1 Introduction and main result

In this paper, we are concerned with the existence and multiplicity of solutions for the following problem:

$$ \textstyle\begin{cases} - (a-b \int _{\Omega } \vert \nabla u \vert ^{p}\,dx ) \Delta _{p}u = \lambda \vert u \vert ^{q-2}u + g(x, u), & x \in \Omega , \\ u = 0, & x \in \partial \Omega , \end{cases} $$
(1.1)

where \(a, b > 0\), \(\Delta _{p} u := \operatorname{div}(|\nabla u|^{p-2}\nabla u)\) is the p-Laplace operator, \(1 < p < N\), \(p < q < p^{\ast }:=(Np)/(N-p)\), \(\Omega \subset \mathbb{R}^{N}\) (\(N \geq 3\)) is a bounded smooth domain, λ is a real parameter.

In what follows, we suppose that the continuous function g satisfies the following conditions:

\((g_{1})\):

\(g \in C^{1}(\Omega \times \mathbb{R},\mathbb{R})\) and

$$ \bigl\vert g(x,s) \bigr\vert \leq C\bigl(1+ \vert s \vert ^{r-1}\bigr) \quad \forall (x,s) \in \Omega \times \mathbb{R}, $$

where \(C > 0\) and \(p < r < p^{\ast }\);

\((g_{2})\):

\(g(x,s)=o(|s|^{p-1})\) as \(s\to 0\);

\((g_{3})\):

(AR-condition) there exist \(\theta \in (p, p^{\ast })\) and \(T > 0\) such that

$$ 0 < \theta G(x,s) \leq g(x,s)s \quad \mbox{for all } \vert s \vert \geq T, x \in \Omega , $$

where \(G(x,s)=\int _{0}^{s} g(x,t)\,dt\);

\((g_{3}^{*})\):

\(\lim_{|x|\rightarrow \infty }\frac{G(x,t)}{|t|^{p}} = \infty \) uniformly in \(x \in \Omega \);

\((g_{3}^{**})\):

\(G(x,0) \in L^{1}(\Omega )\) and there exists \(\sigma \in L^{1}(\Omega )\) such that

$$ \mathcal{G}(x,t) \leq \mathcal{G}(x,s) + \sigma (x) $$

for all \(0 \leq t \leq s\) or \(s \leq t \leq 0\), where \(\mathcal{G}(x,t) := g(x,t)t- pG(x,t)\);

\((g_{4})\):

\(g(x, -s) = -g(x,s)\) for all \((x,s) \in \Omega \times \mathbb{R}\).

The novelty of our work is the fact that we combine several different phenomena in one problem. The features of this paper are the following:

  1. (1)

    The continuous function g may satisfy the Ambrosetti–Rabinowitz condition or not.

  2. (2)

    The presence of the new nonlocal term \((a - b\int _{\Omega }|\nabla u|^{2}\,dx)\).

To the best of our knowledge, there few papers proving the existence and multiplicity of solutions with the combined effects generated by the above features.

Recently, nonlocal problems and operators have been widely studied in the literature and have attracted the attention of a lot of mathematicians coming from different research areas. A typical model proposed by Kirchhoff [4] serves as a generalization of the classic D’Alembert wave equation by taking into account the effects of the changes in the length of the strings during the vibrations. Thanks to the pioneering work of Lions [13], a lot of attention has been drawn to these nonlocal problems during the last decade. After that, some studies on this kind of problems have been performed by using different approaches, see [2, 612, 14, 15, 18, 19, 23] and the references therein.

In this paper, we mainly consider a new Kirchhoff problem involving the p-Laplace operator, that is, the form with a nonlocal coefficient \((a-b\int _{\Omega }|\nabla u|^{p}\,dx)\). Its background is derived from negative Young’s modulus, when the atoms are pulled apart rather than compressed together and the strain is negative. Recently, the authors in [22] first studied this kind of problem

$$ \textstyle\begin{cases} - (a-b\int _{\Omega } \vert \nabla u \vert ^{2}\,dx )\Delta u= \vert u \vert ^{p-2}u, & x\in \Omega , \\ u=0, & x\in \partial \Omega , \end{cases} $$

where \(2< p<2^{*}:=(2N)/(N-2)\), and they obtained the existence of solutions by using the mountain pass lemma. Furthermore, some interesting results have been obtained for this kind of Kirchhoff-type problem. We refer the readers to [1, 3, 5, 16, 2022] and the references therein.

From the above-mentioned papers, it is a natural question to see what results can be recovered when this new Kirchhoff problem involves the p-Laplace operator. Compared to the above papers, some difficulties arise in our paper when dealing with problem (1.1), because of the appearance of the nonlocal coefficient \((a - b\int _{\Omega }|\nabla u|^{p}\,dx)\) which provokes some mathematical difficulties, and these make the study of problem (1.1) particularly interesting. In addition, we need more delicate estimates which are not trivial, the method of this paper is obviously different from the literature works mentioned above.

If the nonlinear term g satisfies the AR-condition, we have the following existence results of problem (1.1).

Theorem 1.1

Suppose that assumptions \((g_{1})\)\((g_{3})\) are fulfilled. Then there exists \(\lambda _{1} > 0\) such that, for any \(\lambda \geq \lambda _{1}\), problem (1.1) admits a nontrivial solution.

Theorem 1.2

Suppose that assumptions \((g_{1})\)\((g_{3})\) and \((g_{4})\) are fulfilled. Then there exists \(\lambda _{2} > 0\) such that, for any \(\lambda \geq \lambda _{2}\), problem (1.1) admits a sequence of solutions with unbounded energy.

If the nonlinear term g satisfies not the AR-condition, our next main result in this paper is the following.

Theorem 1.3

Suppose that assumptions \((g_{1})\)\((g_{2})\), \((g_{3}^{*})\), \((g_{3}^{**})\), and \((g_{5})\) are fulfilled. Then there exists \(\lambda _{3} > 0\) such that, for any \(\lambda \geq \lambda _{3}\), problem (1.1) admits a sequence of solutions with unbounded energy.

Remark 1.1

The main feature of problem (1.1) contains a nonlocal coefficient \((a - b\int _{\Omega }|\nabla u|^{2}\,dx)\), there is no doubt that we encounter serious difficulties because of the lack of compactness. To overcome the challenge, we must estimate precisely the value of c and give a threshold value. So the variational technique for problem (1.1) becomes more delicate. To the best of our knowledge, the present paper results have not been covered yet in the literature.

This paper is organized as follows. In Sect. 2, we give some necessary preliminary knowledge on the functional setting and prove the Palais–Smale compactness condition. In Sect. 3, we prove Theorem 1.1 by using the mountain pass theorem. In Sect. 4, we prove Theorems 1.2 and 1.3 via the symmetric mountain pass theorem where the nonlinear term g satisfies the AR-condition or not, respectively.

2 Preliminaries and compactness results

We seek weak solutions to problem (1.1) in \(W^{1,p}_{0}(\Omega )\) which is the usual Sobolev space with respect to the norm \(\|u\| = \int _{\Omega }|\nabla u|^{p}\,dx\). We then have that \(W^{1,p}_{0}(\Omega )\) is continuously and compactly embedded into the Lebesgue space \(L^{\tau }(\Omega )\) endowed the norm \(|u|_{\tau }= (\int _{\Omega }|u|^{\tau } \,dx )^{\frac{1}{\tau }}\), \(p<\tau <p^{\ast }\). Denote by \(S_{\tau }\) the best constant for this embedding, that is,

$$ S_{\tau } \vert u \vert _{\tau }\leq \Vert u \Vert ,\quad \forall u\in W^{1,p}_{0}(\Omega ). $$
(2.1)

In particular, if S is the best constant for the embedding \(W^{1,p}_{0}(\Omega ) \hookrightarrow L^{p^{\ast }} (\Omega )\), then it is defined by

$$ S=\inf \biggl\{ \int _{\Omega } \vert \nabla u \vert ^{p}\,dx: u \in W^{1,p}_{0}( \Omega ), \int _{\Omega } \vert u \vert ^{p^{\ast }}\,dx = 1 \biggr\} . $$
(2.2)

We consider the energy functional \(J_{\lambda }: W^{1,p}_{0}(\Omega ) \to \mathbb{R}\) defined by

$$ J_{\lambda }(u) = \frac{a}{p} \int _{\Omega } \vert \nabla u \vert ^{p}\,dx - \frac{b}{2p} \biggl( \int _{\Omega } \vert \nabla u \vert ^{p}\,dx \biggr)^{2} - \frac{\lambda }{q} \int _{\Omega } \vert u \vert ^{q}\,dx- \int _{\Omega }G(x,u)\,dx. $$
(2.3)

It is well known that a critical point of \(J_{\lambda }\) is a weak solution of problem (1.1) and the functional \(J_{\lambda }\) is of class \(C^{1}\) in \(W^{1,p}_{0}(\Omega )\) (see [17]). Denote by \(J_{\lambda }'\) the derivative operator of \(J_{\lambda }\) in the weak sense. Then

$$\begin{aligned} \bigl\langle J_{\lambda }'(u), v\bigr\rangle =& a \int _{\Omega } \vert \nabla u \vert ^{p-2} \nabla u \nabla v\, dx - b \biggl( \int _{\Omega } \vert \nabla u \vert ^{p}\,dx \biggr) \int _{\Omega } \vert \nabla u \vert ^{p-2}\nabla u \nabla v \,dx \\ &{} - \lambda \int _{\Omega } \vert u \vert ^{q-2}uv\, dx - \int _{\Omega }g(x, u)v\, dx,\quad \forall u, v \in W_{0}^{1,p}(\Omega ). \end{aligned}$$

We recall that a \(C^{1}\) functional \(J_{\lambda }\) on the Banach space \(W^{1,p}_{0}(\Omega )\) is said to satisfy the Palais–Smale condition at level c (\((\mathit{PS})_{c}\) in short) if every sequence \(\{u_{n}\} \subset W^{1,p}_{0}(\Omega )\) satisfying \(J_{\lambda }(u_{n}) \rightarrow c\) and \(J_{\lambda }'(u_{n}) \rightarrow 0\) (\(n \rightarrow \infty \)) has a convergent subsequence.

Lemma 2.1

Assume that \((g_{1})\)\((g_{3})\) hold. Then the functional \(J_{\lambda }\) satisfies the \((\mathit{PS})_{c}\) condition, where \(c \in (-\infty , \frac{a^{2}}{2pb})\).

Proof

First, let \(\{u_{n}\}_{n} \subset W_{0}^{1,p}(\Omega )\) be a \((\mathit{PS})_{c}\) sequence associated with the functional \(J_{\lambda }\), that is,

$$\begin{aligned} J_{\lambda }(u_{n})\to c \quad \mbox{and} \quad J_{\lambda }'(u_{n}) \to 0 \quad \mbox{as }n\to \infty . \end{aligned}$$

Then, \(\{u_{n}\}_{n}\) is bounded in \(W_{0}^{1,p}(\Omega )\). In fact, arguing by contradiction, we assume that, passing eventually to a subsequence, still denoting by \(\{u_{n}\}_{n}\), we have \(\|u_{n}\| \rightarrow +\infty \) as \(n \rightarrow +\infty \). By \((g_{3})\) we have

$$\begin{aligned} c + o(1) \Vert u_{n} \Vert =& J_{\lambda }(u_{n})-\frac{1}{q}\bigl\langle J_{\lambda }'(u_{n}),u_{n} \bigr\rangle \\ =& \biggl(\frac{1}{p}-\frac{1}{q} \biggr)a \Vert u_{n} \Vert ^{p}+ \biggl( \frac{1}{q}- \frac{1}{2p} \biggr)b \Vert u_{n} \Vert ^{2p} \\ &{}+ \int _{\Omega } \biggl[ \frac{1}{q}g(x,u_{n})u_{n}-G(x,u_{n}) \biggr]\,dx \\ \geq& \biggl(\frac{1}{p}-\frac{1}{q} \biggr) \Vert u_{n} \Vert ^{p}+ \biggl( \frac{1}{q}- \frac{1}{2p} \biggr)b \Vert u_{n} \Vert ^{2p}- C \vert \Omega \vert . \end{aligned}$$
(2.4)

Thus, (2.4) leads to contradiction since \(1 < p\). Therefore, there exists \(u \in W_{0}^{1,p}(\Omega )\) such that up to a subsequence \(u_{n}\rightharpoonup u\) weakly in \(W_{0}^{1,p}(\Omega )\) and \(u_{n}\rightarrow u\) strongly in \(L^{s}(\Omega )\) with \(p\leq s < p^{*}\).

In the following, we will prove \(u_{n} \rightarrow u\) strongly in \(W_{0}^{1,p}(\Omega )\).

In fact, by the Hölder inequality, one has

$$\begin{aligned} \begin{aligned} \int _{\Omega } \vert u_{n} \vert ^{q-2}u_{n}(u_{n}-{u})\,dx&\leq \int _{\Omega } \vert u_{n} \vert ^{q-1}(u_{n}-{u})\,dx \\ &\leq \biggl( \int _{\Omega } \vert u_{n} \vert ^{q}\,dx \biggr)^{\frac{q-1}{q}} \biggl( \int _{\Omega } \vert u_{n}-u \vert ^{q}\,dx \biggr)^{\frac{1}{q}} \\ &\rightarrow 0\quad \mbox{as } n \rightarrow \infty , \end{aligned} \end{aligned}$$

and thus

$$ \lim_{n \rightarrow \infty } \int _{\Omega } \vert u_{n} \vert ^{q-2}u_{n}(u_{n}-{u})\,dx = 0. $$
(2.5)

On the other hand, by conditions \((g_{1})\) and \((g_{2})\), we have that for every \(\varepsilon > 0\) there exists \(C_{\varepsilon }> 0\) such that

$$ \bigl\vert g(x,u_{n}) \bigr\vert \leq \varepsilon \vert u_{n} \vert ^{p-1} + C_{\varepsilon } \vert u_{n} \vert ^{r-1}. $$

This fact implies that

$$\begin{aligned} \biggl\vert \int _{\Omega }g(x,u_{n}) (u_{n} - u) \,dx \biggr\vert \leq {}& \varepsilon \int _{\Omega } \vert u_{n} \vert ^{p-1} \vert u_{n} - u \vert \,dx + C_{\varepsilon } \int _{\Omega } \vert u_{n} \vert ^{r-1} \vert u_{n} - u \vert \,dx \\ \leq {}& \varepsilon \biggl( \int _{\Omega } \vert u_{n} \vert ^{p}\,dx \biggr)^{\frac{p-1}{p}} \biggl( \int _{\Omega } \vert u_{n} - u \vert ^{p}\,dx \biggr)^{ \frac{1}{p}} \\ &{} + C_{\varepsilon } \biggl( \int _{\Omega } \vert u_{n} \vert ^{r}\,dx \biggr)^{ \frac{r-1}{r}} \biggl( \int _{\Omega } \vert u_{n} - u \vert ^{r}\,dx \biggr)^{ \frac{1}{r}} \\ \rightarrow {}& 0\quad \mbox{as } n \rightarrow \infty . \end{aligned}$$

Thus

$$ \lim_{n \rightarrow \infty } \int _{\Omega }g(x,u_{n}) (u_{n} - u) \,dx = 0. $$
(2.6)

From

$$ \bigl\langle J_{\lambda }'(u_{n}),u_{n}-u \bigr\rangle \rightarrow 0 $$

that

$$\begin{aligned} &\biggl(a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \biggr) \int _{ \Omega } \vert \nabla u_{n} \vert ^{p-2}\nabla u_{n}\nabla (u_{n}-u)\,dx \\ &\quad {} - \lambda \int _{\Omega } \vert u_{n} \vert ^{q-2}u_{n}(u_{n}-u)\,dx - \int _{ \Omega }g(x,u_{n}) (u_{n}-u)\,dx \rightarrow 0\quad \mbox{as } n \rightarrow \infty . \end{aligned}$$

Therefore, we can deduce from (2.5) and (2.6) that

$$ \biggl(a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \biggr) \int _{\Omega } \vert \nabla u_{n} \vert ^{p-2}\nabla u_{n}\nabla (u_{n}-u)\,dx \rightarrow 0\quad \mbox{as } n \rightarrow \infty . $$
(2.7)

Since \(\{u_{n}\}_{n}\) is bounded in \(W_{0}^{1,p}(\Omega )\), passing to a subsequence, if necessary, we may assume that

$$ \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \to d \geq 0\quad \mbox{as } n \rightarrow \infty . $$

Next, we distinguish the following two steps.

Step I: \(d \neq \frac{a}{b}\).

In this step, we have

$$ \biggl(a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \biggr)\not \to 0 \quad \mbox{as } n\to \infty . $$

This means that \(\{a-b\int _{\Omega }|\nabla u_{n}|^{p}\,dx\}\) is bounded.

Step II: \(d = \frac{a}{b}\).

In this step, we have

$$ a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \to 0.$$
(2.8)

Define

$$ \psi (u)= \frac{\lambda }{q} \int _{\Omega } \vert u \vert ^{q}\,dx + \int _{\Omega }G(x,u)\,dx. $$

Then

$$ \bigl\langle \psi '(u),v\bigr\rangle = \lambda \int _{\Omega } \vert u \vert ^{q-2}uv\, dx + \int _{\Omega }g(x,u)v\, dx. $$

It follows that

$$ \bigl\langle \psi '(u_{n})-\psi '(u),v \bigr\rangle =\lambda \int _{\Omega }\bigl( \vert u_{n} \vert ^{q-2}u_{n}- \vert u \vert ^{q-2}u\bigr)v\, dx- \int _{\Omega }\bigl(g(x,u_{n})-g(x,u)u\bigr)v\, dx $$

for all \(v \in W_{0}^{1,p}(\Omega )\). From the Hölder inequality and the embedding \(W_{0}^{1,p}(\Omega ) \hookrightarrow L^{s}(\Omega )\) (\(p \leq s < p^{*}\)) is compact, one has

$$ \lambda \int _{\Omega }\bigl( \vert u_{n} \vert ^{q-2}u_{n}- \vert u \vert ^{q-2}u\bigr)v\, dx \to 0 \quad \text{as } n\to \infty $$

and

$$ \int _{\Omega }\bigl(g(x,u_{n})-g(x,u)u\bigr)v\, dx \to 0 \quad \text{as } n\to \infty . $$

Thus

$$ \bigl\langle \psi '(u_{n})-\psi '(u),v\bigr\rangle \rightarrow 0 \quad \mbox{as } n \rightarrow \infty . $$
(2.9)

Since

$$\begin{aligned}& \bigl\langle J_{\lambda }'(u_{n}),v\bigr\rangle = \biggl(a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \biggr) \int _{\Omega } \vert \nabla u_{n} \vert ^{p-2}\nabla u_{n} \nabla v\, dx + \bigl\langle \psi '(u_{n}),v\bigr\rangle , \\& \bigl\langle J_{\lambda }'(u_{n}),v\bigr\rangle \to 0 \quad \mbox{and}\quad \biggl(a-b \int _{\Omega } \vert \nabla u_{n} \vert ^{p}\,dx \biggr)\to 0. \end{aligned}$$

Hence \(\psi '(u_{n})\to 0\) as \(n\to \infty \), i.e.,

$$ \bigl\langle \psi '(u),v\bigr\rangle =\lambda \int _{\Omega } \vert u \vert ^{q-2}uv\, dx + \int _{\Omega }g(x,u)v\, dx = 0\quad \mbox{for all } v\in W_{0}^{1,p}( \Omega ). $$

Then we have

$$ \lambda \vert u \vert ^{q-2}u+g(x,u)=0,\quad \mbox{a.e. } x\in \Omega . $$

By the fundamental lemma of the variational method (see [17]), it follows that \(u=0\). So

$$ \psi (u_{n})=\frac{\lambda }{q} \int _{\Omega } \vert u_{n} \vert ^{q}\,dx + \int _{\Omega }G(x,u_{n})\,dx \to \frac{\lambda }{q} \int _{\Omega } \vert u \vert ^{q}\,dx + \int _{\Omega }G(x,u)\,dx=0. $$

Hence, we see that

$$ J_{\lambda }(u_{n})=\frac{a}{p} \Vert u_{n} \Vert ^{p}-\frac{b}{2p} \Vert u_{n} \Vert ^{2p} - \frac{\lambda }{q} \int _{\Omega } \vert u_{n} \vert ^{q}\,dx - \int _{\Omega }G(x,u_{n})\,dx \to \frac{a^{2}}{2pb}. $$

This is a contradiction since

$$ J_{\lambda }(u_{n}) \rightarrow c < \frac{ a^{2}}{2pb}. $$

Then (2.8) is not true and \(d \neq \frac{a}{b}\), this means that any subsequence of \(\{a-b\|u_{n}\|^{p}\}\) does not converge to zero. Therefore there exists \(\delta >0\) such that \(|a-b\|u_{n}\|^{p}|>\delta \) when n is large enough. It is clear that \(\{a-b\|u_{n}\|\}\) is bounded.

Therefore, it follows from (2.7) that

$$ \int _{\Omega } \vert \nabla u_{n} \vert ^{p-2}\nabla u_{n}\nabla (u-u_{n})\,dx \to 0 \quad \mbox{as } n\to \infty . $$

Thus by the \((S_{+})\) property, \(u_{n}\to u\) strongly in \(W_{0}^{1,p}(\Omega )\). The proof is complete. □

3 Proof of Theorem 1.1

In this section, we first begin by giving the following general mountain pass theorem (see [17]).

Theorem 3.1

Let E be a Banach space and \(I_{\lambda }\in C^{1}(E, \mathbb{R})\) with \(J_{\lambda }(0)=0\). Suppose that

\((A_{1})\):

there exist \(\rho , \alpha >0\) such that \(J_{\lambda }\geq \alpha \) for all \(u\in E\) with \(\|u\|=\rho \);

\((A_{2})\):

there exists \(e\in E\) satisfying \(\|e\|_{E}>\rho \) such that \(I_{\lambda }(e)<0\).

Define \(\Gamma = \{ \gamma \in C([0,1],E) :\gamma (0)=0, \gamma (1)=e \} \).

$$ c=\inf_{\gamma \in \Gamma }\max_{0\leq t\leq 1}J_{ \lambda } \bigl(\gamma (t)\bigr)\geq \alpha $$

and there exists a \((\mathit{PS})_{c}\) sequence \(\{{u_{n}}\}_{n}\subset E\).

Now, we begin proving that \(J_{\lambda }\) satisfies the assumptions of the mountain pass geometry.

Lemma 3.1

Under conditions \((g_{1})\)\((g_{3})\), the functional \(J_{\lambda }\) satisfies the mountain pass geometry, that is,

  1. (i)

    there exist \(\alpha , \rho >0\) such that \(J_{\lambda }(u)\geq \alpha \) for any \(u \in W_{0}^{1,p}(\Omega )\) such that \(\|u\| = \rho \);

  2. (ii)

    there exists \(e\in W_{0}^{1,p}(\Omega )\) with \(\|e\| > \rho \) such that \(J_{\lambda }(e)<0\).

Proof

First, by conditions \((g_{1})\) and \((g_{2})\), we have that for every \(\varepsilon > 0\) there exists \(C_{\varepsilon }> 0\) such that

$$ \bigl\vert G(x,u) \bigr\vert \leq \varepsilon \vert u \vert ^{p} + C_{\varepsilon } \vert u \vert ^{r}. $$

By (2.1) and (2.3), we have

$$\begin{aligned} J_{\lambda }(u)&\geq \frac{a}{p} \Vert u \Vert ^{p}-\frac{b}{2p} \Vert u \Vert ^{2p}-\frac{\lambda }{q} \int _{ \Omega } \vert u \vert ^{q} \,dx - \varepsilon \int _{\Omega } \vert u \vert ^{p} \,dx- C_{\varepsilon } \int _{\Omega } \vert u \vert ^{r} \,dx \\ &\geq \biggl(\frac{a}{2}-\varepsilon S_{p}^{-p} \biggr) \Vert u \Vert ^{p}- \frac{b}{2p} \Vert u \Vert ^{2p}- \lambda S_{q}^{-q} \Vert u \Vert ^{q} - C_{\varepsilon }S_{r}^{-r} \Vert u \Vert ^{r}. \end{aligned}$$
(3.1)

Taking \(\varepsilon > 0\) satisfies \(\frac{a}{2}-\varepsilon S_{p}^{-p} > 0\). Then, we can choose ρ, \(\alpha >0\) such that \(J_{\lambda }(u)\geq \alpha \) for \(\|u\|=\rho \), since \(p < q\) and \(p < r\). Hence \((A_{1})\) in Theorem 3.1 holds.

Next, we verify condition \((A_{2})\) of Theorem 3.1. By \((g_{3})\) we know that, for all \(T > 0\), there exists \(C_{T} > 0\) such that

$$ G(x,u) \geq T \vert u \vert ^{\theta }- C_{T} \quad \mbox{for all } (x, u) \in \Omega \times \mathbb{R}. $$
(3.2)

Set \(v \in C_{0}^{\infty }(\Omega )\) and \(v\neq 0\). It follows from (3.2) that

$$ J_{\lambda }(tv)\leq \frac{a}{p}t^{p} \Vert v \Vert ^{p}-\frac{b}{2p}t^{2p} \Vert v \Vert ^{2p}- \frac{\lambda }{q}t^{q} \int _{\Omega } \vert v \vert ^{q}\,dx- t^{\theta }T \int _{ \Omega } \vert v \vert ^{\theta }\,dx + C_{T}\Omega . $$
(3.3)

From the fact that \(q, \theta > p\), we deduce that \(J_{\lambda }(t_{0}v) < 0\) and \(t_{0}\|v\| > \rho \) for \(t_{0}\) large enough. Set \(e = t_{0}v\). Hence e is the required function and \((A_{2})\) in Theorem 3.1 is valid. This completes the proof. □

Proof of Theorem 1.1

Now, we claim that

$$ c_{\lambda }= \inf_{\gamma \in \Gamma }\max _{0\leq t \leq 1}J_{\lambda }\bigl(\gamma (t)\bigr)< \frac{a^{2}}{2pb} $$
(3.4)

for all sufficiently large λ.

In fact, in order to prove (3.4), we choose \(\nu \in W_{0}^{1,p}(\Omega )\setminus \{0\}\) such that \(\lim_{t\rightarrow \infty }J_{\lambda }(t\nu )=-\infty \). Then

$$ \sup_{t\geq 0}J_{\lambda }(t\nu )= J_{\lambda }(t_{\lambda } \nu ) $$

for some \(t_{\lambda }>0\). Hence \(t_{\lambda }\) satisfies

$$ at_{\lambda }^{p} \Vert \nu \Vert ^{p} - bt^{2p} \Vert \nu \Vert ^{2p} = \lambda t_{ \lambda }^{q} \int _{\Omega } \vert \nu \vert ^{q}\,dx + \int _{\Omega }g(x,t_{\lambda }\nu )t_{\lambda }\nu \,dx. $$
(3.5)

Then, by \((g_{3})\), we have

$$ at_{\lambda }^{p} \Vert \nu \Vert ^{p} \geq bt^{2p} \Vert \nu \Vert ^{2p} + \lambda t_{ \lambda }^{q} \int _{\Omega } \vert \nu \vert ^{q}\,dx - C \vert \Omega \vert . $$
(3.6)

This fact implies that \(\{t_{\lambda }\}_{\lambda >0}\) is bounded since \(q > p\).

In the following, we prove that

$$ t_{\lambda }\rightarrow 0\quad \mbox{as } \lambda \rightarrow \infty . $$
(3.7)

Arguing by contradiction, we can assume that there exist \(t_{0}>0\) and a sequence \(\{\lambda _{n}\}_{n}\) with \(\lambda _{n}\rightarrow \infty \) as \(n\rightarrow \infty \) such that \(t_{\lambda _{n}}\rightarrow t_{0}\) as \(n\rightarrow \infty \). By the Lebesgue dominated convergence theorem, we deduce that

$$ \int _{\Omega } \vert t_{\lambda _{n}}\nu \vert ^{q}\,dx\rightarrow \int _{\Omega } \vert t_{0} \nu \vert ^{q}\,dx \quad \mbox{as } n\rightarrow \infty , $$

from which it follows that

$$ \lambda _{n} \int _{\Omega } \vert t_{\lambda _{n}}\nu \vert ^{q}\,dx\rightarrow + \infty \quad \mbox{as } n\rightarrow \infty . $$

However, (3.5) implies that this fact is absurd. Hence (3.7) holds.

From (3.7) and the definition of \(J_{\lambda }\), we get

$$ \lim_{\lambda \rightarrow \infty } \Bigl(\sup_{t \geq 0}J_{\lambda }(t \nu ) \Bigr)=\lim_{\lambda \rightarrow \infty }J_{\lambda }(t_{\lambda } \nu )=0. $$

So, for any \(\lambda >\lambda _{0}>0\), we have

$$ \sup_{t\geq 0}J_{\lambda }(t \nu )< \frac{a^{2}}{2pb}. $$

If we take \(e=\tau \nu \) with τ large enough to verify \(J_{\lambda }(e)<0\), then we obtain

$$ c_{\lambda }\leq \max_{t\in [0,1]}J_{\lambda }\bigl( \gamma (t)\bigr) \quad \mbox{by taking } \gamma (t) = t\tau \omega . $$

Therefore

$$ c_{\lambda }\leq \sup_{t\geq 0}J_{\lambda }(t \omega )< \frac{a^{2}}{2pb}\quad \mbox{for } \lambda \mbox{ large enough}. $$

Clearly, Lemmas 2.1, 3.1, and Theorem 3.1 give the existence of nontrivial critical points of \(J_{\lambda }\), and this concludes the proof. □

4 Proof of Theorems 1.2 and 1.3

To prove Theorems 1.2 and 1.3, we shall use the following symmetric mountain pass theorem in [17].

Theorem 4.1

(see [17])

Let \(X = Y \oplus Z\) be an infinite dimensional Banach space, where Y is finite dimensional, and let \(J\in C^{1}(X,\mathbb{R})\). Suppose that

\((I_{1})\):

J satisfies the \((\mathit{PS})_{c}\) condition for all \(c > 0\);

\((I_{2})\):

\(J(0)=0\), \(J(-u)=J(u)\) for all \(u \in X\);

\((I_{3})\):

There exist constants ρ, \(\alpha >0\) such that \(J(u)\ge \alpha \) for all \(u\in \partial B_{\rho }\bigcap Z\);

\((I_{4})\):

For any finite dimensional subspace \(\widetilde{X}\subset X\), there is \(R=R(\widetilde{X})>0\) such that \(J(u)\leq 0\) on \(\widetilde{X}\setminus B_{R}\).

Then J possesses an unbounded sequence of critical values.

Proof of Theorem 1.2

We shall apply Theorem 4.1 to \(J_{\lambda }\). On the one hand, we know that \(W_{0}^{1,p}(\Omega )\) is a Banach space and \(J_{\lambda }\in C^{1}(W_{0}^{1,p}(\Omega ), \mathbb{R})\). The functional \(J_{\lambda }\) satisfies \(J_{\lambda }(0)=0\), \(J_{\lambda }(-u)=J_{\lambda }(u)\). So, \((I_{2})\) of Theorem 4.1 is satisfied.

On the other hand, using a similar discussion as in (3.4), there exists \(\lambda _{2} > 0\) such that

$$ c_{\lambda }< \frac{a^{2}}{2pb}\quad \mbox{for all } \lambda > \lambda _{2}. $$

By Lemma 2.1, one knows that \(J_{\lambda }\) satisfies the \((\mathit{PS})_{c}\) condition. Then \((I_{1})\) of Theorem 4.1 is satisfied.

In the following, we will prove that assumptions \((I_{3})\) and \((I_{4})\) of Theorem 4.1 are satisfied.

In fact, the proof of \((I_{3})\) is similar to the proof of \((i)\) in Lemma 3.1. So, we omit the proof here.

In order to prove \((I_{4})\) of Theorem 4.1, we take is the finite dimensional subspace of Banach space X. By (3.2), we deduce that

$$ J_{\lambda }(u)\leq \frac{a}{p} \Vert u \Vert ^{p}-\frac{b}{2p} \Vert u \Vert ^{2p}- \frac{\lambda }{q} \int _{\Omega } \vert u \vert ^{q}\,dx- T \int _{\Omega } \vert u \vert ^{\theta }\,dx + C_{T}\Omega . $$
(4.1)

Because all the norms on the finite dimensional subspace are equivalent, there exists \(C>0\) such that

$$ \int _{\Omega } \vert u \vert ^{q}\,dx \geq C_{\widetilde{X}} \Vert u \Vert ^{q}\quad \mbox{and}\quad \int _{\Omega } \vert u \vert ^{\theta }\,dx \geq C_{\widetilde{X}} \Vert u \Vert ^{\theta }. $$

From these and (4.1), we have

$$ J_{\lambda }(u)\leq \frac{a}{p} \Vert u \Vert ^{p}-\frac{b}{2p} \Vert u \Vert ^{2p}- \frac{\lambda }{q}C_{\widetilde{X}} \Vert u \Vert ^{q} - TC_{\widetilde{X}} \Vert u \Vert ^{\theta }+ C_{T} \vert \Omega \vert . $$

Thus, there exists \(R=R(\widetilde{X})\) such that we can derive \(J_{\lambda }(u) < 0\) for all \(u \in \widetilde{X}\) with \(\|u\| \geq R\). Consequently, \((I_{4})\) of Theorem 4.1 is satisfied.

Since all the assumptions of Theorem 4.1 are satisfied, problem (1.1) possesses infinitely many nontrivial solutions with unbounded energy. □

Proof of Theorem 1.3

If g satisfies conditions \((g_{1})\)\((g_{2})\), \((g_{3}^{*})\), and \((g_{3}^{**})\). First, we claim that the functional \(J_{\lambda }\) satisfies the \((\mathit{PS})_{c}\) condition, where \(c \in (-\infty , \frac{a^{2}}{2pb})\).

Indeed, we take \(\{u_{n}\}\subset W_{0}^{1,p}(\Omega )\) to be a \((\mathit{PS})_{c}\) sequence associated with the functional \(J_{\lambda }\), that is, \(J_{\lambda }(u_{n})\to c\) and \(J_{\lambda }'(u_{n})\to 0\) as \(n\to \infty \). By using \((g_{3}^{*})\) and \((g_{3}^{**})\), we have

$$\begin{aligned} \begin{aligned} c + o(1) \Vert u_{n} \Vert &= J_{\lambda }(u_{n})- \frac{1}{p}\bigl\langle J_{\lambda }'(u_{n}),u_{n} \bigr\rangle \\ &= \frac{b}{2p} \Vert u_{n} \Vert ^{2p}+ \biggl(\frac{1}{p} - \frac{1}{q} \biggr) \lambda \int _{\Omega } \vert u_{n} \vert ^{q}\,dx + \frac{1}{p} \int _{\Omega } \mathcal{G}(x,u_{n})\,dx \\ &\geq \frac{b}{2p} \Vert u_{n} \Vert ^{2p} + \int _{\Omega }\bigl( \mathcal{G}(x,0)-\sigma (x)\bigr) \,dx. \end{aligned} \end{aligned}$$

This fact implies that \(\{u_{n}\}\) is bounded in \(W_{0}^{1,p}(\Omega )\) since \(1 < p\), \(\sigma \in L^{1}(\Omega )\) and \(\mathcal{G}(x,0) \in L^{1}(\Omega )\). Arguing as in the proof of Lemma 2.1, we can also prove \(u_{n}\to u\) strongly in \(W_{0}^{1,p}(\Omega )\), we omit the details here.

Next, we claim that assumptions \((I_{3})\) and \((I_{4})\) of Theorem 4.1 are also satisfied.

In fact, it is easy to prove that \((I_{3})\) of Theorem 4.1 is satisfied.

In the following, we prove that \((I_{4})\) of Theorem 4.1 is satisfied. On the one hand, by \((g_{3}^{*})\), we have

$$ G(x,u) \geq C \vert u \vert ^{p} - C^{\ast },\quad \forall (x,u)\in \Omega \times \mathbb{R}. $$

Hence, we deduce that

$$ J_{\lambda }(u)\leq \frac{a}{p} \Vert u \Vert ^{p}-\frac{b}{2p} \Vert u \Vert ^{2p}- \frac{\lambda }{q} \int _{\Omega } \vert u \vert ^{q}\,dx- C \int _{\Omega } \vert u \vert ^{p} \,dx + C \vert \Omega \vert . $$
(4.2)

Similarly, arguing as in the proof of Theorem 1.2, we know that \((I_{4})\) of Theorem 4.1 is satisfied. Thus, problem (1.1) possesses infinitely many nontrivial solutions with unbounded energy. □