}\| u_n\|^{q^-},C^{q^+}\|
u_n\|^{q^+}\},
\end{aligned}
\end{equation}
where $C>1$ is a constant which appears in \eqref{3cst}.
Let us show that the sequence $(u_n)_{n\in \mathbb{N}}$ is bounded in $X$.
By contradiction, assume that $\| u_n\| \to +\infty \text{ as }
n \to \infty$. For each $n\in \mathbb{N}$ with $\| u_n\|>1$, using
inequalities \eqref{bound}, \eqref{ps1}, \eqref{ps2}, \eqref{ps3}
and \eqref{ps4}, the following holds
\begin{align*}
k+1
& \geq H(u_n)-\frac{1}{\theta}\langle dH(u_n),u_n \rangle+
\frac{1}{\theta}\langle dH(u_n),u_n \rangle \\
& = \int_\Omega \frac{1}{p(x)} |\nabla u_n|^{p(x)}dx+\int_\Omega
\frac{V(x)}{q(x)}|u_n|^{q(x)}dx-\int_\Omega F(x,u_n)dx \\
& \quad -\frac{1}{\theta}\left[\int_\Omega|\nabla u_n|^{p(x)}dx
+\int_\Omega V(x)|u_n|^{q(x)}dx -\int_\Omega f(x,u_n)u_ndx\right] \\
&\quad +\frac{1}{\theta}\langle dH(u_n),u_n \rangle \\
& = \int_\Omega \frac{1}{p(x)} |\nabla u_n|^{p(x)}dx+\int_\Omega
\frac{V(x)}{q(x)}|u_n|^{q(x)}dx-\int_{\Omega'_n} F(x,u_n)dx \\
&\quad -\int_{\Omega_n} F(x,u_n)dx-\frac{1}{\theta}\int_\Omega|\nabla
u_n|^{p(x)}dx-\frac{1}{\theta}\int_\Omega V(x)|u_n|^{q(x)}dx \\
&\quad +\frac{1}{\theta}\int_\Omega f(x,u_n)u_ndx+\frac{1}{\theta}
\langle dH(u_n),u_n \rangle \\
& \geq \frac{1}{p^+}\int_\Omega|\nabla u_n|^{p(x)}dx-\frac{1}{q^-}
\int_\Omega |V(x)||u_n|^{q(x)}dx-\int_{\Omega'_n} F(x,u_n)dx \\
&\quad -\frac{1}{\theta}\int_\Omega|\nabla u_n|^{p(x)}dx-\frac{1}{\theta}
\int_\Omega|V(x)||u_n|^{q(x)}dx+\frac{1}{\theta}\int_{\Omega'_n}
f(x,u_n)u_ndx \\
&\quad +\frac{1}{\theta}\langle dH(u_n),u_n \rangle \\
& \geq \big(\frac{1}{p^+}-\frac{1}{\theta}\big)\varphi_p(\nabla u_n)
-2C^{q^+}\big(\frac{1}{q^-}+\frac{1}{\theta}\big)
|V|_{s(x)}\| u_n\|^{q^+} \\
&\quad -\frac{1}{\theta}\| dH(u_n) \|_{X^*}\| u_n\|-k_1-
\frac{k_2}{\theta}\\
& \geq \big(\frac{1}{p^+}-\frac{1}{\theta}\big)\| u_n\|^{p^-}
-2C^{q^+}\big(\frac{1}{q^-}+\frac{1}{\theta}\big)|V|_{s(x)}\| u_n\|^{q^+}\\
&\quad -\frac{1}{\theta}\| dH(u_n) \|_{X^*}\| u_n\|-k_3,
\end{align*}
where $k_3=k_1+\frac{k_2}{\theta}$. Since $\theta>p^+>q^+$, letting $n\to \infty$
in the last inequality we obtain a contradiction. Therefore, the sequence
$(u_n)_{n\in \mathbb{N}}$ is bounded in $X$. Consequently, we can extract a
subsequence still denoted $(u_n)_{n\in \mathbb{N}}$ weakly convergent to some
$u$ in $X$. Using the compact embedding $X\hookrightarrow L^{\alpha(x)}(\Omega)$,
we deduce that the subsequence $(u_n)_{n\in \mathbb{N}}$ converges strongly to
$u$ in $L^{\alpha(x)}(\Omega)$. To prove the strong convergence of
$(u_n)_{n\in \mathbb{N}}$ in $X$, we need the following proposition.
\begin{proposition}\label{limit0}
If $(u_n)_{n\in \mathbb{N}}$ converges weakly to $u$ in $X$, then
$$
\lim_{n\to \infty}\int_\Omega V(x)|u_n|^{q(x)-2}u_n(u_n-u)dx=0 .
$$
\end{proposition}
\begin{proof}
\begin{align*}
\big| \int_\Omega V(x)|u_n|^{q(x)-2}u_n(u_n-u)dx \big|
& \leq c_0|V|_{s(x)}|
|u_n|^{q(x)-1}|_{\frac{q(x)}{q(x)-1}}|u_n-u|_{\alpha(x)}\\
& \leq c_0|V|_{s(x)}|u_n|^{k_0}_{q(x)}|u_n-u|_{\alpha(x)},
\end{align*}
where $c_0$ and $k_0\in \{q^--1,q^+-1 \}$ are positive constants. Using the
compact embeddings $X\hookrightarrow L^{q(x)}(\Omega)$,
$X\hookrightarrow L^{\alpha(x)}(\Omega)$ and the inequality
$ ||u_n|_{q(x)} -|u|_{q(x)} |\leq |u_n-u|_{q(x)}$, we obtain
$|u_n-u|_{q(x)}\to0$ in $L^{q(x)}(\Omega)$, $|u_n-u|_{\alpha(x)}\to0$
in $L^{\alpha(x)}(\Omega)$ and $|u_n|_{q(x)}\to |u|_{q(x)}$.
The proof is complete.
\end{proof}
Since $dH(u_n)\to 0\text{ as }n\to \infty$, $(u_n)_{n\in \mathbb{N}}$ is
bounded in $X$ and
\begin{align*}
|\langle dH(u_n),u_n-u \rangle|
& \leq |\langle dH(u_n),u_n\rangle|+ |\langle dH(u_n),u \rangle|\\
& \leq \| dH(u_n) \|_{X^*}\| u_n \|+\| dH(u_n) \|_{X^*}\| u \|,
\end{align*}
we infer that
\begin{equation}\label{deriv}
\lim_{n\to \infty}\langle dH(u_n),u_n-u \rangle=0.
\end{equation}
The Nemytskii operator $N_f$ being strongly continuous, so
$ \lim_{n\to \infty}N_f(u_n)=N_f(u)$ in $X^*$, combine this
fact and the weak convergence $u_n\rightharpoonup u$ in $X$, it follows that
\begin{equation}\label{nemys}
\lim_{n\to \infty}\langle N_f(u_n),u_n-u\rangle=0.
\end{equation}
By Proposition \ref{limit0}, expressions \eqref{deriv} and \eqref{nemys},
we can conclude that
$$
\lim_{n\to \infty}\langle -\Delta_{p(x)}u_n,u_n-u \rangle=0.
$$
Now, by Proposition \ref{type} (iii), it is clear that the subsequence
$u_n\to u$ in $X$ strongly, since $-\Delta_{p(x)}$ is a mapping of type
$(S_+)$. The proof of Lemma \ref{lem1} is complete.
\end{proof}
\begin{lemma}\label{lem2}
Under assumptions {\rm (A1)--(A3)}, the functional $H$
satisfies the $(PS)_c^*$ condition for every $c\in \mathbb{R}$.
\end{lemma}
\begin{proof}
Let $(u_n)_{n\in \mathbb{N^*}}\subseteq X$ be a $(PS)_c^*$ sequence for
$H$ with $c\in \mathbb{R}$, i.e., $u_n\in Y_n$ for each $n\in \mathbb{N^*}$,
$H(u_n)\to c$ and $d(H_{|Y_n})(u_n)\to 0$ as $n\to \infty$.
In a similar way to the proof of Lemma \ref{lem1}, we obtain the boundedness
of the sequence $(u_n)_{n\in \mathbb{N^*}}\subseteq X$.
Consequently, we can extract a subsequence
$(u_{n_k})_{k\in \mathbb{N^*}}$ of $(u_n)_{n\in \mathbb{N^*}}$ weakly convergent
to some $u$ in $X$. The space $X$ can be written as
$ X=\overline{\cup_{n\in \mathbb{N^*}}Y_n}$, then we can choose a
sequence $(v_n)_{n\in \mathbb{N^*}}$ such that $v_n\in Y_n$ for each
$n\in \mathbb{N^*}$ and $ \lim_{n\to \infty}v_n=u\text{ in }X$.
We have the following expression
\begin{equation}\label{sum}
\langle dH(u_{n_k}),u_{n_k}-u \rangle=\langle dH(u_{n_k}),u_{n_k}-v_{n_k}
\rangle+\langle dH(u_{n_k}),v_{n_k}-u \rangle.
\end{equation}
As $d(H_{|Y_{n_k}})(u_{n_k})\to 0\text{ as }k\to \infty,\ u_{n_k}-v_{n_k}
\rightharpoonup 0 \text{ in }Y_{n_k}\text{ and }v_{n_k}\to u\in X$,
we deduce that
\begin{equation}\label{conv}
\langle dH(u_{n_k}),u_{n_k}-v_{n_k} \rangle \to 0 \text{ and }\langle
dH(u_{n_k}),v_{n_k}-u \rangle \to 0\text{ as }k\to \infty.
\end{equation}
Hence, \eqref{sum} and \eqref{conv} give us
\begin{equation}\label{derlm}
\langle dH(u_{n_k}),u_{n_k}-u \rangle \to 0\text{ as }k\to \infty.
\end{equation}
We have seen that the Nemytskii operator $N_f:X\to X^*$ is strongly
continuous while the $p(x)$-Laplacian operator is a mapping of type
$(S_+)$. These facts combine with Proposition \ref{limit0}, yield
that $dH:X\to X^*$ is a mapping of type $(S_+)$. Since the
subsequence $(u_{n_k})_{k\in \mathbb{N^*}}$ converges weakly to $u$ in $X$,
from \eqref{derlm} it is clear that
$ \lim_{k\to \infty}u_{n_k}=u\text{ in }X$.
Next, we show that $u$ is a critical point of $H$. Choosing an
arbitrary $w_n\in Y_n$, for any $n_k\geq n$, we can write
\begin{equation} \label{eqn}
\begin{aligned}
\langle dH(u),w_n \rangle
& = \langle dH(u)-dH(u_{n_k}),w_n
\rangle+\langle dH(u_{n_k}),w_n \rangle \nonumber \\
& = \langle dH(u)-dH(u_{n_k}),w_n
\rangle+\langle d(H_{|Y_{n_k}})(u_{n_k}),w_n \rangle.
\end{aligned}
\end{equation}
Since $H\in C^1(X,\mathbb{R})$ and $\lim_{k\to \infty}u_{n_k}=u$ in $X$, it follows
that
$\lim_{k\to \infty}dH(u_{n_k})=dH(u)$. Therefore, \eqref{eqn} letting
$k\to \infty$ we deduce that $\langle dH(u),w_n \rangle=0$ for all $w_n \in Y_n$,
hence $dH(u)=0$. In conclusion, $H$ satisfies the $(PS)_c^*$ condition for every
$c\in \mathbb{R}$. The proof is complete.
\end{proof}
Now, we state several Lemmas that will be useful in the sequel.
\begin{lemma}[see \cite{FZH}]\label{sup1}
If $\alpha \in C_+(\overline{\Omega})$ with $\alpha(x) 0$ and $k\in \mathbb{N^*}$
denote
$$
\alpha_k=\sup \{|\Theta(u)|: u\in Z_k,\ \| u\| \leq \gamma \}.
$$
Then,
$ \alpha_k<\infty \text{ and }\lim_{k\to \infty}\alpha_k=0$.
\end{lemma}
\begin{lemma}\label{sup3}
Assume that the Carath\'eodory function $f$ satisfies {\rm(A2), (A3)}.
Then there exist $k_1,k_2>0$, $\sigma_0 \in L^1(\Omega)$ and
$\chi \in L^\infty(\Omega)$ with $\chi(x)>0$ for every $x\in \Omega$ such that
$$
F(x,t)\geq \chi(x)|t|^\theta-k_1-k_2\sigma_0(x),\text{ for }x\in \Omega,\ t\in
\mathbb{R}.
$$
\end{lemma}
Now, we are in a position to give the proofs of main theorems state above.
\begin{proof}[Proof of Theorem \ref{cr1}]
Let us verify the conditions of the Fountain theorem.
It is clear that the $C^1$-functional $H:X\to \mathbb{R}$ defined by
$$
H(u)= \int_\Omega \frac{1}{p(x)} |\nabla u|^{p(x)}dx+\int_\Omega
\frac{V(x)}{q(x)}|u|^{q(x)}dx-\int_\Omega F(x,u)dx
$$
is even and, by Lemma \ref{lem1}, it satisfies the $(PS)$ condition. So,
the functional $H$ satisfies also the $(PS)_c$ condition for every $c>0$,
which gives the condition (3) of Fountain theorem.
Let us prove that for each $k\in \mathbb{N^*}$ there exists $r_k>0$ such that
$$
\inf_{u\in Z_k,\ \| u \|=r_k}H(u)\to \infty \text{ as }k\to \infty.
$$
By Proposition \ref{cara2}, we deduce that
$$
\big|\int_\Omega F(x,u(x))dx \big|
\leq \int_{\Omega}\big(c_1|u|^{\beta(x)}
+\sigma(x)\big)dx\leq c_1\varphi_{\beta}(u)+c_2,
$$
where $ c_2=\int_{\Omega}\sigma(x)dx$. By Proposition \ref{connect}
(1) and (2), $\varphi_\beta(u)\leq1$ if $|u|_{\beta(x)}\leq1$ and
$\varphi_\beta(u)\leq |u|^{\beta^+}_{\beta(x)}$ if $|u|_{\beta(x)}>1$,
respectively. Using Lemma \ref{sup1},
we also have $|u|_{\beta(x)}\leq \beta_k\| u\|$, for all $u\in Z_k$. Then,
for $u\in Z_k$ with $\| u\| \geq1$, it follows that
\begin{equation} \label{Hin}
\begin{aligned}
H(u)
& \geq \frac{1}{p^+}\varphi_{p}(|\nabla u|)-\frac{1}{q^-}\int_{\Omega}|V(x)|
|u(x)|^{q(x)}dx-c_1\varphi_{\beta}(u)-c_2\nonumber \\
& \geq \begin{cases}
\frac{1}{p^+}\| u\|^{p^-}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}
\| u\|^{q^+}-c_1-c_2 & \text{if }|u|_{\beta(x)} \leq1\\
\frac{1}{p^+}\| u\|^{p^-}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}
\| u\|^{q^+}-c_1\beta^{\beta^+}_k\| u
\|^{\beta^+}-c_2 & \text{if }|u|_{\beta(x)}>1
\end{cases} \\
& \geq \frac{1}{p^+}\| u\|^{p^-}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}\|
u\|^{q^+}-c_1\beta^{\beta^+}_k\| u\|^{\beta^+}-c_3,
\end{aligned}
\end{equation}
where $c_3=c_1+c_2$. For each $k\in \mathbb{N^*}$, define the real numbers
$r_k$ by
$$
r_k=(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{1}{p^--\beta^+}}.
$$
From hypothesis (A5), we know that $\beta^+>p^-$, hence
$ \lim_{k\to \infty}r_k=+\infty$. Without any loss of generality,
we can suppose that $r_k\geq1$ for each $k\in \mathbb{N^*}$. Using the
above inequality, for all $u\in Z_k$ with $\| u\|=r_k$, we infer that
\begin{align*}
H(u)
& \geq \frac{1}{p^+}(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{p^-}
{p^--{\beta^+}}}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}(c_1{\beta^+}
\beta_k^{\beta^+})^{\frac{q^+}{p^--{\beta^+}}} \\
&\quad -c_1\beta^{\beta^+}_k(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{{\beta^+}}
{p^--{\beta^+}}}-c_3 \\
& = \frac{{\beta^+}-p^+}{{\beta^+}p^+}(c_1{\beta^+}\beta_k^{\beta^+})^
{\frac{p^-}{p^--{\beta^+}}}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}(c_1
{\beta^+}\beta_k^{\beta^+})^{\frac{q^+}{p^--{\beta^+}}}-c_3 \\
& = (c_1{\beta^+}\beta_k^{\beta^+})^{\frac{p^-}{p^--{\beta^+}}}
\Big[\frac{{\beta^+}-p^+}{{\beta^+}p^+}
-\frac{2C^{q^+}}{q^-}|V|_{s(x)}(c_1{\beta^+}\beta_k^{\beta^+})^
{\frac{p^--q^+}{{\beta^+}-p^-}} \\
& \quad -\frac{c_3}{(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{p^-}
{p^--{\beta^+}}}}\Big].
\end{align*}
Consequently,
\begin{equation}\label{Hinf}
\begin{aligned}
\inf_{u\in Z_k,\, \| u \|=r_k}H(u)
& \geq (c_1{\beta^+}\beta_k^{\beta^+})^{\frac{p^-}{p^--{\beta^+}}}
\Big[\frac{{\beta^+}-p^+}
{{\beta^+}p^+} \\
&\quad -\frac{2C^{q^+}}{q^-}|V|_{s(x)}
(c_1{\beta^+}\beta_k^{\beta^+})^
{\frac{p^--q^+}{{\beta^+}-p^-}}
-\frac{c_3}{(c_1{\beta^+}\beta_k^{\beta^+})^
{\frac{p^-}{p^--{\beta^+}}}}\Big].
\end{aligned}
\end{equation}
Using inequality \eqref{Hinf} and hypothesis (A5), it is obvious that
$$
\inf_{u\in Z_k,\ \| u \|=r_k}H(u)\to +\infty \text{ as }k\to
\infty,
$$
so condition (1) of Fountain theorem is satisfied.
It remain to prove that for each $k\in \mathbb{N^*}$ there exists
$\rho_k>r_k>0$ such that
$$
\max_{u\in Y_k,\ \| u\|=\rho_k}H(u)\leq0.
$$
The functional $\| \cdotp \|_\theta:X\to \mathbb{R}$ defined by
\[
\| u\|_\theta= \Big(\int_{\Omega}\chi(x)|u(x)|^\theta dx\Big)^{1/\theta}
\]
being a norm on the Banach space $X$, with $\chi$ as defined in Lemma \ref{sup3}.
Then, on the finite dimensional subspace $Y_k$ the norms $\| \cdotp \|$ and
$\| \cdotp \|_\theta$ are equivalent, so there exists a constant
$\delta>0$ such that $\| u\|_\theta \geq \delta \| u \|$,
for all $u\in Y_k$. Using Lemma \ref{sup3}, we also obtain
$ \int_\Omega F(x,u)dx\geq \| u \|^\theta_\theta-k_3,$
where $ k_3=\int_\Omega(k_1+k_2\sigma_0(x))dx$. Then, for all
$u\in Y_k$ with $\| u \| \geq1$, we have
\begin{equation} \label{deflim0}
\begin{aligned}
H(u) & \leq \frac{1}{p^-}\varphi_{p}(|\nabla u|)+\frac{1}{q^-}
\int_{\Omega}|V(x)||u(x)|^{q(x)}dx-\| u \|^\theta_\theta+k_3 \\
& \leq \frac{1}{p^-}\| u\|^{p^+}+\frac{2C^{q^+}}{q^-}
|V|_{s(x)}\| u\|^{q^+}-\delta^\theta \| u \|^\theta +k_3.
\end{aligned}
\end{equation}
Hypothesis $\theta>p^+>q^+$ implies that
$$
\lim_{t\to \infty}
\Big(\frac{1}{p^-}t^{p^+}+\frac{2C^{q^+}}{q^-}|V|_{s(x)}t^{q^+}-\delta^\theta
t^\theta+k_3\Big)=-\infty.
$$
Then, there exists $t_0>0$ such that for all $t\in [1,+\infty)\cap[t_0,+\infty)$
\begin{equation}\label{deflim1}
\frac{1}{p^-}t^{p^+}+\frac{2C^{q^+}}{q^-}|V|_{s(x)}t^{q^+}-\delta^\theta
t^\theta+k_3\leq-1.
\end{equation}
By Choosing $\rho_k=\max \{r_k,t_0\}+1$, inequality \eqref{deflim1} is fulfilled
for $t=\rho_k$. Then, for all $u\in Y_k$ with $\| u\|=\rho_k$, it follows
that
\begin{equation}\label{deflim2}
\frac{1}{p^-}\| u\|^{p^+}+\frac{2C^{q^+}}{q^-}|V|_{s(x)}\| u\|^
{q^+}-\delta^\theta \| u \|^\theta+k_3\leq-1<0.
\end{equation}
Combine \eqref{deflim0} and \eqref{deflim2}, it is obvious that
$$
\max_{u\in Y_k,\,\| u\|=\rho_k}H(u)\leq0,
$$
which shows that the condition (2) of Fountain theorem is satisfied.
By applying Theorem \ref{FT} (``Fountain theorem"), the $C^1$-functional
$H$ has a sequence of critical values tending to $+\infty$.
Therefore, there is a sequence
$(\pm u_n)_{n\in \mathbb{N}}\subseteq X$ of critical points for the functional
$H$ such that $H(\pm u_n)\to +\infty \text{ as }n\to \infty$. So, the proof
is complete.
\end{proof}
\begin{proof}[Proof of Theorem \ref{cr2}]
Let us verify the conditions of the Dual Fountain theorem.
The $C^1$-functional $H$ is even, because the function $f$ is odd in its
second argument (see hypothesis (A4)). By Lemma \ref{lem2}, the functional
$H$ satisfies the $(PS)_c^*$ condition for every $c\in \mathbb{R}$,
in particular for every $c\in [d_{k_0},0)$, so condition (4) of Dual
Fountain theorem is satisfied.
We first prove that for each $k\in \mathbb{N}^*$ there exists $r_k>0$
such that
$$
\max_{u\in Y_k,\ \| u\|=r_k}H(u)<0.
$$
The norm $\| \cdot \|_\theta$ defined previously being equivalent with the norm
$\| \cdot \|$ on the finite dimensional subspace $Y_k$, there exists a constant
$\delta>0$ such that $\| u \|_\theta \geq \delta \| u \|$, for all
$u\in Y_k$. As in the proof of Theorem \ref{cr1}, for all $u\in Y_k$ with
$\| u\|\geq1$, the following inequality holds
\begin{equation}\label{prcr21}
H(u)\leq \frac{1}{p^-}\| u\|^{p^+}+\frac{2C^{q^+}}{q^-}|V|_{s(x)}
\| u\|^{q^+}-\delta^\theta \| u \|^\theta+k_3.
\end{equation}
Hypothesis $\theta>p^+>q^+$ implies that
$$
\lim_{t\to \infty}\Big(\frac{1}{p^-}t^{p^+}+\frac{2C^{q^+}}
{q^-}|V|_{s(x)}t^{q^+}-\delta^\theta t^\theta+k_3\Big)=-\infty.
$$
So, there exists a constant $t_1\in (1,+\infty)$ such that for all
$t\in [t_1,+\infty)$
\begin{equation}\label{prcr22}
\frac{1}{p^-}t^{p^+}+\frac{2C^{q^+}}{q^-}|V|_{s(x)}t^{q^+}-
\delta^\theta t^\theta+k_3\leq-1.
\end{equation}
Inequalities \eqref{prcr21} and \eqref{prcr22} show that, for any $u\in Y_k$ with
$\| u\|=t_1,\ H(u)\leq-1$. Choosing $r_k=t_1$ for each $k\in \mathbb{N^*}$,
we deduce that
$$
\max_{u\in Y_k,\ \| u\|=r_k}H(u)\leq-1<0,
$$
so condition (2) of Dual Fountain theorem is satisfied.
Second, we prove that there is $k_0\in \mathbb{N^*}$ such that for each
$k\in \mathbb{N^*},\ k\geq k_0$, there exists $\rho_k>r_k>0$ for which
$$
\inf_{u\in Z_k,\ \| u\|=\rho_k}H(u)\geq0.
$$
In a similar way to the proof of Theorem \ref{cr1}, for all
$u\in Z_k$ with $\| u\| \geq1$, the following inequality holds
\begin{equation}\label{prcr23}
H(u)\geq \frac{1}{p^+}\| u\|^{p^-}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}\|
u\|^{q^+}-c_1\beta^{\beta^+}_k\| u\|^{\beta^+}
-c_3.
\end{equation}
We also have
\begin{align*}
&\lim_{k\to \infty}(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{1}{p^--{\beta^+}}}\\
& = \lim_{k\to \infty}\big[\frac{{\beta^+}-p^+}{{\beta^+}p^+}(c_1{\beta^+}
\beta_k^{\beta^+})^{\frac{p^-}{p^--{\beta^+}}}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}
(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{q^+}{p^--{\beta^+}}}-
c_3 \big]=+\infty.
\end{align*}
Then, there is $k_0\in \mathbb{N^*}$ such that for all $k\geq k_0$,
$(c_1{\beta^+}\beta_k^{\beta^+})^{\frac{1}{p^--{\beta^+}}}>t_1$ and
$$
\frac{{\beta^+}-p^+}{{\beta^+}p^+}(c_1{\beta^+}\beta_k^{\beta^+})
^{\frac{p^-}{p^--{\beta^+}}}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}(c_1{\beta^+}
\beta_k^{\beta^+})^{\frac{q^+}{p^--{\beta^+}}}-c_3\geq0.
$$
By Choosing $\rho_k=(c_1{\beta^+}\beta_{k_0}^{\beta^+})^{\frac{1}{p^--{\beta^+}}}$
for $k\geq k_0$, it follows that $\rho_k>r_k=t_1>0$ for each $k\in \mathbb{N^*}$.
Using \eqref{prcr23}, it is obvious that
$$
H(u)\geq \frac{{\beta^+}-p^+}{{\beta^+}p^+}(c_1{\beta^+}\beta_{k_0}^{\beta^+})^
{\frac{p^-}{p^--{\beta^+}}}-\frac{2C^{q^+}}{q^-}|V|_{s(x)}
(c_1{\beta^+}\beta_{k_0}^{\beta^+})^{\frac{q^+}{p^--{\beta^+}}}-c_3\geq0,
$$
for all $u\in Z_k,\ \| u\|=\rho_k$. Finally, this last inequality gives
$$
\inf_{u\in Z_k,\ \| u\|=\rho_k}H(u)\geq0,
$$
which shows that the condition (1) of Dual Fountain theorem is satisfied.
Next, we prove that
$$
\inf_{u\in Z_k,\ \| u\| \leq \rho_k}H(u)\to 0\text{ as }k\to \infty.
$$
Let us denote
$$
b_k=\max_{u\in Y_k,\, \| u\|=r_k}H(u),\quad
d_k=\inf_{u\in Z_k,\, \| u\| \leq \rho_k}H(u).
$$
It is easy to remark that $Y_k\cap Z_k\neq0$ for each $k\in \mathbb{N^*}$.
For $k\geq k_0$, let $u_0\in Y_k\cap Z_k$, with $u_0\neq0$, and
$u_k=\frac{r_k} {\| u_0\|}u_0$, then $\| u_k\|=r_k$.
Since $0