Existence of a nontrivial solution for a $(p,q)$-Laplacian equation with p-critical exponent in ${\mathbb{R}}^N$

In this paper we prove the existence of a nontrivial solution in ${\mathcal{D}}^{1,p}({\mathbb{R}}^N)\cap {\mathcal{D}}^{1,q}({\mathbb{R}}^N)$ for the following $(p,q)$-Laplacian problem:

where $1<q\le p<r+1<p^{\star }:=\frac{Np}{N-p}$, $p<N$, $\lambda >0$ is a parameter, ${\mathrm{\Delta }}_{m}u:=div(|\mathrm{\nabla }u{|}^{m-2}\mathrm{\nabla }u)$ is the m-Laplacian operator and $g\in L^{\frac{p^{\star }}{p^{\star }-r-1}}({\mathbb{R}}^N)$ is positive in an open set.

MSC: 35J92, 47J30.

In this paper we prove the existence of a nontrivial solution for the following problem involving the $(p,q)$-Laplacian and the p-critical exponent

where $1<q\le p<r+1<p^{\star }:=\frac{Np}{N-p}$, $p<N$, $\lambda >0$ is a parameter, ${\mathrm{\Delta }}_{m}u:=div(|\mathrm{\nabla }u{|}^{m-2}\mathrm{\nabla }u)$ is the m-Laplacian operator and $g:{\mathbb{R}}^N\to \mathbb{R}$ is an integrable function satisfying

and

where ${\mathrm{\Omega }}_g$ is an open set of ${\mathbb{R}}^N$.

This kind of problem arises, for example, as the stationary version of the reaction-diffusion equation

where u describes a concentration, $D(u):=({|\mathrm{\nabla }u|}^{p-2}+{|\mathrm{\nabla }u|}^{q-2})$ is the diffusion coefficient and $f(x,u)$ is the reaction term related to source and loss mechanisms (see [1]–[4]).

The differential operator ${\mathrm{\Delta }}_p+{\mathrm{\Delta }}_q$, known as the $(p,q)$-Laplacian operator when $p\ne q$, has deserved special attention in the last decade. It is not homogeneous and this feature turns out to impose some technical difficulties in applying usual elliptic methods for obtaining the existence and regularity of weak solutions of problems involving this operator.

When $p=q$, we have a single operator p-Laplacian. In this case, problem (1) can be reduced to

with $f(x)=1$.

In the paper [5], Gonçalves and Alves showed the existence of a weak nonnegative solution for problem (4) with $\lambda =f(x)=1$, $p\ge 2$ and $g\ge 0$.

Drábek and Huang in [6], proved the existence of two positive solutions for problem (4) in the case where $r=p-1$, g and f change sign, $g^{+}\ne 0$, $f^{+}\ne 0$ (and other conditions).

Regarding specifically the $(p,q)$-Laplacian ($p\ne q$), Figueiredo proved, as a particular case of his main result in [1] (which was obtained for a problem involving a more general operator), the existence of a nontrivial weak solution for the following problem:

where f satisfies the Ambrosetti-Rabinowitz condition

for some positive constant θ. In general, this condition not only ensures that the Euler-Lagrange functional associated with (5) has a mountain pass geometry, but also guarantees the boundedness of Palais-Smale sequences corresponding to the functional. We emphasize that the positiveness of $\lambda g(x){\int }_0^t|s{|}^{r-1}sds$ in problem (1) is not guaranteed since the function g can be negative in a large part of ${\mathbb{R}}^N$.

When Ω is a bounded domain of ${\mathbb{R}}^N$, variational methods have been employed for obtaining results of existence and multiplicity of solutions for the following problem with p-critical growth:

For $\theta =0$ and $g=1$, we refer to [7], where $1<r<q<p<N$, and to [8], where $1<q<p<r<p^{\star }$.

In [9], Yin and Yang established the existence of multiple weak solutions in $W_0^{1,p}(\mathrm{\Omega })$ for (6) where the nonlinearity $f(x,t)$ is of concave-convex type, $\lambda ,\theta >0$ are parameters, $g\in L^{\mathrm{\infty }}{(\mathrm{\Omega })}_{+}$ and $1<r<q<p<N$. They also obtained some results for the case $1<q<\frac{N(p-1)}{N-1}<p\le max\{p,p^{\star }-\frac{q}{p-1}\}<r<p^{\star }$.

The natural space to study $(p,q)$-Laplacian problems in a bounded domain Ω is $W_0^{1,p}(\mathrm{\Omega })$, thus taking advantage of the compact immersion $W_0^{1,p}(\mathrm{\Omega })\hookrightarrow L^s(\mathrm{\Omega })$ for $1\le s<p^{\star }$.

When the domain is the whole ${\mathbb{R}}^N$, Sobolev’s immersion is not compact. In order to overcome this issue, the concentration-compactness principle or constrained minimization methods (see [1], [3], [10] and [4], respectively) have been used to find weak solutions in $W^{1,p}({\mathbb{R}}^N)\cap W^{1,q}({\mathbb{R}}^N)$.

In this paper we prove an existence result for (1) in the reflexive Banach space

where ${\mathcal{D}}^{1,m}({\mathbb{R}}^N)$ denotes the closure of $C_0^{\mathrm{\infty }}({\mathbb{R}}^N)$ with respect to the norm of $W^{1,m}({\mathbb{R}}^N)$. More precisely, our main result is stated as follows.

Theorem 1

Let g satisfy (2) and (3). There exists${\lambda }^{\ast }>0$such that for any$\lambda >{\lambda }^{\ast }$problem (1) has at least one nontrivial weak solution in$\mathbb{W}$.

Our nontrivial solution is obtained from the mountain pass theorem. We prove that $I_{\lambda }$, the Euler-Lagrange functional associated with nonnegative solutions of (1) in $\mathbb{W}$, satisfies a mountain pass geometry, circumventing the difficulties due to the fact that the $(p,q)$-Laplacian operator is not homogeneous. We also adapt standard arguments to prove the boundedness of Palais-Smale sequences. In order to overcome the lack of compactness of Sobolev’s immersion, we apply the concentration-compactness principle by making use of a suitable bounded measure and adapting arguments from [5], where a p-Laplacian problem involving critical exponents is considered. By following [7] and [8] we get a strict upper bound for $c_{\lambda }$, the level of the Palais-Smale sequence, valid for all λ large enough. Then, we use this fact and arguments derived from [5] to conclude that the nonnegative critical point for $I_{\lambda }$, obtained from the mountain pass theorem, is not the trivial one.

In this section, we state some known results and notations that will be used to prove Theorem 1.

First, let us introduce the following version of the mountain pass theorem (see [11] or [12]).

Lemma 2

Let X be a real Banach space and$\mathrm{\Phi }\in C^1(X,\mathbb{R})$. Suppose that$\mathrm{\Phi }(0)=0$and that there exist$\alpha ,\rho >0$and$x_1\in X\setminus {\overline{B}}_{\rho }(0)$such that

♦ $\mathrm{\Phi }(u)\ge \alpha$for all$u\in X$with${\parallel u\parallel }_X=\rho$;

♦ $\mathrm{\Phi }(x_1)<\alpha$.

There exists a sequence $\{u_n\}\subset X$ satisfying

where c is the minimax level, defined by

Let $1<m<N$ and denote by ${\mathcal{D}}^{1,m}({\mathbb{R}}^N)$ the closure of $C_0^{\mathrm{\infty }}({\mathbb{R}}^N)$ with respect to the norm of $W^{1,m}({\mathbb{R}}^N)$. We recall that ${\mathcal{D}}^{1,m}({\mathbb{R}}^N)$ is a reflexive Banach space that is also characterized by (see [13])

where $m^{\star }:=\frac{Nm}{N-m}$, and that its original norm is equivalent to the gradient norm ${\parallel \mathrm{\nabla }\cdot \parallel }_{L^m({\mathbb{R}}^N)}$. Moreover, $W^{1,m}({\mathbb{R}}^N)⫋{\mathcal{D}}^{1,m}({\mathbb{R}}^N)\hookrightarrow L^{m^{\star }}({\mathbb{R}}^N)$.

The next result is a version of the concentration-compactness principle of Lions (see [14] and [15]).

Lemma 3

Let$v_n\in {\mathcal{D}}^{1,p}({\mathbb{R}}^N)$be a bounded sequence such that$v_n\rightharpoonup v$in$L^{p^{\star }}({\mathbb{R}}^N)$. If$v_n$is a subsequence such that${|v_n|}^{p^{\star }}dx\rightharpoonup \nu$for some measure ν, then there exist$x_i\in {\mathbb{R}}^N$and${\nu }_i>0$, $i=1,2,3,\dots$ , such that

where${\delta }_{x_i}$denotes the Dirac measure concentrated at$x_i$.

The next result follows from Theorem 1 of [16] combined with the Banach-Alaoglu theorem (see Remark (iii) of [16]).

Lemma 4

Let$1<p<\mathrm{\infty }$and let$\{u_n\}\subset L^p({\mathbb{R}}^N)$be a bounded sequence converging to u almost everywhere. Then$u_n\rightharpoonup u$ (weakly) in$L^p({\mathbb{R}}^N)$.

The following lemma can be found in [17], Lemma 2.7].

Lemma 5

Let$s>1$, Ω an open set in${\mathbb{R}}^N$and$u_n,u\in W^{1,s}(\mathrm{\Omega })$, $n=1,2,3,\dots$ . Let$a(x,\xi )\in C^0(\mathrm{\Omega }\times {\mathbb{R}}^N,{\mathbb{R}}^N)$satisfy, for positive numbers$\alpha ,\beta >0$, the following properties:

♦ $\alpha {|\xi |}^s\le a(x,\xi )\xi$for all$\xi \in {\mathbb{R}}^N$,

♦ $|a(x,\xi )|\le \beta {|\xi |}^{s-1}$for all$(x,\xi )\in \mathrm{\Omega }\times {\mathbb{R}}^N$,

♦ $[a(x,\xi )-a(x,\eta )][\xi -\eta ]>0$for all$(x,\xi )\in \mathrm{\Omega }\times {\mathbb{R}}^N$with$\xi \ne \eta$.

Then $\mathrm{\nabla }{u}_n\to \mathrm{\nabla }u$ in $L^s(\mathrm{\Omega })$ if and only if

We denote by S the best Sobolev constant defined by

We deal with problem (1) in the reflexive Banach space

endowed with the norm

where

The Euler-Lagrange functional associated with (1) is

where $u_{+}:=max\{0,u\}$. It is well defined in $\mathbb{W}$ and of class $C^1$ (as a consequence of hypothesis (2)).

In order to obtain a critical point for $I_{\lambda }$, we will find a Palais-Smale sequence for this functional, that is, a sequence $\{u_n\}\subset \mathbb{W}$ satisfying

In the sequel we show that $I_{\lambda }$ satisfies a mountain pass geometry. In order to simplify the presentation, we denote, from now on, the norm of $\mathbb{W}$ by $\parallel \cdot \parallel$ instead of ${\parallel \cdot \parallel }_{\mathbb{W}}$.

Lemma 6

There exist$\eta ,\rho >0$and$u_0\in \mathbb{W}$satisfying: $\parallel u_0\parallel >\rho$, $I_{\lambda }(u_0)<0$and$I_{\lambda }(u)\ge \eta$for any$u\in \mathbb{W}$such that$\parallel u\parallel =\rho$.

Proof

The Hölder inequality implies that

and (7) yields

Let us suppose $\parallel u\parallel \le 1$. Then ${\parallel u\parallel }_{{\mathbb{E}}_q}\le \parallel u\parallel \le 1$ and

We have concluded that

Let us define $\varphi (t):=t^p(\frac{1}{p{2}^{p-1}}-C_1{t}^{r+1-p}-C_2{t}^{p^{\star }-p})$, $t\ge 0$. It is easy to see that there exists $0<t_1<1$ such that $\varphi (t)>0$ for all $t\in (0,t_1]$. Therefore, there exist $\eta >0$ and $0<\rho <1$ such that $I_{\lambda }(u)\ge \eta >0$ whenever $\parallel u\parallel =\rho$.

Now, let $v_0\in \mathbb{W}\setminus \{0\}$ such that $v_0\ge 0$. Then, for any $t>0$, one has

Since $I_{\lambda }(t{v}_0)\to -\mathrm{\infty }$ as $t\to \mathrm{\infty }$, there exists $u_0=t_0{v}_0\in \mathbb{W}$ such that $\parallel u_0\parallel >\rho$ and $I_{\lambda }(u_0)<0$. □

Lemma 7

Let$\{u_n\}\subset \mathbb{W}$be a Palais-Smale sequence. Then$\{u_n\}$is bounded in$\mathbb{W}$.

Proof

By hypothesis, $\{u_n\}$ satisfies (9). It follows that there exist positive constants $k_0$ and $k_1$ such that $I_{\lambda }(u_n)\le k_0$ and ${\parallel I_{\lambda }^{\prime }(u_n)\parallel }_{{\mathbb{W}}^{\ast }}\le k_1$ for all n large. Thus,

That is, for all n large, we have

where $c_0$, $c_1$ and $c_2$ are positive constants that do not depend on n.

Suppose $\parallel u_n\parallel \to \mathrm{\infty }$. Then we have the three following cases to consider:

1. 1.

   ${\parallel u_n\parallel }_{{\mathbb{E}}_p}\to \mathrm{\infty }$ and ${\parallel u_n\parallel }_{{\mathbb{E}}_q}\to \mathrm{\infty }$;

2. 2.

   ${\parallel u_n\parallel }_{{\mathbb{E}}_p}\to \mathrm{\infty }$ and ${\parallel u_n\parallel }_{{\mathbb{E}}_q}$ is bounded;

3. 3.

   ${\parallel u_n\parallel }_{{\mathbb{E}}_p}$ is bounded and ${\parallel u_n\parallel }_{{\mathbb{E}}_q}\to \mathrm{\infty }$.

The first case cannot occur. Indeed, it implies that ${\parallel u_n\parallel }_{{\mathbb{E}}_p}^p>{\parallel u_n\parallel }_{{\mathbb{E}}_p}^q$ for all n large, and thus

which contradicts the fact that $\parallel u_n\parallel \to \mathrm{\infty }$.

If the second case occurs, we have, for all n large,

and hence we arrive at the absurd

Proceeding as in the second case, one can check that the third case cannot also happen. □

Lemma 8

Let$\{u_n\}\subset \mathbb{W}$be a Palais-Smale sequence. There exists a nonnegative function$u\in \mathbb{W}$such that, up to a subsequence,

Proof

We have

for all $\phi \in C_0^{\mathrm{\infty }}({\mathbb{R}}^N)$ and $v\in {\mathcal{D}}^{1,p}({\mathbb{R}}^N)$, where the first inequality comes from (7). Hence,

for all $\phi \in C_0^{\mathrm{\infty }}({\mathbb{R}}^N)$ and $v\in {\mathcal{D}}^{1,p}({\mathbb{R}}^N)\cap {\mathcal{D}}^{1,q}({\mathbb{R}}^N)$.

As a consequence of the boundedness of $\{u_n\}$, given by Lemma 7, there exists $u\in \mathbb{W}$ such that, up to a subsequence, $u_n\rightharpoonup u$ in $\mathbb{W}$. Since $I_{\lambda }^{\prime }(u_n)u_{n-}\to 0$, it follows that $u_{n-}\to 0$ in $\mathbb{W}$, so $u_{n+}\to u$ a.e. in ${\mathbb{R}}^N$.

Let $\mathrm{\Phi }\in C_0^{\mathrm{\infty }}({\mathbb{R}}^N)$ satisfy $0\le \mathrm{\Phi }\le 1$ and

where $B_{\tau }$ denotes the ball of ${\mathbb{R}}^N$ centered at the origin and with radius τ.

By applying Lemma 3 with $v_n=u_{n+}$ and $v=u$, we have

Define the measure $({|\mathrm{\nabla }{u}_{n+}|}^p+{|\mathrm{\nabla }{u}_{n+}|}^q)dx$. Since it is bounded, we have

for some measure μ. For each index i and each $\epsilon >0$, define

It follows from inequality (11) that

By making $n\to \mathrm{\infty }$, we obtain

and then, by making $\epsilon \to 0$, we find

yielding

On the other hand, from the fact that $I_{\lambda }^{\prime }(u_n){\phi }_{\epsilon }{u}_{n_{+}}\to 0$ we have

and hence

By Claim 1 in [5] and by the same argument replacing p with q, we obtain

Making $\epsilon \to 0$ in (13), we arrive at

that is, ${\nu }_i={\mu }_i$. By combining this equality with (12), we obtain

Since ${\sum }_{i=1}^{\mathrm{\infty }}{({\nu }_i)}^{p/p^{\star }}<\mathrm{\infty }$, there exist at most a finite number s of indices i with ${\nu }_i>0$. Let us first consider the case where $s>0$. In this case we take ${\epsilon }_0>0$ such that

We also define

for all $0<\epsilon <{\epsilon }_0$. Thus,

Now, let us define

We claim that $P_n\ge 0$. Indeed, this is a consequence of the well-known fact: there exists $C(s)>0$ such that

Fix $\rho ,\epsilon >0$ with $0<\epsilon <\rho <{\epsilon }_0$. Then

and thus

Since both $\{u{\mathrm{\Psi }}_{\epsilon }\}$ and $\{u_n{\mathrm{\Psi }}_{\epsilon }\}$ are bounded in $\mathbb{W}$, we have

By Claim 3 in [5] and by the same argument replacing p by q, we have

and

Since the functional

is bounded in $\mathbb{W}$, we have

It follows from Lemma 4 that

Since $u\ge 0$, we have

and

It follows from Lemma 3 that

We then conclude from (15)-(21) that

Note that

and that (14) yields that each term above is nonnegative. Therefore,

Lemma 5 with $a(x,\xi )={|\xi |}^{p-2}\xi$ then implies that $\mathrm{\nabla }{u}_n\to \mathrm{\nabla }u$ in $L^p(A_{\rho })$. Thus,

Since $\rho <{\epsilon }_0$ we have, in fact, that

At last, in the case where $s=0$, that is, ${\nu }_i=0$ for all i, we just take ${\mathrm{\Psi }}_{\epsilon }(x):=\mathrm{\Phi }(\epsilon x)$ and $A_{\rho }:=B_{\frac{1}{2\rho }}$ and repeat the arguments above. □

From now on we denote, for each $\lambda >0$,

Lemma 9

There exists ${\lambda }^{\ast }>0$ such that

Proof

It follows from Lemma 6 that $I_{\lambda }(u)\ge \eta >0$ whenever $\parallel u\parallel =\rho$. Of course, this fact implies that ${\tilde{c}}_{\lambda }\ge \eta >0$. (We remark that η might depend on λ, but it is always positive.)

We recall that ${\mathrm{\Omega }}_g$ denotes the open set where g is positive. Let $u_0\in \mathbb{W}\setminus \{0\}$ with support in ${\mathrm{\Omega }}_g$ such that $u_0\ge 0$ and ${\parallel u_0\parallel }_{p^{\star }}=1$. Since

we can see that $I_{\lambda }(t{u}_0)\to -\mathrm{\infty }$ as $t\to \mathrm{\infty }$ and that $I_{\lambda }(t{u}_0)\to 0^{+}$ as $t\to 0^{+}$. These facts imply that there exists $t_{\lambda }>0$ such that

Since

we get