\documentclass[reqno]{amsart}
\usepackage{hyperref}

\AtBeginDocument{{\noindent\small
\emph{Electronic Journal of Differential Equations},
Vol. 2013 (2013), No. 148, pp. 1--13.\newline
ISSN: 1072-6691. URL: http://ejde.math.txstate.edu or http://ejde.math.unt.edu
\newline ftp ejde.math.txstate.edu}
\thanks{\copyright 2013 Texas State University - San Marcos.}
\vspace{8mm}}

\begin{document}
\title[\hfilneg EJDE-2013/148\hfil Existence and multiplicity of solutions]
{Existence and multiplicity of solutions for a degenerate nonlocal
elliptic differential equation}

\author[N. T. Chung, H. Q. Toan\hfil EJDE-2013/148\hfilneg]
{Nguyen Thanh Chung, Hoang Quoc Toan}  % in alphabetical order

\address{Nguyen Thanh Chung \newline
Dept. Science Management and International Cooperation,
 Quang Binh University, 312 Ly Thuong Kiet, Dong Hoi, Quang Binh, Vietnam}
\email{ntchung82@yahoo.com}

\address{Hoang Quoc Toan \newline
Department of Mathematics, Hanoi University of Science,
334 Nguyen Trai, Thanh Xuan, Hanoi, Vietnam}
\email{hq\_toan@yahoo.com}

\thanks{Submitted October 23, 2012. Published June 27, 2013.}
\subjclass[2000]{35J60, 35B38, 35J25}
\keywords{Degenerate nonlocal problems; existence o solutions;
multiplicity; \hfill\break\indent variational methods}

\begin{abstract}
 Using variational arguments, we study the existence and multiplicity 
 of solutions for the degenerate nonlocal differential equation
 \begin{gather*}
 - M\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx\Big)\operatorname{div}
 \Big(|x|^{-ap}|\nabla u|^{p-2}\nabla u\Big)
 = |x|^{-p(a+1)+c} f(x,u) \quad \text{in } \Omega,\\
 u =  0 \quad \text{on } \partial\Omega,
 \end{gather*}
 where $\Omega \subset \mathbb{R}^N$ ($N \geq 3$) and the function
 $M$ may be zero at zero.
\end{abstract}

\maketitle
\numberwithin{equation}{section}
\newtheorem{theorem}{Theorem}[section]
\newtheorem{lemma}[theorem]{Lemma}
\newtheorem{definition}[theorem]{Definition}
\allowdisplaybreaks

\section{Introduction}

In this article, we study the boundary-value problem
\begin{equation}\label{e1.1}
\begin{gathered}
- M\Big(\int_{\Omega}|x|^{-ap}|\nabla u|^p\,dx\Big)\operatorname{div}\Big(
|x|^{-ap}|\nabla u|^{p-2}\nabla u\Big) = |x|^{-p(a+1)+c} f(x,u)
\quad \text{ in } \Omega,\\
u =  0 \quad \text{on } \partial\Omega,
\end{gathered}
\end{equation}
where $\Omega \subset \mathbb{R}^N$ ($N \geq 3$) is a smooth bounded domain,
$0 \in \Omega$, $0 \leq a < \frac{N-p}{p}$, $1 < p < N$, $0<c $, $M: \mathbb{R}^+
\to \mathbb{R}^+$ is a continuous function, $\mathbb{R}^+=[0,\infty)$.

Since the first equation in \eqref{e1.2} contains an integral over $\Omega$,
it is no longer a pointwise equation, and therefore it is often called nonlocal
problem.
It should be noticed that if $a = 0$ and
$c=p$ then problem \eqref{e1.1} becomes
\begin{equation}\label{e1.2}
\begin{gathered}
- M\Big(\int_{\Omega}|\nabla u|^p\,dx\Big)\Delta_p u = f(x,u) \quad
 \text{in }\Omega,\\
u =  0 \quad \text{on } \partial\Omega.
\end{gathered}
\end{equation}
This equation  is related to the stationary version of the
Kirchhoff equation
\begin{equation}\label{e1.3}
\rho\frac{\partial^2u}{\partial t^2}
-\Big(\frac{P_0}{h}+\frac{E}{2L}\int_0^L
\big|\frac{\partial u}{\partial x}\big|^2\,dx\Big)\frac{\partial^2 u}{\partial x^2}=0
\end{equation}
presented by Kirchhoff in 1883 \cite{Kirchhoff}. This  is
an extension of the classical d'Alembert's wave equation by considering
the effects of the changes in the length of the string during the vibrations.
The parameters in \eqref{e1.3} have the following meanings: $L$ is the
length of the string, $h$ is the area of the cross-section, $E$ is the
Young modulus of the material, $\rho$ is the mass density, and $P_0$ is
the initial tension.

In recent years, problems involving Kirchhoff type operators have been
studied in many papers, we refer to \cite{Anello,BensBouc,CorreFigue1,
CorreFigue2,GDaiDLiu,GDaiRHao,DLiu,TFMa,Ricceri,SunTang}, in which
the authors have used different methods to get the existence of solutions
for \eqref{e1.2}. One of the important hypotheses in these papers is that the
function $M$ is non-degenerate; i.e.,
\begin{equation}\label{e1.4}
M(t) \geq m_0>0 \quad \text{for all } t \in \mathbb{R}^+.
\end{equation}
We  refer the readers to  \cite{AutColPuc,ColaPucc} where the
authors studied the existence of weak solutions for elliptic equations involving $p$-polyharmonic Kirchhoff operators.

Motivated by the ideas introduced in \cite{Chung,ColaPucc,XLFan,DLiu,BJXuan},
the goal of this paper is to study the existence and multiplicity of solutions for \eqref{e1.1} without condition \eqref{e1.4}. The approach is based on variational arguments.
Our results complement the previous ones in the non-degenerate case.
Moreover, we consider problem \eqref{e1.1} in the general case $0 \leq a < \frac{N-p}{p}$, $1 < p < N$, $0<c $. It should be noticed that in \cite{ChungToan},
we studied the existence of solutions for problem \eqref{e1.1} in the sublinear case when $f: \Omega\times [0,+\infty) \to \mathbb{R}$ is a Carath\'eodory function satisfying
$$
|f(x,t)| \leq Ct^{\alpha p-1}, \quad 1<\alpha<\min\big\{\frac{N}{N-p},\frac{N-p(a+1)
+c}{N-p(a+1)}\big\}, \quad C>0
$$
for all $t\in [0,+\infty)$ and $x \in \Omega$.

We start by recalling some useful results in \cite{CafKohNir, CatWang,
BJXuan}. We have known that for all $u \in C^\infty_0(\mathbb{R}^N)$, there exists
a constant $C_{a,b} > 0$ such that
\begin{equation}\label{e1.5}
\Big(\int_{\mathbb{R}^N}|x|^{-bq}|u|^q\,dx\Big)^{p/q} \leq C_{a,b}\int_{\mathbb{R}^N}
|x|^{-ap}|\nabla u|^p\,dx,
\end{equation}
where
$$
- \infty < a < \frac{N-p}{p}, \quad
a \leq b \leq a+1, \quad
q = p^\ast(a,b) =\frac{Np}{N-dp}, \quad
 d = 1+a-b.
$$
Let $W^{1,p}_0(\Omega,|x|^{-ap})$ be the completion of $C^\infty_0
(\Omega)$ with respect to the norm
$$
\|u\|_{a,p} = \Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx\Big)^{1/p}.
$$
Then $W^{1,p}_0(\Omega,|x|^{-ap})$ is reflexive and separable Banach
space. From the boundedness of $\Omega$ and the standard
approximation argument, it is easy to see that \eqref{e1.5} holds for any
$u \in W^{1,p}_0(\Omega,|x|^{-ap})$ in the sense that
\begin{equation}\label{e1.6}
\Big(\int_{\mathbb{R}^N}|x|^{-\alpha}|u|^l\,dx\Big)^{p/l}
 \leq C_{a,b}\int_{\mathbb{R}^N}
|x|^{-ap}|\nabla u|^p\,dx,
\end{equation}
for $1 \leq l \leq p^\ast = \frac{Np}{N-p}$, $\alpha \leq (1+a)l + N\Big(1-
\frac{l}{p}\Big)$; that is, the embedding $W^{1,p}_0(\Omega,|x|^{-ap})
\hookrightarrow L^l(\Omega,|x|^{-\alpha})$ is continuous, where $L^l
(\Omega,|x|^{-\alpha})$ is the weighted $L^l(\Omega)$ space with the
norm
$$
|u|_{l,\alpha} : = |u|_{L^l(\Omega, |x|^{-\alpha})}
= \Big(\int_\Omega|x|^{-\alpha}|u|^l\,dx\Big)^{1/l}.
$$
In fact, we have the following compact embedding result which is an
extension of the classical Rellich-Kondrachov compactness theorem.

\begin{lemma}[Compactness embedding theorem \cite{BJXuan}]
\label{lem1.1}
Suppose that $\Omega\subset \mathbb{R}^N$ is an open bounded domain with
$C^1$ boundary and that $0 \in \Omega$, where $1 < p < N$, $-\infty < a
< \frac{N-p}{p}$, $1 \leq l < \frac{Np}{N-p}$ and $\alpha < (1+a)l+N\big(1-
\frac{l}{p}\big)$. Then the embedding $W^{1,p}_0(\Omega,|x|^{-ap})
\hookrightarrow L^l(\Omega,|x|^{-\alpha})$ is compact.
\end{lemma}

\section{Main results}

In this section, will we discuss the existence of weak solutions for problem
\eqref{e1.1}. For simplicity, we denote $X=W^{1,p}_0(\Omega,|x|^{-ap})$.
In the following, when there is no misunderstanding, we always use $c_i,
C_i$ to denote positive constants.

\begin{definition}\label{def2.1}\rm
We say that $u \in X$ is a weak solution of problem \eqref{e1.1} if
\begin{align*}
&M\Big(\int_\Omega|x|^{-ap}|\nabla u|^p\,dx\Big)\int_\Omega |x|^{-ap}|\nabla
u|^{p-2}\nabla u\cdot \nabla \varphi \,dx \\
&- \int_\Omega |x|^{-p(a+1)+c}f(x,u)
\varphi \,dx = 0
\end{align*}
for all $\varphi \in C^\infty_0(\Omega)$.
\end{definition}

Define
\begin{equation}\label{e2.1}
\Phi(u) = \frac{1}{p}\widehat{M}\Big(\int_\Omega|x|^{-ap}|\nabla u|^p\,dx\Big),
\quad \Psi(u) = \int_\Omega |x|^{-p(a+1)+c}F(x,u)\,dx,
\end{equation}
where 
\[
\widehat{M}(t) = \int_0^tM(s)\,ds, \quad
F(x,t) = \int_0^tf(x,s)\,ds.
\]
By the condition (F0) (see Theorem \ref{the2.2} below), 
Lemma \ref{lem1.1} implies that the energy functional 
$J(u) = \Phi(u)-\Psi(u): X \to \mathbb{R}$ associated
with problem \eqref{e1.1} is well defined. 
Then it is easy to see that $J \in C^1(X,\mathbb{R})$ and $u \in X$ 
is a weak solution of \eqref{e1.1} if and only if $u$
is a critical point of $J$. Moreover, we have
\begin{align*}
J'(u)(\varphi) 
&= M\Big(\int_\Omega|x|^{-ap}|\nabla u|^p\,dx\Big)\int_\Omega
|x|^{-ap}|\nabla u|^{p-2}\nabla u\cdot \nabla \varphi \,dx \\
&\quad - \int_\Omega |x|^{-p (a+1)+c}f(x,u)\varphi \,dx \\
& = \Phi'(u)(\varphi)-\Psi'(u)(\varphi)
\end{align*}
for all $\varphi \in X$.

For the next theorem, we use the following assumptions:
\begin{itemize}
\item[(M0)] $M: \mathbb{R}^+ \to \mathbb{R}^+$ is a continuous function and
satisfies
$$
m_0t^{\alpha-1} \leq M(t) \quad \text{for all } t \in \mathbb{R}^+,
$$
where $m_0>0$ and $\alpha>1$;

\item[(F0)] $f: \Omega\times \mathbb{R} \to \mathbb{R}$ is a Carath\'{e}odory function such
that
$$
|f(x,t)| \leq C_1(1+|t|^{q-1}) \quad\text{for all } 
x \in \Omega \text{ and } t \in \mathbb{R},
$$
where $C_1>0$ and $1<q<\min\{p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+1)p}\}$;

\item[(E0)] $\alpha p > q$.
\end{itemize}

\begin{theorem}\label{the2.2}
Under assumptions {\rm (M0), (F0), (E0)},
problem \eqref{e1.1} has at least one weak solution.
\end{theorem}

\begin{proof}
Let $\{u_m\}$ be a sequence that converges weakly to $u$ in $X$. Then, by
the weak lower semicontinuity of the norm, we have
$$
\liminf_{m\to \infty}\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx \geq \int_\Omega
|x|^{-ap}|\nabla u|^p\,dx.
$$
Combining this with the continuity and monotonicity of the function
 $\psi: \mathbb{R}^+ \to \mathbb{R}$, $t \mapsto \psi(t)=\frac{1}{p}\widehat{M}(t)$, we obtain
\begin{equation} \label{e2.2}
\begin{aligned}
\liminf_{m\to \infty}\Phi(u_m)
& = \liminf_{m\to \infty}\frac{1}{p}\widehat{M}
\Big(\int_\Omega |x|^{-ap}|\nabla u_m|^p\,dx\Big) \\
& = \liminf_{m\to \infty}\psi\Big(\int_\Omega |x|^{-ap}|\nabla u_m|^p\,dx\Big) \\
& \geq \psi\Big(\liminf_{m\to \infty}\int_\Omega |x|^{-ap}|\nabla u_m|^p\,dx
\Big) \\
& \geq \psi\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx\Big) \\
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx\Big)
 = \Phi(u).
\end{aligned}
\end{equation}
Using (F0), H\"older's inequality, and Lemma \ref{lem1.1}, it follows that
\begin{equation} \label{e2.3}
\begin{aligned}
& \big|\int_\Omega |x|^{-p(a+1)+c}[F(x,u_m)-F(x,u)]\,dx\big| \\
& \leq \int_\Omega |x|^{-p(a+1)+c}|f(x,u+\theta_{m}(u_m-u))| |u_m-u|\,dx \\
& \leq C_1\int_\Omega|x|^{-p(a+1)+c}\left(1+|u+\theta_{m}(u_m-u)|^{q-1}\right)
|u_m-u|\,dx \\
& \leq C_1\Big(\int_\Omega |x|^{-p(a+1)+c}\,dx\Big)^\frac{q-1}{q}\|u_m-u\|_{L^q
(\Omega,|x|^{-p(a+1)+c})} \\
& \quad +C_1\|u+\theta_{m}(u_m-u)\|_{L^q(\Omega,|x|^{-p(a+1)+c})
}^{q-1}\|u_m-u\|_{L^q(\Omega,|x|^{-p(a+1)+c})},
\end{aligned}
\end{equation}
which tends to $0$ as $m\to \infty$, where $0 \leq \theta_m(x) \leq 1$ for all
$x \in \Omega$. From \eqref{e2.2} and \eqref{e2.3}, the functional $J$ is weakly
lower semi-continuous in $X$.

On the other hand, by assumptions (M0) and (F0), we have
\begin{equation} \label{e2.4}
\begin{aligned}
J(u) & = \frac{1}{p}\widehat{M}\Big(\int_\Omega|x|^{-ap}|\nabla u|^p\,dx
\Big)-\int_\Omega |x|^{-p(a+1)+c}F(x,u)\,dx \\
& \geq \frac{m_0}{p}\int_0^{\|u\|^p_{a,p}}t^{\alpha-1}\,dt-c_1\int_\Omega
|x|^{-p(a+1)+c}\big(1+|u|^q\big)\,dx \\
& \geq \frac{m_0}{\alpha p}\|u\|^{\alpha p}_{a,p}-c_2\|u\|^q_{a,p}-c_3.
\end{aligned}
\end{equation}
Since $1<q<\alpha p$, it follows from \eqref{e2.4} that the functional $J$ is
coercive. Therefore, using the minimum principle, we deduce that the
functional $J$ has at least one weak solution and thus problem \eqref{e1.1}
has at least one weak solution.
\end{proof}

For the next theroem, we sue the following conditions:
\begin{itemize}
\item[(M1)] $M: \mathbb{R}^+ \to \mathbb{R}^+$ is a continuous function and satisfies the
condition
$$
m_1t^{\alpha_1-1} \leq M(t) \leq m_2t^{\alpha_2-1}\quad
 \text{ for all } t \in \mathbb{R}^+,
$$
where $m_2\geq m_1 >0$ and $1< \alpha_1 \leq\alpha_2$;

\item[(M2)] $M$ satisfies
$$
\widehat{M}(t) \geq M(t)t \text{ for all } t \in \mathbb{R}^+;
$$

\item[(F1)] $f(x,t)=o\big(|t|^{\alpha_1 p-1}\big)$, $t\to 0$  uniformly for $x
\in \Omega$;

\item[(F2)] There exists a positive constant $\mu > \alpha_2p$ such that
$$
0< \mu F(x,t) := \int_0^t f(x,s)ds \leq f(x,t)t
$$
for all $x\in \Omega$ and $|t| \geq T>0$;

\item[(E1)] $\alpha_1 p < q$.
\end{itemize}

\begin{theorem}\label{the2.3}
Under assumptions {\rm (F0)--(F2), (M1)--(M2)}, 
problem \eqref{e1.1} has at least one nontrivial weak solution.
\end{theorem}

To prove the above theorem, we need to verify the following lemmas.

\begin{lemma}\label{lem2.4}
Assume that {\rm (M1), (M2), (F0), (F2)} are satisfied. Then the
functional $J$ satisfies the (PS) condition.
\end{lemma}

\begin{proof}
Let $\{u_m\}\subset X$ be a sequence such that
\begin{equation}\label{e2.5}
J(u_m) \to \overline c<\infty, \quad J'(u_m) \to 0 \quad 
\text{in } X^\ast \text{ as } m\to \infty,
\end{equation}
where $X^\ast$ is the dual space of $X$.

First, we will show that the sequence $\{u_m\}$ is bounded in $X$. Indeed,
from \eqref{e2.5}, (M1), (M2) and (F2), we obtain that for all $m$ large
enough,
\begin{equation} \label{e2.6}
\begin{aligned}
&1+\overline c +\|u_m\|_{a,p} \\
& \geq J(u_m)-\frac{1}{\mu}J'(u_m)(u_m) \\
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)-
\frac{1}{\mu}M\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)\int_\Omega
|x|^{-ap}|\nabla u_m|^p\,dx\\
& \quad -\int_\Omega |x|^{-p(a+1)+c}F(x,u_m)\,dx +\frac{1}{\mu}
\int_\Omega |x|^{-p(a+1)+c}f(x,u_m)u_m\,dx \\
& \geq \Big(\frac{1}{p}-\frac{1}{\mu}\Big)M\Big(\int_\Omega|x|^{-ap}|\nabla
u_m|^p\,dx\Big)\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx \\
& \quad -\int_\Omega |x|^{-p(a+1)+c}\Big(\frac{1}{\mu}f(x,u_m)u_m-
F(x,u_m)\Big)\,dx \\
& \geq m_1\big(\frac{1}{p}-\frac{1}{\mu}\big)\|u_m\|^{\alpha_1p}_{a,p}-c_4.
\end{aligned}
\end{equation}
Since $\alpha_1p>1$, it follows from \eqref{e2.6} that $\{u_m\}$ is bounded.
Passing to a subsequence if necessary, there exists $u \in X$, such that
$\{u_m\}$ converges weakly to $u$ in $X$. By \eqref{e2.5}, we obtain
\begin{equation}\label{e2.7}
\lim_{m\to \infty}J'(u_m)(u_m-u) = 0.
\end{equation}
By (F0) and Lemma \ref{lem1.1}, we have
\begin{equation} \label{e2.8}
\begin{aligned}
&\big| \int_\Omega |x|^{-p(a+1)+c}f(x,u_m)(u_m-u)\,dx\big| \\
&\leq \int_\Omega |x|^{-p(a+1)+c}|f(x,u_m)||u_m-u|\,dx \\
& \leq C_1\int_\Omega |x|^{-p(a+1)+c}(1+|u_m|^{q-1})|u_m-u|\,dx \\
& \leq C_1\Big(\int_\Omega |x|^{-p(a+1)+c}\,dx\Big)^\frac{q-1}{q}\|u_m-u
\|_{L^q(\Omega,|x|^{-p(a+1)+c})} \\
& \quad + C_1\|u_m\|_{L^q(\Omega,|x|^{-p(a+1)+c})}^{q-1}\|u_m-
u\|_{L^q(\Omega,|x|^{-p(a+1)+c})},
\end{aligned}
\end{equation}
which tends to $0$ as $m\to \infty$.

By \eqref{e2.7}, \eqref{e2.8} and the definition of the functional $J$, 
it follows that
\begin{equation}\label{e2.9}
\lim_{m\to\infty}M\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)
\int_{\Omega}|x|^{-ap}|\nabla u_m|^{p-2}\nabla u_m\cdot (\nabla u_m-\nabla u)
\,dx=0.
\end{equation}
Since $\{u_m\}$ is bounded in $X$, passing to a subsequence, if
necessary, we may assume that
$$
\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx \to t_0 \geq 0 \quad \text{as } m\to
\infty.
$$
If $t_0 = 0$ then $\{u_m\}$ converges strongly to $u = 0$ in $X$
and the proof is finished. If $t_0 > 0$ then by (M1)  and the
continuity of $M$, we obtain
$$
M\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx \Big) \to M(t_0)>0 \quad
\text{as } m\to\infty.
$$
Thus, for $m$ sufficiently large, we have
\begin{equation}\label{e2.10}
0 < c_5 \leq M\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)\leq c_6.
\end{equation}
From \eqref{e2.9} and \eqref{e2.10} and the condition (M1), we have
\begin{equation}\label{e2.11}
\lim_{m\to\infty}\int_\Omega |x|^{-ap}|\nabla u_m|^{p-2}\nabla u_m\cdot
(\nabla u_m-\nabla u)\,dx=0.
\end{equation}
On the other hand, since $\{u_m\}$ converges weakly to $u$ in $X$, we
have
\begin{equation}\label{e2.12}
\lim_{m\to\infty}\int_\Omega |x|^{-ap}|\nabla u|^{p-2}\nabla u\cdot (\nabla
u_m-\nabla u)\,dx=0.
\end{equation}
By \eqref{e2.11} and \eqref{e2.12},
$$
\lim_{m\to\infty}\int_\Omega |x|^{-ap}\left(|\nabla u_m|^{p-2}\nabla u_m-
|\nabla u|^{p-2}\nabla u\right)\cdot (\nabla u_m-\nabla u)\,dx=0.
$$
or
\begin{equation}\label{e2.13}
\lim_{m\to\infty}\int_\Omega \left(|\nabla v_m|^{p-2}\nabla v_m-|\nabla
v|^{p-2}\nabla v\right)\cdot (\nabla v_m-\nabla v)\,dx=0,
\end{equation}
where $\nabla v_m=|x|^{-a}\nabla u_m$, $\nabla v=|x|^{-a}\nabla u \in L^p(\Omega)$.

We recall that the following inequalities hold
\begin{equation} \label{e2.14}
\begin{gathered}
\langle {|\xi|^{p-2}\xi-|\eta|^{p-2}\eta,\xi-\eta} \rangle  \geq c_7
\Big(|\xi|+|\eta|\Big)^{p-2}|\xi-\eta|^{2}  \quad \text{ if }1<p<2, \\
\langle {|\xi|^{p-2}\xi-|\eta|^{p-2}\eta,\xi-\eta} \rangle  \geq c_8
|\xi-\eta|^{p} \quad \text{ if } p\geq 2,
\end{gathered}
\end{equation}
for all $\xi,\eta\in \mathbb{R}^{N}$, where $\langle .,.\rangle$ denote
the usual product in $\mathbb{R}^N$.

If $1<p<2$, using the H\"{o}lder inequality, by \eqref{e2.13}, we have
\begin{align*}
0&\leq \|u_m-u\|^p_{a,p} 
 = \||\nabla v_m-\nabla v|\|_{L^p(\Omega)}^{p}\\
&\leq\int_{\Omega}|\nabla v_m-\nabla v|^{p}\Big(|\nabla v_m|+|\nabla v|
\Big)^{\frac{p(p-2)}{2}}\Big(|\nabla v_m|+|\nabla v|\Big)^{\frac{p(2-p)}{2}}\,dx\\
&\leq\Big(\int_{\Omega}|\nabla v_m-\nabla v|^{2}(|\nabla v_m|+|\nabla v|
)^{p-2}\,dx\Big)^{p/2}
\Big(\int_{\Omega}(|\nabla v_m|+|\nabla v|)^{p}\,dx\Big)^{\frac{2-p}{2}}\\
&\leq c_9\Big(\int_{\Omega}\langle {|\nabla v_m|^{p-2}\nabla v_m-
|\nabla v|^{p-2}\nabla v,\nabla v_m-\nabla v}\rangle \,dx\Big)^{\frac{p
}{2}}\\
&\quad \times\Big(\int_{\Omega}(|\nabla v_m|+|\nabla v|)^{p}\,dx
\Big)^{\frac{2-p}{2}}\\
&\leq c_{10}\Big(\int_{\Omega}\langle {|\nabla v_m|^{p-2}\nabla v_m
-|\nabla v|^{p-2}\nabla v,\nabla v_m-\nabla v} \rangle \,dx
\Big)^{p/2},
\end{align*}
which converges to $0$ as $m \to \infty$. If $p\geq2$, one has
\begin{align*}
0 & \leq \|u_m-u\|^p_{a,p}
=\||\nabla v_m-\nabla v|\|_{L^p(\Omega)}^p \\
& \leq c_{11}\int_{\Omega}\langle
{|\nabla v_m|^{p-2}\nabla v_m-|\nabla v|^{p-2}\nabla v,\nabla v_m-\nabla
u} \rangle \,dx,
\end{align*}
which converges to $0$ as $m \to \infty$. So we deduce that $\{u_m\}$
converges strongly to $u$ in $X$ and the functional $J$ satisfies the
(PS) condition.
\end{proof}

\begin{lemma}\label{lem2.5}
Suppose that {\rm (M1), (F0), (F1), (F2), (E1)} hold.
Then we have:
\begin{itemize}
\item[(i)] There exist two positive real numbers $\rho$ and $R$ such
that $J(u) \geq R >0$ for all $u \in X$ with $\|u\|_{a,p}=\rho$;
\item[(ii)] There exists $\widehat{u} \in X$ such that $\|\widehat{u}\|_{
a,p}>\rho$ and $J(u) < 0$.
\end{itemize}
\end{lemma}

\begin{proof}
(i) By (M1), we have
\begin{equation} \label{e2.15}
\begin{aligned}
J(u)
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx
\Big)-\int_\Omega|x|^{-p(a+1)+c}F(x,u)\,dx \\
& \geq \frac{m_1}{\alpha_1p}\|u\|_{a,p}^{\alpha_1p}-\int_{\Omega}|x|^{
-p(a+1)+c}F(x,u)\,dx.
\end{aligned}
\end{equation}
Since $\alpha_1 p < q< \min \{ p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+1)p}\}$,
the embeddings 
\[
X \hookrightarrow L^{\alpha_1p}(\Omega, |x|^{-p(a+1)+c}),\quad
X\hookrightarrow L^{q}(\Omega,|x|^{-p(a+1)+c})
\]
 are compact. Then there are constants $c_{12}, c_{13}>0$ such
that
\begin{gather}\label{e2.16}
\|u\|_{L^{\alpha_1p}(\Omega,|x|^{-p(a+1)+c})} \leq c_{12}\|u\|_{a,p},
\\
\label{e2.17}
\|u\|_{L^q(\Omega,|x|^{-p(a+1)+c})} \leq c_{13}\|u\|_{a,p}.
\end{gather}
Let $\epsilon > 0$ be small enough such that
$\epsilon < \frac{m_1}{\alpha_1pc^{\alpha_1p}_{12}}$. By (F0) and (F1),
we obtain
\begin{equation}\label{e2.18}
|F(x,t)|\leq \epsilon|t|^{\alpha_1p} + c_\epsilon |t|^q \text{ for all } x\in
\Omega \text{ and } t \in \mathbb{R}.
\end{equation}
Therefore, by \eqref{e2.15}-\eqref{e2.18}, we have
\begin{align*}
J(u) & \geq \frac{m_1}{\alpha_1p}\|u\|_{a,p}^{\alpha_1p}-\int_{\Omega}
|x|^{-p(a+1)+c}F(x,u)\,dx \\
& \geq \frac{m_1}{\alpha_1p}\|u\|_{a,p}^{\alpha_1p}-\epsilon\int_\Omega
|x|^{-p(a+1)+c}|u|^{\alpha_1p}\,dx-c_\epsilon\int_\Omega|x|^{-p(a+1)+c}
|u|^q\,dx \\
& \geq \Big(\frac{m_1}{\alpha_1p}-\epsilon c^{\alpha_1p}_{12}\Big)\|u
\|^{\alpha_1p}_{a,p}-c_\epsilon c_{13}^q\|u\|^q.
\end{align*}
Since $\alpha_1p < q$, there exist real numbers $\rho, R>0$ such that
$J(u) \geq R$ for all $u \in X$ with $\|u\|_{a,p}=\rho$.

(ii) By (F2), there exists $c_{14}>0$ such that
\begin{equation}\label{e2.19}
F(x,t) \geq c_{14}|t|^\mu \text{ for all } x \in \Omega \text{ and } |t| \geq T.
\end{equation}
For $w \in X \backslash\{0\}$ and $t>0$, it follows from \eqref{e2.19} that
\begin{equation} \label{e2.20}
\begin{aligned}
J(tw) & = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla tw|^p\,dx
\Big)-\int_{\Omega}|x|^{-p(a+1)+c}F(x,tw)\,dx \\
& \leq \frac{m_2t^{\alpha_2p}}{\alpha_2p}\|w\|_{a,p}^{\alpha_2p}-c_{14}
t^\mu\int_{\Omega}|x|^{-p(a+1)+c}|w|^\mu \,dx - c_{15},
\end{aligned}
\end{equation}
which tends to $-\infty$ as $t\to +\infty$ since $\alpha_2p < \mu$. Then,
there exists $t_0>0$ such that $J(t_0w)<0$ and $\|t_0w\|_{a,p}>\rho$.
We set $\widehat{u} = t_0w$, then Lemma \ref{lem2.5} is proved.
\end{proof}

\begin{proof}[Proof of Theorem \ref{the2.3}]
By Lemmas \ref{lem2.4} and \ref{lem2.5}, all assumptions of the mountain
pass theorem in \cite{AmbRab} are satisfied. Then the functional $J$ has
a nontrivial critical point in $X$ and thus problem \eqref{e1.1} has a nontrivial
weak solution.
\end{proof}

Next, we will use the Fountain theorem and the Dual fountain theorem
in order to study the existence of infinitely many solution for \eqref{e1.1}.
More exactly, we will prove the following theorems.

\begin{theorem}\label{the2.6}
Assume that  {\rm (M1), (M2), (F0), (F2), (E1)} are satisfied. 
Moreover, we assume that
\begin{itemize}
\item[(F3)] $f(x,-t) = -f(x,t)$ for all $x \in \Omega$ and $t \in \mathbb{R}$.
\end{itemize}
Then problem \eqref{e1.1} has a sequence of weak solutions 
$\{\pm u_k\}_{k=1}^\infty$ such that $J(\pm u_k) \to +\infty$ as $k \to +\infty$.
\end{theorem}

\begin{theorem}\label{the2.7}
Assume that {\rm (M1), (M2), (F0)--(F2)} are satisfied.
 Moreover, we assume that
\begin{itemize}
\item[(F4)] $f(x,t) \geq C_2|t|^{r-1}$, $t \to 0$, where $\alpha_2p<r
<\min\{p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+1)p}\}$ for all $x \in
\Omega$ and $t \in \mathbb{R}$.
\end{itemize}
Then problem \eqref{e1.1} has a sequence of weak solutions 
$\{\pm v_k\}_{k=1}^\infty$ such that $J(\pm v_k)<0$ and $J(\pm v_k) \to 0
$ as $k \to +\infty$.
\end{theorem}

Because $X$ is a reflexive and separable Banach space, there exist 
$\{e_j\} \subset X$ and $\{e^\ast_j\}\subset X^\ast$ such that
$$
X = \overline{\operatorname{span}\{e_j: j = 1, 2, \dots , \}}, \quad
 X^\ast = \overline{\operatorname{span}\{e^\ast_j: j = 1, 2, \dots , \}},
$$
and
$$
\langle {e_i,e^\ast_j} \rangle  =
\begin{cases}
1, & \text{ if } i = j, \\
0, & \text{ if } i \ne j.
\end{cases}
$$
For convenience, we write $X_j = \operatorname{span}\{e_j\}$,
 $Y_k = \oplus_{j=1 }^kX_j$ and $Z_k = \oplus_{j=k}^\infty X_j$.

\begin{lemma}\label{lem2.8}
If $1<l < \min\{p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+1)p}\}$, denote
$$
\beta_k = \sup\{\|u\|_{L^l(\Omega,|x|^{-p(a+1)+c})}: \|u\|_{a,p}=1, u
\in Z_k\},
$$
then $\lim_{k\to \infty}\beta_k = 0$.
\end{lemma}

\begin{proof}
Obviously, for any $k$, $0<\beta_{k+1}\leq \beta_k$, so 
$\beta_k \to \beta \geq 0$ as $k \to \infty$. 
Let $u_k \in Z_k$, $k = 1, 2$, \dots  satisfy
$$
\|u_k\|_{a,p} = 1, \quad  0 \leq \beta_k-\|u_k\|_{L^l(\Omega,|x|^{-p
(a+1)+c})} < \frac{1}{k}.
$$
Then there exists a subsequence of $\{u_k\}$, still denoted by $\{u_k\}$
such that $\{u_k\}$ converges weakly to $u$ in $X$ and
$$
\langle {e^\ast_j,u} \rangle =\lim_{k\to \infty}\langle {e^\ast_j,
u_k} \rangle, \quad j = 1, 2, \dots ,
$$
which implies that $u=0$ and so $\{u_k\}$ converges weakly to $0$ in 
$X$ as $k \to \infty$. Since 
$1<l < \min\{p^\ast, \frac{p(N-(a+1)p+c)}{N-
(a+1)p}\}$, the embedding 
$X\hookrightarrow L^l(\Omega,|x|^{-p(a+ 1)+c})$ is compact 
(see Lemma \ref{lem1.1}), then $\{u_k\}$ converges
strongly to $0$ in $L^l(\Omega,|x|^{-p(a+1)+c})$. Hence, 
$\lim_{k\to \infty }\beta_k = 0$.
\end{proof}

\begin{lemma}[Fountain theorem \cite{Willem}]\label{lem2.9}
Assume that $(X,\|\cdot\|)$ is a separable Banach space, 
$J \in C^1(X,\mathbb{R})$ is an even functional satisfying the (PS) condition. 
Moreover, for each $k = 1, 2, \dots $, there exist $\rho_k >r_k>0$ such that
\begin{itemize}
\item[(A1)] $\inf_{\{u \in Z_k: \|u\|=r_k\}}J(u) \to +\infty$ as $k
\to \infty$;
\item[(A2)] $\max_{\{u \in Y_k: \|u\|=\rho_k\}}J(u) \leq 0$.
\end{itemize}
Then $J$ has a sequence of critical values which tends to $+\infty$.
\end{lemma}

\begin{definition}\label{def2.10}\rm
We say that $J$ satisfies the (PS)$^\ast_c$ condition (with respect to
$(Y_n)$) if any sequence $\{u_{n_j}\}\subset X$ such that $u_{n_j} \in
Y_{n_j}$, $J(u_{n_j})\to c$ and $(J|_{Y_{n_j}})'(u_{n_j})\to 0$  as $n_j
\to +\infty$, contains a subsequence converging to a critical point of $J$.
\end{definition}

\begin{lemma}[Dual fountain theorem \cite{Willem}]\label{lem2.11}
Assume that $(X,\|\cdot\|)$ is a separable Banach space, $J \in C^1(X,\mathbb{R})$ is
an even functional satisfying the (PS)$^\ast_c$ condition. Moreover, for
each $k=1, 2, \dots $, there exist ${\rho}_k >r_k>0$ such that
\begin{itemize}
\item[(B1)] $\inf_{\{u \in Z_k: \|u\|=\rho_k\}}J(u) \geq 0$;
\item[(B2)] $b_k: =\max_{\{u \in Y_k: \|u\|=r_k\}}J(u) < 0$;
\item[(B3)] $d_k :=\inf_{\{u \in Z_k: \|u\|=\rho_k\}}J(u) \to 0$ as $k \to
\infty$.
\end{itemize}
Then $J$ has a sequence of negative critical values which tends to $0$.
\end{lemma}

\begin{proof}[Proof of Theorem \ref{the2.6}]
According to (F3) and Lemma \ref{lem2.4}, $J$ is an even functional
and satisfies the (PS) condition. We will prove that if $k$ is large enough,
then there exist $\rho_k>r_k>0$ such that (A1) and (A2) hold.
Thus, the assertion of conclusion can be obtained from the Fountain
theorem.

(A1): From (F0), there exists $c_{16}>0$ such that
$$
|F(x,t)| \leq c_{16}(|t|+|t|^q) \quad\text{for all } 
x \in \Omega \text{ and all } t \in \mathbb{R}.
$$
Then, using (M1) and Lemma \ref{lem1.1}, for any $u \in Z_k$,
\begin{equation} \label{e2.21}
\begin{split}
J(u) & = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx
\Big)-\int_\Omega|x|^{-p(a+1)+c}F(x,u)\,dx \\
& \geq \frac{m_1}{p\alpha_1}\Big(\int_\Omega |x|^{-ap}|\nabla u|^p\,dx
\Big)^{\alpha_1}-c_{16}\int_\Omega|x|^{-p(a+1)+c}(|u|+|u|^q)\,dx \\
& \geq \frac{m_1}{p\alpha_1}\|u\|_{a,p}^{\alpha_1p}-c_{17}\beta_k^q
\|u\|_{a,p}^q-c_{17}\|u\|_{a,p},
\end{split}
\end{equation}
where
\begin{equation}\label{e2.22}
\beta_k = \sup\big\{\|u\|_{L^q(\Omega,|x|^{-p(a+1)+c})}: \|u\|_{a,p}=1,
u \in Z_k\big\}.
\end{equation}
Now, we deduce from \eqref{e2.21} that for any $u \in Z_k$,
 $\|u\|_{a,p} = r_k = \Big(\frac{c_{17}q\beta_k^q}{m_1}\Big)^\frac{1}{\alpha_1p-q}$,
\begin{equation} \label{e2.23}
\begin{split}
J(u) & \geq \frac{m_1}{p\alpha_1}\|u\|_{a,p}^{\alpha_1p}-c_{17}\beta_k^q
\|u\|_{a,p}^q-c_{17}\|u\|_{a,p}\\
& = \frac{m_1}{p\alpha_1}\Big(\frac{c_{17}q\beta_k^q}{m_1}\Big)^{
\frac{\alpha_1p}{\alpha_1p-q}}
- c_{17}\beta_k^q\Big(\frac{c_{17}q{\beta }_k^q}{m_1}\Big)^{\frac{q}{\alpha_1p-q}}
-c_{17}\Big(\frac{c_{17}q{\beta}_k^q}{m_1}\Big)^\frac{1}{\alpha_1p-q} \\
& = m_1\Big(\frac{1}{\alpha_1p}-\frac{1}{q}\Big)\Big(\frac{c_{17}q\beta_k^q
}{m_1}\Big)^\frac{\alpha_1p}{\alpha_1p-q}-c_{17}\Big(\frac{c_{17}q{\beta
}_k^q}{m_1}\Big)^\frac{1}{\alpha_1p-q},
\end{split}
\end{equation}
which tends to $+\infty$ as $k \to +\infty$, because $\alpha_1p<q<\min
\{p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+1)p}\}$ and $\beta_k \to 0$
as $k \to \infty$, see Lemma \ref{lem2.8}.

(A2): From (F2), there exists a constant $c_{18}>0$ such that
$$
F(x,t) \geq c_{18}|t|^\mu - c_{18} \quad
\text{for all } x \in \Omega \text{ and } t \in \mathbb{R}.
$$
Therefore, using (M1), for any $w \in Y_k$ with $\|w\|_{a,p} = 1$ and
$1 < t < \rho_k$, we have
\begin{equation} \label{e2.24}
\begin{split}
J(tw) & = \frac{1}{p}\widehat{M}
\Big(\int_\Omega |x|^{-ap}|\nabla tw|^p\,dx \Big)
 -\int_\Omega|x|^{-p(a+1)+c}F(x,tw)\,dx \\
& \leq \frac{m_2}{\alpha_2p}\Big(\int_\Omega |x|^{-ap}|\nabla tw|^p\,dx
\Big)^{\alpha_2}-c_{18}\int_\Omega |x|^{-p(a+1)+c}|tw|^\mu \,dx-c_{19} \\
& =\frac{m_2t^{\alpha_2p}}{\alpha_2p}\|w\|_{a,p}^{\alpha_2p}-c_{18}t^\mu
{\int}_\Omega |x|^{-p(a+1)+c}|w|^\mu \,dx-c_{19}.
\end{split}
\end{equation}
Since $\mu > \alpha_2p$ and dim$(Y_k)=k$, it is easy to see that $J(u)
\to -\infty$ as $\|u\|_{a,p} \to +\infty$ for $u \in Y_k$.
\end{proof}

To prove Theorem \ref{the2.7}, we need to verify the following
lemma.

\begin{lemma}\label{lem2.12}
Assume that  {\rm (M1), (M2), (F0), (F2)} are
satisfied. Then the functional $J$ satisfies the $(PS)^\ast_c$ condition.
\end{lemma}

\begin{proof}
Let $\{u_{n_j}\}\subset X$ be such that $u_{n_j} \in Y_{n_j}$ and $J(u_{
n_j})\to 0$ and $(J|_{Y_{n_j}})'(u_{n_j}) \to 0$ as $n_j\to \infty$. Similar
to the process of verifying the (PS) condition in the proof of Lemma
\ref{lem2.4}, we can get the boundedness of $\{\|u_{n_j}\|_{a,p}\}$.
Going, if necessary, to a subsequence, we can assume that $\{u_{n_j
}\}$ converges weakly to $u$ in $X$. As $X = \overline{\cup_{n_j}Y_{
n_j}}$, we can choose $v_{n_j} \in Y_{n_j}$ such that $v_{n_j}\to u$.
Hence,
\begin{equation} \label{e2.25}
\begin{split}
\lim_{n_j\to \infty} J'(u_{n_j})(u_{n_j}-u) & = \lim_{n_j\to \infty} J'(u_{n_j})
(u_{n_j}-v_{n_j})+\lim_{n_j\to \infty} J'(u_{n_j})(v_{n_j}-u) \\
& = \lim_{n_j\to \infty} (J|_{Y_{n_j}})'(u_{n_j})(u_{n_j}-v_{n_j}) = 0.
\end{split}
\end{equation}
From the proof of Lemma \ref{lem2.4}, $J'$ is of $(S_+)$ type, so we
can conclude that $u_{n_j} \to u$ as $n_j\to \infty$, furthermore we
have $J'(u_{n_j})\to J'(u)$.

Let us prove $J'(u) = 0$, i.e., $u$ is a critical point of $J$. Indeed, taking
arbitrarily $w_k \in Y_k$, notice that when $n_j \geq k$ we have
\begin{equation} \label{e2.26}
\begin{split}
J'(u)(w_k) & = (J'(u)-J'(u_{n_j}))(w_k)+J'(u_{n_j})(w_k) \\
& =(J'(u)-J'(u_{n_j}))(w_k)+(J|_{Y_{n_j}})'(u_{n_j})(w_k).
\end{split}
\end{equation}
Going to limit in the right hand-side of \eqref{e2.26} reaches $J'(u)(w_k)=
0$ for all $w_k \in Y_k$. Thus, $J'(u)=0$ and the functional $J$ satisfies
the (PS)$^\ast_c$ condition for every $c\in \mathbb{R}$.
\end{proof}

\begin{proof}[Proof of Theorem \ref{the2.7}]
From (F0), (F2), (F3) and Lemma \ref{lem2.12}, we know that
$J$ is an even functional and satisfies the (PS)$^\ast_c$ condition, the assertion
of conclusion can be obtained from Dual fountain theorem.

(B1): For any $v \in Z_k$, $\|v\|_{a,p}=1$ and $0<t<1$, using (M1) 
and \eqref{e2.18}, we have
\begin{equation} \label{e2.27}
\begin{split}
&J(tv) \\
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla tv|^p\,dx
\Big)-\int_\Omega|x|^{-p(a+1)+c}F(x,tv)\,dx \\
& \geq \frac{m_1}{\alpha_1p}t^{\alpha_1p}\|v\|_{a,p}^{\alpha_1p}-
\epsilon t^{\alpha_1p}\int_\Omega |x|^{-p(a+1)+c}|v|^{\alpha_1p}\,dx-
c_\epsilon t^q\int_\Omega|x|^{-p(a+1)+c} |v|^q\,dx \\
& \geq \Big(\frac{m_1}{\alpha_1p}-\epsilon c_{20}\Big)t^{\alpha_1p}
-c_{21}\beta_k^q t^q.
\end{split}
\end{equation}
Let $0<\epsilon < \frac{M_1}{\alpha_1pc_{20}}$. Since $q>\alpha_1p$,
taking $\rho_k = t$ small enough and sufficiently large $k$, for
 $v \in Z_k$ with $\|v\|_{a,p} = 1$, we have $J(tv)\geq 0$. So for sufficiently
large $k$,
$$
\inf_{\{u \in Z_k: \|u\|_{a,p} = \rho_k\}} J(u) \geq 0;
$$
i.e., (B1) is satisifed.

(B2): For $v \in Y_k$, $\|v\|_{a,p}=1$ and $0 < t < \rho_k < 1$, we
have
\begin{equation} \label{e2.28}
\begin{split}
J(tv)
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega |x|^{-ap}|\nabla tv|^p
\,dx\Big)-\int_\Omega|x|^{-p(a+1)+c}F(x,tv)\,dx \\
& \leq \frac{m_2}{\alpha_2p}\Big(\int_\Omega |x|^{-ap}|\nabla tv|^p\,dx
\Big)^{\alpha_2} - C_2\int_\Omega |x|^{-p(a+1)+c}|tv|^{r}\,dx \\
& = \frac{m_2}{\alpha_2p}t^{\alpha_2p}\|v\|_{a,p}^{\alpha_2p}-C_2t^r
\int_{\Omega} |x|^{-p(a+1)+c}|v|^{r}\,dx.
\end{split}
\end{equation}
Condition $\alpha_2p<r<\min\{p^\ast, \frac{p(N-(a+1)p+c)}{N-(a+
1)p}\}$ implies that there exists a constant $r_k \in (0,{\rho}_k)$
such that $J(tv)<0$ when $t = r_k$. Hence, we obtain from \eqref{e2.28}
that
$$
b_k : = \max_{\{u \in Y_k: \|u\|_{a,p} = r_k\}}J(u) < 0,
$$
so (B2) is satisfied.

(B3): Because $Y_k\cap Z_k \ne \emptyset$ and $r_k < \rho_k$
we have
\begin{equation}\label{e2.29}
d_k : = \inf_{\{u \in Z_k: \|u\|_{a,p}\leq \rho_k\}}J(u)\leq b_k:=\max_{\{u
\in Y_k: \|u\|_{a,p}=r_k\}}J(u)<0.
\end{equation}
From \eqref{e2.27}, for $v \in Z_k$, $\|v\|_{a,p}=1$, $0 \leq t \leq \rho_k$
and $u = tv$ we have
\begin{equation} \label{e2.30}
\begin{split}
J(u) & = J(tv) \\
&\geq \Big(\frac{m_1}{\alpha_1p}-\epsilon c_{20}\Big)t^{\alpha_1p} -
c_{21}\beta_k^q t^q \\
& \geq - c_{21}\beta_k^qt^q.
\end{split}
\end{equation}
From \eqref{e2.29} and \eqref{e2.30}, $d_k \to 0$ as $k \to \infty$; i.e.,
(B3) is satisfied.
\end{proof}

\subsection*{Acknowledgments}
The authors would like to thank the anonymous referees for their suggestions 
and helpful comments which improved the presentation of the original manuscript.
The paper was done when the first author was working at the Division of
Mathematical Sciences, School of Physical and Mathematical Sciences,
Nanyang Technological University, Singapore, as a Research Fellow.
This work was supported by Vietnam National Foundation for Science and
Technology Development (NAFOSTED).


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\end{thebibliography}

\section{Corrigendum posted on August 21, 2014}

A reader pointed out that no function $M(t)$ can satisfy both hypotheses
(M1) and (M2). In response, we present a proof of our results with a modified
assumption (F2), and without assumption (M2).

\subsection*{Modified assumptions}
We delete the assumption (M2), and re-state the following:
\begin{itemize}
\item [(M1)] There exist $m_2\geq m_1 > 0$ and $\alpha> 1$ such that
$$
m_1t^{\alpha-1} \leq M(t) \leq m_2t^{\alpha-1}, \quad \forall t \in \mathbb{R}^+
$$
(The original (M1) implies $\alpha_1=\alpha_2$, so we rename constant $\alpha$.);

\item[(F2)] There exists a positive constant $\mu > \frac{m_2}{m_1}\alpha p$ 
such that
$$
0< \mu F(x,t) = \mu\int_0^t f(x,s)\,ds \leq f(x,t)t
$$
for all $x\in \Omega$ and $|t| \geq T>0$
(The constant $\mu$ has been redefined);
\end{itemize}

\subsection*{New Lemma 2.4}
\textit{Assume that} (M1), (F0), (F2) \textit{are satisfied. Then
the functional $J$ satisfies the Palais-Smale condition in the space $X$.}

\begin{proof} Let $\{u_m\}\subset X$ be a sequence such that
\begin{equation}\label{e3n}
J(u_m) \to \overline c<\infty, \quad J'(u_m) \to 0 \quad\text{in }X^\ast\text{ as }
 m\to \infty,
\end{equation}
where $X^\ast$ is the dual space of $X$.

We shall show that the sequence $\{u_m\}$ is bounded in $X$. Indeed, from (\ref{e3n}), (M1) and (F2),  for all $m$ large enough, we have
\begin{align}\label{e4n}
\begin{split}
&1+\overline c +\|u_m\|_{a,p} \\
& \geq J(u_m)-\frac{1}{\mu}J'(u_m)(u_m) \\
& = \frac{1}{p}\widehat{M}\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)
- \frac{1}{\mu} M\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)
 \int_\Omega |x|^{-ap}|\nabla u_m|^p\,dx\\
& \quad -\int_\Omega |x|^{-p(a+1)+c}F(x,u_m)\,dx
 +\frac{1}{\mu} \int_\Omega |x|^{-p(a+1)+c}f(x,u_m)u_m\,dx \\
& \geq \frac{m_1}{\alpha p}
 \Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)^\alpha
- \frac{m_2}{\mu}\Big(\int_\Omega|x|^{-ap}|\nabla u_m|^p\,dx\Big)^\alpha \\
& \quad -\int_\Omega |x|^{-p(a+1)+c}\big(\frac{1}{\mu}f(x,u_m)u_m-F(x,u_m)\big)\,dx \\
& \geq \big(\frac{m_1}{\alpha p}-\frac{m_2}{\mu}\big)\|u_m\|^{\alpha p}_{a,p}-c_4.
\end{split}
\end{align}
Since $\alpha p>1$ and $\mu > \frac{m_2}{m_1}\alpha p$,
from \eqref{e4n}  it follows  that $\{u_m\}$ is bounded.
Then with similar arguments as in the proof of the original Lemma 2.4 we can show that
$J$ satisfies the Palais-Smale condition.
\end{proof}

Theorem 2.2 remains unchanged. However,
Theorems 2.3, 2.6, 2.7 and Lemma 2.12 need to be stated without assumption (M2).
Their proofs are similar to the original proofs, but using the new Lemma 2.4,
and replacing  $\alpha_1$ and $\alpha_2$ by $\alpha$.
\smallskip

The authors would like to thank anonymous reader and the editor for
allowing us to correct our mistake.


\end{document}