Existence of homoclinic solutions for a class of difference systems involving p-Laplacian

By using the critical point theory, some existence criteria are established which guarantee that the difference p-Laplacian systems of the form $\mathrm{\Delta }({|\mathrm{\Delta }u(n-1)|}^{p-2}\mathrm{\Delta }u(n-1))-a(n){|u(n)|}^{q-p}u(n)+\mathrm{\nabla }W(n,u(n))=0$ have at least one or infinitely many homoclinic solutions, where $1<p<(q+2)/2$, $q>2$, $n\in \mathbb{Z}$, $u\in {\mathbb{R}}^N$, $a:\mathbb{Z}\to (0,+\mathrm{\infty })$, and $W:\mathbb{Z}\times {\mathbb{R}}^N\to \mathbb{R}$ are not periodic in n.

MSC:34C37, 35A15, 37J45, 47J30.

Consider homoclinic solutions of the following p-Laplacian system:

where $1<p<(q+2)/2$, $q>2$, $n\in \mathbb{Z}$, $u\in {\mathbb{R}}^N$, $a:\mathbb{Z}\to (0,+\mathrm{\infty })$, and $W:\mathbb{Z}\times {\mathbb{R}}^N\to \mathbb{R}$ are not periodic in n. Δ is the forward difference operator defined by $\mathrm{\Delta }u(n)=u(n+1)-u(n)$, ${\mathrm{\Delta }}^{2}u(n)=\mathrm{\Delta }(\mathrm{\Delta }u(n))$. As usual, we say that a solution u of (1.1) is homoclinic (to 0) if $u(n)\to 0$ as $n\to \pm \mathrm{\infty }$. In addition, if $u(n)\not\equiv 0$, then $u(n)$ is called a nontrivial homoclinic solution. We may think of (1.1) being a discrete analogue of the following differential system:

When $p=2$, (1.1) can be regarded as a discrete analogue of the following second-order Hamiltonian system:

Problem (1.2) has been studied by Shi et al. in [1] and problem (1.3) has been studied in [2–4]. It is well known that the existence of homoclinic orbits for Hamiltonian systems is a classical problem and its importance in the study of the behavior of dynamical systems has been firstly recognized by Poincaré [5]. If a system has the transversely intersected homoclinic orbits, then it must be chaotic. If it has the smoothly connected homoclinic orbits, then it cannot stand the perturbation and its perturbed system probably produces chaotic phenomenon. Therefore, it is of practical importance to investigate the existence of homoclinic orbits of (1.1) emanating from 0.

By applying critical point theory, the authors [6–22] studied the existence of periodic solutions and subharmonic solutions for difference equations or differential equations, which show that the critical point theory is an effective method to study periodic solutions of difference equations or differential equations. In this direction, several authors [23–34] used critical point theory to study the existence of homoclinic orbits for difference equations. Motivated mainly by the ideas of [1–4, 35], we will consider homoclinic solutions of (1.1) by the mountain pass theorem and the symmetric mountain pass theorem. More precisely, we obtain the following main results, which seem not to have been considered in the literature.

Theorem 1.1 Suppose that a and W satisfy the following conditions:

1. (A)

   Let $1<p<(q+2)/2$ and $q>2$, $a:\mathbb{Z}\to (0,+\mathrm{\infty })$ is a positive function on ℤ such that for all $n\in \mathbb{Z}$

   $$a(n)\ge \alpha {|n|}^{\beta },\alpha >0,\beta >(q-2p+2)/p.$$

(W1) $W(n,x)=W_1(n,x)-W_2(n,x)$, $W_1$, $W_2$ are continuously differentiable in x, and there is a bounded set $J\subset \mathbb{Z}$ such that

uniformly in $n\in \mathbb{Z}\mathrm{\setminus }J$.

(W2) There is a constant $\mu >q-p+2$ such that

(W3) $W_2(n,0)=0$ and there exists a constant $\varrho \in (q-p+2,\mu )$ such that

Then problem (1.1) has one nontrivial homoclinic solution.

Theorem 1.2 Suppose that a and W satisfy (A), (W2) and the following conditions:

(W1)′ $W(n,x)=W_1(n,x)-W_2(n,x)$, $W_1$, $W_2$ are continuously differentiable in x, and

uniformly in $n\in \mathbb{Z}$.

(W3)′ $W_2(n,0)=0$ and there exists a constant $\varrho \in (q-p+2,\mu )$ such that

Then problem (1.1) has one nontrivial homoclinic solution.

Theorem 1.3 Suppose that a and W satisfy (A), (W1)-(W3) and

(W4) $W(n,-x)=W(n,x)$, $\mathrm{\forall }(n,x)\in \mathbb{Z}\times {\mathbb{R}}^N$.

Then problem (1.1) has an unbounded sequence of homoclinic solutions.

Theorem 1.4 Suppose that a and W satisfy (A), (W1)′, (W2), (W3)′ and (W4). Then problem (1.1) has an unbounded sequence of homoclinic solutions.

The rest of this paper is organized as follows: in Section 2, some preliminaries are presented and we establish an embedding result. In Section 3, we give the proofs of our results. In Section 4, some examples are given to illustrate our results.

Let

and for $u\in W$, let

Then W is a uniform convex Banach space with this norm. As usual, for $1\le p<+\mathrm{\infty }$, let

and their norms are given by

respectively.

If σ is a positive function on ℤ and $1<s<+\mathrm{\infty }$, let

$l_{\sigma }^s$ equipped with the norm

is a reflexive Banach space.

Set $E=W\cap l_a^{q-p+2}$, where a is the function given in condition (A). Then E with its standard norm $\parallel \cdot \parallel$ is a reflexive Banach space. The functional φ corresponding to (1.1) on E is given by

Clearly, it follows from (W1) or (W1)′ that $\phi :E\to \mathbb{R}$. By Theorem 2.1 of [36], we can deduce that the map

is continuous from $l_a^{q-p+2}$ in the dual space $l_{a^{-1/(q-p+1)}}^{p_1}$, where $p_1=(q-p+2)/(q-p+1)$. As the embeddings $E\subset W\subset l^{\gamma }$ for all $\gamma \ge p$ are continuous, if (A) and (W1) or (W1)′ hold, then $\phi \in C^1(E,\mathbb{R})$ and one can easily check that

Furthermore, the critical points of φ in E are classical solutions of (1.1) with $u(\pm \mathrm{\infty })=0$.

Lemma 2.1 [23]

For $u\in E$

Lemma 2.2 If a satisfies assumption (A), then

Moreover, there exists a Sobolev space Z such that

Proof Let $\theta =(q-p+2)/(q-2p+2)$, ${\theta }^{\prime }=(q-p+2)/p$, we have

where $a_1={({\sum }_{n\in \mathbb{Z}}{[a(n)]}^{-p/(q-2p+2)})}^{(q-2p+2)/(q-p+2)}<+\mathrm{\infty }$ from (A). Then (2.4) holds.

By (A), there exists a positive function ρ such that $\rho (n)\to +\mathrm{\infty }$ as $|n|\to +\mathrm{\infty }$ and

Since

(2.5) holds by taking $Z=l_{\rho }^p$.

Finally, as $W\cap Z$ is the weighted Sobolev space ${\mathrm{\Gamma }}^{1,p}(\mathbb{Z},\rho ,1)$, it follows from [36] that (2.6) holds. □

The following two lemmas are the mountain pass theorem and the symmetric mountain pass theorem, which are useful in the proofs of our theorems.

Lemma 2.3 [37]

Let E be a real Banach space and $I\in C^1(E,\mathbb{R})$ satisfying the (PS)-condition. Suppose $I(0)=0$ and

1. (i)

   There exist constants $\rho ,\alpha >0$ such that $I_{\partial B_{\rho }(0)}\ge \alpha$.

2. (ii)

   There exists an $e\in E\mathrm{\setminus }{\overline{B}}_{\rho }(0)$ such that $I(e)\le 0$.

Then I possesses a critical value $c\ge \alpha$ which can be characterized as

where $\mathrm{\Phi }=\{h\in C([0,1],E)|h(0)=0,h(1)=e\}$, and $B_{\rho }(0)$ is an open ball in E of radius ρ centered at 0.

Lemma 2.4 [37]

Let E be a real Banach space and $I\in C^1(E,\mathbb{R})$ with I even. Assume that $I(0)=0$ and I satisfies (PS)-condition, (i) of Lemma  2.3 and the following condition:

1. (iii)

   For each finite dimensional subspace $E^{\prime }\subset E$, there is $r=r(E^{\prime })>0$ such that $I(u)\le 0$ for $u\in E^{\prime }\mathrm{\setminus }{B}_r(0)$, $B_r(0)$ is an open ball in E of radius r centered at 0.

Then I possesses an unbounded sequence of critical values.

Lemma 2.5 Assume that (W2) and (W3) or (W3)′ hold. Then for every $(n,x)\in \mathbb{Z}\times {\mathbb{R}}^N$,

1. (i)

   $s^{-\mu }{W}_1(n,sx)$ is nondecreasing on $(0,+\mathrm{\infty })$;

2. (ii)

   $s^{-\varrho }{W}_2(n,sx)$ is nonincreasing on $(0,+\mathrm{\infty })$.

The proof of Lemma 2.5 is routine and we omit it. In the following, $C_i$ ($i=1,2,\dots$) denote different positive constants.

Proof of Theorem 1.1 Firstly, we prove that the functional φ satisfies the (PS)-condition. Let $\{u_k\}\subset E$ satisfying $\phi (u_k)$ is bounded and ${\phi }^{\prime }(u_k)\to 0$ as $k\to \mathrm{\infty }$. Hence, there exists a constant $C_1>0$ such that

From (2.1), (2.2), (3.1), (W2), and (W3), we have

It follows from Lemma 2.2, $p<(q+2)/2$, $\mu >q-p+2$, and (3.2) that there exists a constant $C_2>0$ such that

Now we prove that $u_k\to u$ in E. Passing to a subsequence if necessary, it can be assumed that $u_k\rightharpoonup u$ in E. For any given $\epsilon >0$, by (W1), we can choose $\delta \in (0,1)$ such that

Since $u\in E$, we can also choose a positive integer $K>max\{|k|:k\in J\}$ such that

Hence,

Furthermore,

Hence, from (3.5) and (3.6), we have

where $p^{\prime }=p/(p-1)$. Moreover, since $a(n)$ is a positive function on ℤ, $p<q-p+2$, and $u_k(n)\to u(n)$ for almost every $n\in \mathbb{Z}$, we have

and

It follows from (3.7), (3.8), (3.9), and the Lebesgue dominated convergence theorem that

This shows that

From (2.2), we have

It is easy to see that for any $\alpha >1$ there exists a constant $C_3>0$ such that

Hence, we have

and

Since ${\phi }^{\prime }(u_k)\to 0$ as $k\to +\mathrm{\infty }$, $u_k\rightharpoonup u$ in E and the embeddings $E\subset W\subset l^{\gamma }$ for all $\gamma \ge p$ are continuous, it follows from Lemma 2.2, (3.10), (3.11), (3.13), and (3.14) that

and

Hence, we have $u_k\to u$ in E by (3.15) and (3.16). This shows that φ satisfies the (PS)-condition.

Secondly, we prove that there exist $\rho ,\alpha >0$ such that ${\phi }_{\partial B_{\rho }(0)}\ge \alpha$. From (W1), there exists ${\delta }_1\in (0,1)$ such that

From (3.17), we have

Let

Set $\sigma =min\{1/{(p(q-p+2)C_6+1)}^{1/(\mu -q+p-2)},{\delta }_1\}$ and $\parallel u\parallel =\sigma /2:=\rho$, it follows from (2.3) that

which shows that $|u(n)|\le \sigma \le {\delta }_1<1$. From Lemma 2.5(i) and (3.19), we have

It follows from (W3), (3.18), and (3.20) that

Therefore, we can choose a constant $\alpha >0$ depending on ρ such that $\phi (u)\ge \alpha$ for any $u\in E$ with $\parallel u\parallel =\rho$.

Thirdly, we prove that assumption (ii) of Lemma 2.3 holds. From Lemma 2.5(ii) and (2.3), we have for any $u\in E$

where $C_7=2^{\varrho }{\sum }_{n\in [-3,3]}{max}_{|x|=1}{W}_2(n,x)$, $C_8={\sum }_{n\in [-3,3]}{max}_{|x|\le 1}{W}_2(n,x)$. Take $\omega \in E$ such that

and $|\omega (n)|\le 1$ for $|n|\in (1,3]$. For $s>1$, from Lemma 2.5(i) and (3.22), we get

where $C_9={\sum }_{n\in [-1,1]}{W}_1(n,\omega (n))>0$. From (W3), (2.1), (3.21), (3.22), (3.23), we have for $s>1$

Since $\mu >\varrho >q-p+2$ and $C_9>0$, it follows from (3.24) that there exists $s_1>1$ such that $\parallel s_1\omega \parallel >\rho$ and $\phi (s_1\omega )<0$. Let $e=s_1\omega (n)$, then $e\in E$, $\parallel e\parallel =\parallel s_1\omega \parallel >\rho$, and $\phi (e)=\phi (s_1\omega )<0$.

By Lemma 2.3, φ has a critical value $c>\alpha$ given by

where

Hence, there exists $u^{\ast }\in E$ such that

The function $u^{\ast }$ is a desired solution of problem (1.1). Since $c>0$, $u^{\ast }$ is a nontrivial homoclinic solution. The proof is complete. □

Proof of Theorem 1.2 In the proof of Theorem 1.1, the condition $W_2(t,x)\ge 0$ in (W3) is only used in the proofs of (3.3) and assumption (i) of Lemma 2.3. Therefore, we only need to prove that (3.3) and assumption (i) of Lemma 2.3 still hold if we use (W1)′ and (W3)′ instead of (W1) and (W3), respectively. We first prove that (3.3) holds. From (W2), (W3)′, (2.1), (2.2), and (3.1), we have

which implies that there exists a constant $C_2>0$ such that (3.3) holds. Next, we prove that assumption (i) of Lemma 2.3 still holds. From (W1)′, there exists ${\delta }_2\in (0,1)$ such that

By (3.26), we have

Let $0<\sigma \le {\delta }_2$ and $\parallel u\parallel =\sigma /2:=\rho$, it follows from (2.3) that

which shows that $|u(n)|\le \sigma \le {\delta }_2<1$. It follows from (2.1) and (3.27) that