Existence and multiplicity of solutions for equations involving nonhomogeneous operators of $p(x)$-Laplace type in ${\mathbb{R}}^N$

We are concerned with the following elliptic equations with variable exponents: $-div(\phi (x,\mathrm{\nabla }u))+{|u|}^{p(x)-2}u=\lambda f(x,u)$ in ${\mathbb{R}}^N$, where the function $\phi (x,v)$ is of type ${|v|}^{p(x)-2}v$ with continuous function $p:{\mathbb{R}}^N\to (1,\mathrm{\infty })$ and $f:{\mathbb{R}}^N\times \mathbb{R}\to \mathbb{R}$ satisfies a Carathéodory condition. The purpose of this paper is to show the existence of at least one solution, and under suitable assumptions, infinitely many solutions for the problem above by using mountain pass theorem and fountain theorem.

MSC: 35D30, 35J60, 35J90, 35P30, 46E35.

The differential equations and variational problems with $p(x)$-growth conditions have been much interest in recent years since they can model physical phenomena which arise in the study of elastic mechanics, electro-rheological fluid dynamics and image processing, etc. We refer the readers to [1]–[4] and references therein.

In this paper, we establish some results about the existence and multiplicity of nontrivial weak solution to nonlinear elliptic equations of the $p(x)$-Laplacian type,

where the function $\phi (x,v)$ is of type $|v{|}^{p(x)-2}v$ with continuous function $p:{\mathbb{R}}^N\to (1,\mathrm{\infty })$ and $f:{\mathbb{R}}^N\times \mathbb{R}\to \mathbb{R}$ satisfies a Carathéodory condition. The essential interest in studying problem (B) starts from the presence of the $p(x)$-Laplace type operator $div(\phi (x,\mathrm{\nabla }u))$, which is small perturbation of the $p(x)$-Laplace operator $div({|\mathrm{\nabla }u|}^{p(x)-2}\mathrm{\nabla }u)$. The study for the $p(x)$-Laplacian problems has been extensively considered by several authors in various ways; see for example [5]–[8] and references therein. Fan and Zhang [6] established the existence of solutions for the $p(x)$-Laplacian Dirichlet problems on bounded domains by using the variational method. For the case of the entire domain ${\mathbb{R}}^N$, the existence and multiplicity results of solutions for the $p(x)$-Laplacian equations have been discussed in [5]. Concerning the $p(x)$-Laplace type operator, Mihăilescu and Rădulescu in [3] investigated a multiplicity result for quasilinear nonhomogeneous problems with Dirichlet boundary conditions by adequate variational methods and a variant of mountain pass theorem which are crucial tools for finding solutions to elliptic problems. In particular, in order to obtain the existence of solutions for equations like (B) in [3], they assume that the functional Φ induced by φ is uniform convex, that is, there exists a constant $k>0$ such that

for all $x\in \overline{\mathrm{\Omega }}$ and $\xi ,\eta \in {\mathbb{R}}^N$, where Ω is a bounded domain in ${\mathbb{R}}^N$. When $p(x)\equiv p$ and $1<p<2$, it is well known that this condition is not applicable for the p-Laplacian problems because the function $\mathrm{\Phi }(x,t)=t^p$ is not uniformly convex for $t>0$. Recently the authors in [9] have studied the existence of infinitely many solutions for a class of quasilinear elliptic problems involving the $p(x)$-Laplace type operator with nonlinear boundary conditions without using the uniform convexity of Φ.

The aim of this paper is to show the existence of at least one nontrivial solution and infinitely many nontrivial solutions for problem (B) without the assumption of the uniform convexity of the functional Φ as in [9]; see also [10]. We give our main results in a more general setting than those of [5], [6] because (B) is a problem which involves the usual $p(x)$-Laplacian operator. Especially, our proof as regards the existence of infinitely many nontrivial solutions for (B) is different from those of [5], [6], [9].

This paper is organized as follows. In Section 2, we state some basic results for the variable exponent Lebesgue-Sobolev spaces. In Section 3, under certain conditions on φ and f, we establish several existence results of nontrivial weak solutions for problem (B) by employing as the main tools the variational principle.

In this section, we recall some definitions and basic properties of the variable exponent Lebesgue spaces $L^{p(\cdot )}({\mathbb{R}}^N)$ and the variable exponent Lebesgue-Sobolev spaces $W^{1,p(\cdot )}({\mathbb{R}}^N)$ which will be treated in the next sections. For a deeper treatment on these spaces, we refer to [11]–[13].

Set

For any $h\in C_{+}({\mathbb{R}}^N)$, we define

For any $p\in C_{+}({\mathbb{R}}^N)$, we introduce the variable exponent Lebesgue space

endowed with the Luxemburg norm

The dual space of $L^{p(\cdot )}({\mathbb{R}}^N)$ is $L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$, where $1/p(x)+1/p^{\prime }(x)=1$.

The variable exponent Sobolev space $W^{1,p(\cdot )}({\mathbb{R}}^N)$ is defined by

where the norm is

It has the following equivalent norm:

Lemma 2.1

([11])

The space$L^{p(\cdot )}({\mathbb{R}}^N)$is a separable, uniformly convex Banach space, and its conjugate space is$L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$where$1/p(x)+1/p^{\prime }(x)=1$. For any$u\in L^{p(\cdot )}({\mathbb{R}}^N)$and$v\in L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$, we have

Lemma 2.2

If$1/p(x)+1/q(x)+1/r(x)=1$, then for any$u\in L^{p(\cdot )}({\mathbb{R}}^N)$, $v\in L^{q(\cdot )}({\mathbb{R}}^N)$, and$w\in L^{r(\cdot )}({\mathbb{R}}^N)$,

Lemma 2.3

([11])

Denote

Then

1. (1)

   $\rho (u)>1$ (=1; <1) if and only if ${\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}>1$ (=1; <1), respectively;

2. (2)

   if ${\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}>1$, then ${\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}^{p_{-}}\le \rho (u)\le {\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}^{p_{+}}$;

3. (3)

   if ${\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}<1$, then ${\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}^{p_{+}}\le \rho (u)\le {\parallel u\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}^{p_{-}}$.

Remark 2.4

([5])

Denote

Then

1. (1)

   $\rho (u)>1$ (=1; <1) if and only if ${\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}>1$ (=1; <1), respectively;

2. (2)

   if ${\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}>1$, then ${\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}^{p_{-}}\le \rho (u)\le {\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}^{p_{+}}$;

3. (3)

   if ${\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}<1$, then ${\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}^{p_{+}}\le \rho (u)\le {\parallel u\parallel }_{W^{1,p(\cdot )}({\mathbb{R}}^N)}^{p_{-}}$.

Lemma 2.5

([13])

Let$q\in L^{\mathrm{\infty }}({\mathbb{R}}^N)$be such that$1\le p(x)q(x)\le \mathrm{\infty }$, for almost all$x\in {\mathbb{R}}^N$. If$u\in L^{q(\cdot )}({\mathbb{R}}^N)$with$u\ne 0$, then

1. (1)

   if ${\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}>1$, then ${\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}^{q_{-}}\le {\parallel |u{|}^{q(x)}\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}\le {\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}^{q_{+}}$;

2. (2)

   if ${\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}<1$, then ${\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}^{q_{+}}\le {\parallel |u{|}^{q(x)}\parallel }_{L^{p(\cdot )}({\mathbb{R}}^N)}\le {\parallel u\parallel }_{L^{p(\cdot )q(\cdot )}({\mathbb{R}}^N)}^{q_{-}}$.

Lemma 2.6

([12], [14])

Let$\mathrm{\Omega }\subset {\mathbb{R}}^N$be an open, bounded set with Lipschitz boundary and let$p\in C_{+}(\overline{\mathrm{\Omega }})$with$1<p_{-}\le p_{+}<\mathrm{\infty }$. If$q\in L^{\mathrm{\infty }}(\mathrm{\Omega })$with$q_{-}>1$satisfies

for all$x\in \mathrm{\Omega }$, then we have

and the imbedding is compact if${inf}_{x\in \mathrm{\Omega }}(p^{\ast }(x)-q(x))>0$.

Lemma 2.7

([14])

Suppose that$p:{\mathbb{R}}^N\to \mathbb{R}$is Lipschitz continuous with$1<p_{-}\le p_{+}<N$. Let$q\in L^{\mathrm{\infty }}({\mathbb{R}}^N)$and$p(x)\le q(x)\le p^{\ast }(x)$, for almost all$x\in {\mathbb{R}}^N$. Then there is a continuous embedding$W^{1,p(\cdot )}({\mathbb{R}}^N)\hookrightarrow L^{q(\cdot )}({\mathbb{R}}^N)$.

In what follows, let $p\in C_{+}({\mathbb{R}}^N)$ be Lipschitz continuous with $1<p_{-}\le p_{+}<N$. We denote by the space $X:=W^{1,p(\cdot )}({\mathbb{R}}^N)$, and $X^{\ast }$ be a dual space of X. Furthermore, $〈\cdot ,\cdot 〉$ denotes the pairing of X and its dual $X^{\ast }$ and Euclidean scalar product on ${\mathbb{R}}^N$, respectively.

In this section, we shall give the proof of the existence of nontrivial weak solutions for problem (B), by applying the mountain pass theorem, fountain theorem, and the basic properties of the spaces $L^{p(\cdot )}({\mathbb{R}}^N)$ and $W^{1,p(\cdot )}({\mathbb{R}}^N)$.

Definition 3.1

We say that $u\in X$ is a weak solution of problem (B) if

for all $v\in X$.

We assume that $\phi (x,v):{\mathbb{R}}^N\times {\mathbb{R}}^N\to {\mathbb{R}}^N$ is the continuous derivative with respect to v of the mapping ${\mathrm{\Phi }}_0:{\mathbb{R}}^N\times {\mathbb{R}}^N\to \mathbb{R}$, ${\mathrm{\Phi }}_0={\mathrm{\Phi }}_0(x,v)$, that is, $\phi (x,v)=\frac{d}{dv}{\mathrm{\Phi }}_0(x,v)$. Suppose that φ and ${\mathrm{\Phi }}_0$ satisfy the following assumptions:

(J1) The equalities

hold, for almost all $x\in {\mathbb{R}}^N$ and for all $v\in {\mathbb{R}}^N$.

(J2)$\phi :{\mathbb{R}}^N\times {\mathbb{R}}^N\to {\mathbb{R}}^N$ satisfies the following conditions: $\phi (\cdot ,v)$ is measurable, for all $v\in {\mathbb{R}}^N$, and $\phi (x,\cdot )$ is continuous, for almost all $x\in {\mathbb{R}}^N$.

(J3) There are a function $a\in L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$ and a nonnegative constant b such that

for almost all $x\in {\mathbb{R}}^N$ and for all $v\in {\mathbb{R}}^N$.

(J4)${\mathrm{\Phi }}_0(x,\cdot )$ is strictly convex in ${\mathbb{R}}^N$, for all $x\in {\mathbb{R}}^N$.

(J5) The relation

holds, for all $x\in {\mathbb{R}}^N$ and $v\in {\mathbb{R}}^N$, where d is a positive constant.

Let us define the functional $\mathrm{\Phi }:X\to \mathbb{R}$ by

The analog of the following lemma can be found in [3]. However, we will give the proof of those because our growth condition is slightly different from that of [3].

Lemma 3.2

Assume that (J1)-(J3) and (J5) hold. Then the functional Φ is well defined on X, $\mathrm{\Phi }\in C^1(X,\mathbb{R})$and its Fréchet derivative is given by

Proof

A simple calculation as in [3] implies that the functional Φ is well defined on X. For a fixed $x\in {\mathbb{R}}^N$, it is clear that ${\mathrm{\Phi }}_0\in C^1({\mathbb{R}}^N,\mathbb{R})$. Let $u,v\in X$, then given $x\in {\mathbb{R}}^N$ and $0<|t|<1$, by the classical mean value theorem, there exist ${\theta }_1,{\theta }_2\in \mathbb{R}$ with $0<|{\theta }_1|<|t|$ and $0<|{\theta }_2|<|t|$ such that

and

Since

it is easy to obtain

for a positive constant C. Hence $|a+b{(|\mathrm{\nabla }u|+|\mathrm{\nabla }v|)}^{p(\cdot )-1}||\mathrm{\nabla }v|\in L^1({\mathbb{R}}^N)$. Since $t\to 0$ implies ${\theta }_1\to 0$ and ${\theta }_2\to 0$, it follows from the Lebesgue dominated convergence theorem that

Let ${\mathrm{\Lambda }}_1:X\to L^{p^{\prime }(\cdot )}({\mathbb{R}}^N;{\mathbb{R}}^N)$ and ${\mathrm{\Lambda }}_2:X\to L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$ be an operators defined by

Then the operators ${\mathrm{\Lambda }}_1$ and ${\mathrm{\Lambda }}_2$ are continuous on X. In fact, for any $u\in X$, let $u_n\to u$ in X as $n\to \mathrm{\infty }$. Then there exist a subsequence $\{u_{n_k}\}$ and functions v, $w_j$ in $L^{p(\cdot )}({\mathbb{R}}^N)$ for $j=i,\dots ,N$ such that $u_{n_k}(x)\to u(x)$ as $k\to \mathrm{\infty }$, and $|u_{n_k}(x)|\le v(x)$ and $|(\partial u_{n_k}/\partial x_j)(x)|\le w_j(x)$, for all $k\in \mathbb{N}$ and for almost all $x\in {\mathbb{R}}^N$. Without loss of generality, we assume that ${\parallel {\mathrm{\Lambda }}_1(u_{n_k})-{\mathrm{\Lambda }}_1(u)\parallel }_{L^{p^{\prime }(\cdot )}({\mathbb{R}}^N;{\mathbb{R}}^N)}<1$ and ${\parallel {\mathrm{\Lambda }}_2(u_{n_k})-{\mathrm{\Lambda }}_2(u)\parallel }_{L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)}<1$. Then we have

and

Hence (J3) implies that the integrands at the right-hand sides in the above estimates are dominated by integrable functions. Since the function φ satisfies (J2) and $u_{n_k}\to u$ in X as $k\to \mathrm{\infty }$, we obtain $\phi (x,\mathrm{\nabla }{u}_{n_k}(x))\to \phi (x,\mathrm{\nabla }u(x))$ and ${|u_{n_k}(x)|}^{p(x)-2}{u}_{n_k}(x)\to {|u(x)|}^{p(x)-2}u(x)$ as $k\to \mathrm{\infty }$, for almost all $x\in {\mathbb{R}}^N$. Therefore, the Lebesgue dominated convergence theorem tells us that ${\mathrm{\Lambda }}_1(u_{n_k})\to {\mathrm{\Lambda }}_1(u)$ in $L^{p^{\prime }(\cdot )}({\mathbb{R}}^N;{\mathbb{R}}^N)$ and ${\mathrm{\Lambda }}_2(u_{n_k})\to {\mathrm{\Lambda }}_2(u)$ in $L^{p^{\prime }(\cdot )}({\mathbb{R}}^N)$ as $k\to \mathrm{\infty }$. Thus, ${\mathrm{\Lambda }}_1$ and ${\mathrm{\Lambda }}_2$ are continuous on X. From the Hölder inequality, we have

for all $v\in X$, and thus

Consequently, the operator ${\mathrm{\Phi }}^{\prime }$ is continuous on X. □

Now we will show that the operator ${\mathrm{\Phi }}^{\prime }$ is a mapping of type $(S_{+})$, which plays a key role in obtaining our main results. To do this, we first prove the following useful result.

Lemma 3.3

Assume that (J1)-(J5) hold. If the sequence$\{v_n\}$in${\mathbb{R}}^N$such that

as$n\to \mathrm{\infty }$, for$v\in {\mathbb{R}}^N$and for almost all$x\in {\mathbb{R}}^N$, then$v_n\to v$in${\mathbb{R}}^N$as$n\to \mathrm{\infty }$.

Proof

Let $\{v_{n_k}\}$ be a subsequence of the sequence $\{v_n\}$ in ${\mathbb{R}}^N$ satisfied

as $k\to \mathrm{\infty }$ for any $v\in {\mathbb{R}}^N$. Then there exists $M>0$ such that, for almost all $x\in {\mathbb{R}}^N$,

This together with assumptions (J3), (J5), and Young’s inequality imply that

for almost all $x\in {\mathbb{R}}^N$, and hence

for almost all $x\in {\mathbb{R}}^N$, where d is the positive constant from (J5). Since $d>0$, the sequence $\{|v_{n_k}|\}$ is bounded, and then the sequence $\{v_{n_k}\}$ is bounded in ${\mathbb{R}}^N$. By passing to a subsequence, we can assume that $v_{n_k}\to \xi$ as $k\to \mathrm{\infty }$, for some $\xi \in {\mathbb{R}}^N$. Then we obtain $\phi (x,v_{n_k})\to \phi (x,\xi )$ as $k\to \mathrm{\infty }$ and the relation (3.2) implies that

Since it follows from assumption (J4) and Proposition 25.10 in [15] that φ is monotone on X, this relation occurs only if $\xi =v$, that is, $v_n\to v$ in ${\mathbb{R}}^N$ as $n\to \mathrm{\infty }$. Since these arguments hold for any subsequence of the sequence $\{v_n\}$, we conclude that $v_n\to v$ in ${\mathbb{R}}^N$ as $n\to \mathrm{\infty }$. □

Next we give the following assertion, which is based on the idea of the proof in [16]; see [17] for the case of bounded domain in ${\mathbb{R}}^N$.

Lemma 3.4

Assume that (J1)-(J5) hold. Then the functional$\mathrm{\Phi }:X\to \mathbb{R}$is convex and weakly lower semicontinuous on X. Moreover, the operator${\mathrm{\Phi }}^{\prime }$is a mapping of type$(S_{+})$, i.e., if$u_n\rightharpoonup u$in X as$n\to \mathrm{\infty }$and$lim{sup}_{n\to \mathrm{\infty }}〈{\mathrm{\Phi }}^{\prime }(u_n)-{\mathrm{\Phi }}^{\prime }(u),u_n-u〉\le 0$, then$u_n\to u$in X as$n\to \mathrm{\infty }$.

Proof

Let $\{u_n\}$ be a sequence in X such that $u_n\rightharpoonup u$ in X as $n\to \mathrm{\infty }$ and

It follows from $u_n\rightharpoonup u$ in X as $n\to \mathrm{\infty }$ that $〈{\mathrm{\Phi }}^{\prime }(u),u_n-u〉\to 0$ as $n\to \mathrm{\infty }$. Since Φ is strictly convex by (J4), it is obvious that the operator ${\mathrm{\Phi }}^{\prime }$ is monotone, that is,

By (3.3) and (3.4), we have

Hence the sequences $\{〈\phi (x,\mathrm{\nabla }{u}_n)-\phi (x,\mathrm{\nabla }u),\mathrm{\nabla }{u}_n-\mathrm{\nabla }u〉\}$ and $\{(|u_n{|}^{p(x)-2}{u}_n-|u{|}^{p(x)-2}u)(u_n-u)\}$ converge to 0 in $L^1({\mathbb{R}}^N;{\mathbb{R}}^N)$ and $L^1({\mathbb{R}}^N)$ as $n\to \mathrm{\infty }$, respectively. By Lemma 3.3, we have $\mathrm{\nabla }{u}_n(x)\to \mathrm{\nabla }u(x)$ in ${\mathbb{R}}^N$ and $u_n(x)\to u(x)$ in ℝ as $n\to \mathrm{\infty }$, for almost all $x\in {\mathbb{R}}^N$. Then (3.3) holds in the stronger form

It follows from the convexity of Φ that

and hence we obtain $\mathrm{\Phi }(u)\ge {lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}\mathrm{\Phi }(u_n)$ by (3.5). Since the functional Φ is strictly convex and $C^1$-functional on X, it follows that Φ is weakly lower semicontinuous on X. Then it is immediate that $\mathrm{\Phi }(u)\le {lim\hspace{0.17em}inf}_{n\to \mathrm{\infty }}\mathrm{\Phi }(u_n)$. Thus it implies

Consider the sequence $\{h_n\}$ in $L^1({\mathbb{R}}^N)$ defined pointwise by

From (J1) and (J4), it is clear that the sequence $h_n\ge 0$. Since ${\mathrm{\Phi }}_0(x,\cdot )$ is continuous, for almost all $x\in {\mathbb{R}}^N$, we obtain $h_n(x)\to {\mathrm{\Phi }}_0(x,\mathrm{\nabla }u)+(1/p(x))|u(x)|$ as $n\to \mathrm{\infty }$, for almost all $x\in {\mathbb{R}}^N$. Hence, by the Fatou lemma and (3.6), we have

Thus we get

that is,

Then by assumption (J5), ${lim}_{n\to \mathrm{\infty }}{\parallel u_n-u\parallel }_X=0$, we conclude that $u_n\to u$ in X as $n\to \mathrm{\infty }$. □

Until now, we considered some properties for the integral operator corresponding to the divergence part in problem (B). To deal with our main results in this section, we need the following assumptions for f. Denoting $F(x,t)={\int }_0^{t}f(x,s)ds$, we assume that

(H1)$p,q\in C_{+}({\mathbb{R}}^N)$, $p(x)<N$, and $1<p_{-}\le p_{+}<q_{-}\le q_{+}<p^{\ast }(x)$, for all $x\in {\mathbb{R}}^N$.

(H2)$m\in L^{\frac{r(\cdot )}{r(\cdot )-q(\cdot )}}({\mathbb{R}}^N)\cap L^{\mathrm{\infty }}({\mathbb{R}}^N)$, for some $r\in C_{+}({\mathbb{R}}^N)$ with $q(x)<r(x)<p^{\ast }(x)$ and $meas\{x\in {\mathbb{R}}^N:m(x)>0\}>0$, for all $x\in {\mathbb{R}}^N$.

(F1)$f:{\mathbb{R}}^N\times \mathbb{R}\to \mathbb{R}$ satisfies the Carathéodory condition in the sense that $f(\cdot ,t)$ is measurable, for all $t\in \mathbb{R}$, and $f(x,\cdot )$ is continuous, for almost all $x\in {\mathbb{R}}^N$.

(F2)f satisfies the following growth condition: For all $(x,t)\in {\mathbb{R}}^N\times \mathbb{R}$,

where q and m are given in (H1) and (H2), respectively.

(F3) There exists a positive constant θ such that $\theta >p_{+}$ and

(F4)$f(x,t)=o({|t|}^{p_{+}-1})$, as $|t|\to 0$ uniformly, for all $x\in {\mathbb{R}}^N$.

Then it follows from assumption (F2) that

(F2^′):$|F(x,t)|\le \frac{|m(x)|}{q(x)}|t{|}^{q(x)}$, for all $(x,t)\in {\mathbb{R}}^N\times \mathbb{R}$.

Define the functional $\mathrm{\Psi }:X\to \mathbb{R}$ by

Then it is easy to check that $\mathrm{\Psi }\in C^1(X,\mathbb{R})$ and its Fréchet derivative is

for any $u,v\in X$. Next we define the functional $I_{\lambda }:X\to \mathbb{R}$ by

Then it follows that the functional $I_{\lambda }\in C^1(X,{\mathbb{R}}^N)$ and its Fréchet derivative is

for any $u,v\in X$.

Lemma 3.5

Assume that (H1)-(H2) and (F2) hold. Then Ψ and${\mathrm{\Psi }}^{\prime }$are weakly strongly continuous on X.

Proof

Proceeding the argument analogous to Lemma 3.2 of [5], it implies that the functionals Ψ and ${\mathrm{\Psi }}^{\prime }$ are weakly strongly continuous on X. □

With the aid of Lemma 3.5, we prove that the energy functional $I_{\lambda }$ satisfies the Palais-Smale condition ((PS)-condition for short). This plays a key role in obtaining the existence of a nontrivial weak solution for the given problem.

Lemma 3.6

Assume that (J1)-(J5), (H1)-(H2), and (F1)-(F3) hold. Then$I_{\lambda }$satisfies the (PS)-condition, for all$\lambda >0$.

Proof

Note that ${\mathrm{\Psi }}^{\prime }$ is of the type $(S_{+})$, since ${\mathrm{\Psi }}^{\prime }$ is weakly strongly continuous. Let $\{u_n\}$ be a (PS)-sequence in X, i.e., $I_{\lambda }(u_n)\to c$ and $I_{\lambda }^{\prime }(u_n)\to 0$ as $n\to \mathrm{\infty }$. Since $I_{\lambda }^{\prime }$ is of type $(S_{+})$ and X is reflexive, it suffices to verify that the sequence $\{u_n\}$ is bounded in X. Suppose that ${\parallel u_n\parallel }_X\to \mathrm{\infty }$, in the subsequence sense. By assumption (J5), we deduce that