Existence of solutions for a class of degenerate quasilinear elliptic equation in $R^N$ with vanishing potentials

We establish the existence of positive solution for the following class of degenerate quasilinear elliptic problem

where $-\mathcal{L}{u}_{ap}=-div({|x|}^{-ap}{|\mathrm{\nabla }u|}^{p-2}\mathrm{\nabla }u)$, $1<p<N$, $-\mathrm{\infty }<a<\frac{N-p}{p}$, $a\le e\le a+1$, $d=1+a-e$, and $p^{\ast }:=p^{\ast }(a,e)=\frac{Np}{N-dp}$ denote the Hardy-Sobolev’s critical exponent, V is a bounded nonnegative vanishing potential and f has a subcritical growth at infinity. The technique used here is a truncation argument together with the variational approach.

MSC:35B09, 35J10, 35J20, 35J70.

Consider the following degenerate quasilinear elliptic problem in $R^N$:

where $-\mathcal{L}{u}_{ap}=-div({|x|}^{-ap}{|\mathrm{\nabla }u|}^{p-2}\mathrm{\nabla }u)$, $1<p<N$, $-\mathrm{\infty }<a<\frac{N-p}{p}$, $a\le e\le a+1$, $d=1+a-e$, and $p^{\ast }:=p^{\ast }(a,e)=\frac{Np}{N-dp}$ denote the Hardy-Sobolev’s critical exponent, $V:R^N\to R$ is a bounded, nonnegative and vanishing potential and $f:R\to R$ a continuous function with a subcritical growth at infinity. Here, ${\mathcal{D}}_a^{1,p}(R^N)$ is the completion of the ${\mathcal{C}}_0^{\mathrm{\infty }}(R^N)$ with the norm $|u|={({\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }u|}^{p}dx)}^{\frac{1}{p}}$. We impose the following hypotheses on f and V:

$f:R\to R$ is a continuous function verifying

($f_1$) ${lim\hspace{0.17em}sup}_{s\to 0^{+}}\frac{sf(s)}{{|x|}^{-a{p}^{\ast }}{s}^{p^{\ast }}}<\mathrm{\infty }$, uniformly in x.

($f_2$) There exists $\alpha \in (p,p^{\ast })$ such that ${lim\hspace{0.17em}sup}_{s\to \mathrm{\infty }}\frac{sf(s)}{{|x|}^{-a{p}^{\ast }}{s}^{\alpha }}<\mathrm{\infty }$, uniformly in x.

($f_3$) There exists $\theta >p$ such that $\theta F(s)\le sf(s)$, for all $s>0$.

$V:R^N\to R$ is a continuous function verifying

($V_1$) $V(x)\ge 0$, for all $x\in R^N$.

($V_2$) There are $\mathrm{\Lambda }>0$ and $\overline{r}>1$ such that ${inf}_{|x|>\overline{r}}V(x){|x|}^{\frac{p^2[N-p(a+1)]}{(p-1)(N-p)}}\ge \mathrm{\Lambda }$.

Remark 1.1 The conditions ($f_1$) and ($f_2$) imply the following:

Example 1.2 An example for the function f is given by

with $\lambda >p^{\ast }$ and α given by ($f_2$).

By vanishing potential we mean a potential that vanish on some bounded domain or become very close to zero at infinity. An important example for a such potential is given by

with $\mathrm{\Lambda }>0$.

Consider first the case $a=0$, that is $-\mathcal{L}{u}_{ap}$ is the p-Laplacian operator, and the potential is bounded from below by a positive constant $V_0>0$.

Equations involving the p-Laplacian operator appear in many problems of nonlinear diffusion. Just to mention, in nonlinear optics, plasma physics, condensed matter physics and in modeling problems in non-Newtonian fluids. For more information on the physical background, we refer to [1].

For the case $p=2$, we cite [2–12], and references therein. In [13], in addition to the above assumptions, the authors consider a local condition, namely,

where $\mathrm{\Omega }\subset R^N$ is a open bounded set, instead of the global condition imposed by Rabinowitz in [12]. For $p\ne 2$, see [14–17].

Now, consider that V is the zero mass case, that is ${lim}_{|x|\to \mathrm{\infty }}V(x)=0$. When $p=2$, we cite [18–20] and the recent paper [21] by Alves and Souto.

Let us now consider the case $a\ne 0$ and the potential bounded from below by a positive constant $V_0>0$.

In this case, the equations arise in problems of existence of stationary waves for anisotropic Schrödinger equation (see [22]) and others problems (for example, see [6, 23]). We cite [22] for $p=2$; and [24, 25] for $p\ne 2$. For the case $V\equiv 0$, we cite [26], for $p=2$ and $a\ne 0$; and [27], for $p\ne 2$ and $a=0$.

The result presented here for $1<p<N$ and $a\ne 0$ extends that one in [21] for $p=2$ and $a=0$. In [21], the presence of Hilbertian structure and some compact embeddings provide the convergence of the gradient. In the case studied here, with the absence of this structure, we do not obtain the convergence so directly. To overcome this problem, we use a result found in [28, 29], whose ideas come from [30, 31], when the domain is a smooth and bounded. In addition to this difficulty, there are others. For instance, in the present situation, our space is no longer Hilbert, which forces us to obtain new estimates. Since the problem involves singular terms, the estimates are more refined and for which the principal ingredient is the Caffarelli-Kohn-Nirenberg’s inequality (see [32]). Now we state the main result of this work.

Theorem 1.3 Suppose that V and f satisfy, respectively, ($V_1$) and ($V_2$) and ($f_1$) to ($f_3$). Then there is a constant${\mathrm{\Lambda }}^{\ast }={\mathrm{\Lambda }}^{\ast }(V_{\mathrm{\infty }},\theta ,p,c_0)>0$such that the problem (P) has a positive solution, for all$\mathrm{\Lambda }\ge {\mathrm{\Lambda }}^{\ast }$, being$V_{\mathrm{\infty }}$the maximum of the f in the ball of$R^N$centered in the origin with radius 1.

In order to prove this theorem, we first build an auxiliary problem (AP), and then we solve the problem (AP) using variational methods. To finish, we show that the solution of (AP) is also a solution of (P). These steps are the content of the next three sections.

Hereafter, C is a positive constant which can change value in a sequence of inequalities. We denote $B_R=B_R(0)$ the ball in $R^N$ centered in the origin with radius R. The weak (⇀) and strong (→) convergences are always taken as $n\to \mathrm{\infty }$ and ${\int }_{A}f$ means ${\int }_{A}f(x)dx$. The weighted $L^p$ spaces are denoted by $L_{\alpha }^p(A)=\{u:R^N\to R:{\int }_A{|x|}^{-\alpha }{|u|}^p<\mathrm{\infty }\}$. When $\alpha =0$, we denote ${\parallel \cdot \parallel }_{L^p(A)}$ the usual norm in $L^p(A)$, with $1\le p\le \mathrm{\infty }$. For $A=R^N$, we use ${\parallel \cdot \parallel }_p$.

As usual, since we are looking for positive solutions of problem (P), we set $f(t)=0$, for all $t\le 0$. The hypothesis ($V_1$) allows us to consider the space

with norm

Associated to the problem (P), we define on E, the Euler-Lagrange functional

being $F(s)={\int }_0^{s}f(t)dt$. From the assumptions on f, it follows that I is $C^1$ with Gâteaux derivative

To obtain solutions of problem (P), we introduce some truncation of the function f. Consider $k=\frac{p\theta }{\theta -p}>p$, $\overline{r}>1$ and define

Now we define the auxiliary problem:

Associated to the problem (AP), we define, on E, the Euler-Lagrange functional

being $G(x,s)={\int }_0^{s}g(x,t)dt$. From the assumptions on f, it follows that J is $C^1$ with Gâteaux derivative

In this section, we show that the problem (AP) has a least energy solution, but first we define some minimax levels. To begin with we set in the space ${\mathcal{D}}_a^{1,p}(B_1)$, the norm $⦀u⦀={({\int }_{B_1}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p+V_{\mathrm{\infty }}{|x|}^{-a{p}^{\ast }}{|u|}^p)}^{\frac{1}{p}}$ and we define the functional $I_0$ given by $I_0(u)=\frac{1}{p}{\int }_{B_1}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p+V_{\mathrm{\infty }}{|x|}^{-a{p}^{\ast }}{|u|}^p-{\int }_{B_1}F(u)$. Here, ${\mathcal{D}}_a^{1,p}(B_1)$ is the completion of the ${\mathcal{C}}_0^{\mathrm{\infty }}(B_1)$ with the norm $|u|={({\int }_{B_1}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p)}^{\frac{1}{p}}$.

Lemma 3.1 The functional$I_0$has the mountain pass geometry, namely,

1. 1.

   $\mathrm{\exists }{r}_0,{\rho }_0>0$ such that $I_0(u)\ge {\rho }_0$ for $⦀u⦀=r_0$.

2. 2.

   $\mathrm{\exists }{e}_0\in {\mathcal{D}}_a^{1,p}(B_1)$ such that $⦀e_0⦀\ge r_0$ and $J(e_0)\le 0$.

Proof By using the growth of f given in Remark 1.1 and the Caffarelli-Kohn-Nirenberg’s inequality (see [32]), we get ${\int }_{B_1}F(u)\le {\int }_{B_1}{c}_0{|x|}^{-a{p}^{\ast }}{|u|}^{p^{\ast }}\le c_0⦀u{⦀}^{p^{\ast }}$, and hence $I_0(u)\ge \frac{1}{p}⦀u{⦀}^p-c_0⦀u{⦀}^{p^{\ast }}$. Since $p^{\ast }>p$, there exists $r_0$ such that ${\rho }_0:=\frac{1}{p}{r}_0^p-c{r}_0^{p^{\ast }}>0$. Thus, we have $I_0(u)\ge {\rho }_0$ for $⦀u⦀=r_0$. By ($f_3$), it follows that there exist $\theta >p$ and $C>0$ such that $F(s)\ge C{|s|}^{\theta }$. Now $u_0\in {\mathcal{D}}_a^{1,p}(B_1)$ implies $I_0(t{u}_0)\le \frac{t^p}{p}⦀u_0{⦀}^p-t^{\theta }C{\int }_{B_1}{|u_0|}^{\theta }$. Since $\theta >p$, there exists a $t_0$ large enough such that, taking $e_0=t_0{u}_0$, we have $I_0(e_0)<0$ and $⦀e_0⦀\ge r_0$. □

Lemma 3.2 The functional J has the mountain pass geometry, namely,

1. 1.

   $\mathrm{\exists }{r}_1,{\rho }_1>0$ such that $J(u)\ge {\rho }_1$ for $\parallel u\parallel =r_1$.

2. 2.

   $\mathrm{\exists }{e}_1\in E$ such that $\parallel e_1\parallel \ge r_1$ and $J(e_1)\le 0$.

Proof From the definition of G, we have ${\int }_{R^N}G(x,u)\le {\int }_{R^N}F(u)$. Thus, like the previous lemma, we have $J(u)\ge {\rho }_1:=\frac{1}{p}{r}_1^p-c{r}_1^{p^{\ast }}>0$ for $\parallel u\parallel =r_1$. Take the same $u_0\in {\mathcal{D}}_a^{1,p}(B_1)$ of the proof of the previous lemma. Thus, $u_0\in E$ and $G(x,u)=F(u)$. With the same argument, we have $J(t{u}_0)\le \frac{t^p}{p}{\parallel u_0\parallel }^p-t^{\theta }C{\int }_{R^N}{|u_0|}^{\theta }$. Since $\theta >p$, there exists a $t_1$ large enough such that, taking $e_1=t_1{u}_0$, we have $J(e_1)<0$ and $\parallel e_1\parallel \ge r_1$. □

Next, we are going to define two minimax levels, which will play an important role in our arguments. Note that is possible to take t such that $e=t{u}_0$ satisfies two previous lemmas. This allows to define the minimax levels c and $\overline{c}$ by

and

respectively. Since $J(u_0)\le I_0(u_0)$ in ${\mathcal{D}}_a^{1,p}(B_1)$, we have $c\le \overline{c}$, by their definitions. Now using the above lemma together with the mountain pass theorem [[33], Theorem 2.2], we conclude that there exists a Palais-Smale sequence ((PS) sequence for short) $(u_n)\subset E$ for J, i.e., $(u_n)$ satisfies $J(u_n)\to c$ and $J^{\prime }(u_n)\to 0$.

Lemma 3.3 Suppose ($V_1$) and ($f_1$) to ($f_3$) and let$(u_n)\subset E$be a (PS) sequence for the functional J. Then$(u_n)$is bounded in E.

Proof Define the set $A=\{x\in R^N:|x|\le R\text{ or }f(u(x))\le \frac{V(x)}{k}{|x|}^{-a{p}^{\ast }}{|u(x)|}^{p-2}u(x)\}$. In A, we have $G(x,u)=F(u)$. By using ($f_3$), we conclude that there is $\theta >p$ such that $-G(x,u)+\frac{1}{\theta }ug(x,u)\ge 0$. So, we have

Now consider the set $B=A^c=\{x\in R^N:|x|>R\text{ and }f(u(x))>\frac{V(x)}{k}{|x|}^{-a{p}^{\ast }}{|u(x)|}^{p-2}u(x)\}$. In B, we have ${\int }_{B}ug(x,u)>0$ and $G(x,u)=\frac{V}{pk}{|x|}^{-a{p}^{\ast }}{|u|}^p$. Then

Therefore, we get $J(u)-\frac{1}{\theta }{J}^{\prime }(u)u\ge \frac{(p-1)}{pk}{\parallel u\parallel }^p$. In particular, the above equation holds for the (PS) sequence $(u_n)$ for J, and we have $J(u_n)-\frac{1}{\theta }{J}^{\prime }(u_n)u_n\ge \frac{(p-1)}{pk}{\parallel u_n\parallel }^p$. On the other hand, we have $J(u_n)\to c$, $\theta >p>1$ and $J^{\prime }(u_n)\frac{u_n}{\parallel u_n\parallel }\to 0$, since $J^{\prime }(u_n)\to 0$. Thus, we get $J(u_n)-\frac{1}{\theta }{J}^{\prime }(u_n)u_n\le M+\frac{1}{\theta }\parallel u_n\parallel \le M+\parallel u_n\parallel$, for some constant $M>0$. Then we have $\frac{(p-1)}{pk}{\parallel u_n\parallel }^p\le M+\parallel u_n\parallel$, which can be rewritten as

Assuming $\parallel u_n\parallel \to \mathrm{\infty }$, equation (4) implies that $(p-1){\parallel u_n\parallel }^{p-1}-pk\to 0$. So $\parallel u_n\parallel \to {(\frac{pk}{p-1})}^{\frac{1}{p-1}}$, which is a contradiction. Therefore, $\parallel u_n\parallel$ is bounded in E. □

Lemma 3.4 Suppose ($V_1$) and ($f_1$) to ($f_3$). Then the functional J satisfies the Palais-Smale condition, i.e., every (PS) sequence has a convergent subsequence.

Proof Observe that, given the (PS) sequence $(u_n)$, by Lemma 3.3, there exists $u\in E$ such that $u_n\rightharpoonup u$, because E is reflexive space.^a Thus, it is enough to show that $\parallel u_n\parallel \to \parallel u\parallel$. We divide this task in the four claims below.

1. 1.

   Claim 1 ${\int }_{R^N}{u}_{n}g(x,u_n)\to {\int }_{R^N}ug(x,u)$.

2. 2.

   Claim 2 ${\int }_{R^N}ug(x,u_n)\to {\int }_{R^N}ug(x,u)$.

3. 3.

   Claim 3 ${\int }_{R^N}V{|x|}^{-a{p}^{\ast }}{|u_n|}^{p-2}{u}_{n}u\to {\int }_{R^N}V{|x|}^{-a{p}^{\ast }}{|u|}^p$.

4. 4.

   Claim 4 ${\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }{u}_n|}^{p-2}\mathrm{\nabla }{u}_n\mathrm{\nabla }u\to {\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p$.

Assuming Claims 1 to 4 for now, we proceed with the proof of lemma.

Since $J^{\prime }(u_n)u_n\to 0$, we have ${\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }{u}_n|}^p+V{|x|}^{-a{p}^{\ast }}{|u_n|}^p-{\int }_{R^N}{u}_{n}g(x,u_n)=o_n(1)$, and by Claim 1, we get

As $J^{\prime }(u_n)u\to 0$, we get ${\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }{u}_n|}^{p-2}\mathrm{\nabla }{u}_n\mathrm{\nabla }u+V{|x|}^{-a{p}^{\ast }}{|u_n|}^{p-2}{u}_{n}u-{\int }_{R^N}ug(x,u_n)=o_n(1)$. Passing the limit in the above equation and using Claims 2, 3 and 4, we get

Using equations (5) and (6), we have $\parallel u_n\parallel \to \parallel u\parallel$. □

In order to prove the claims, for a given $ϵ>0$, we choose r satisfying, the following two conditions:

1. 1.

   $max\{{\int }_{B_{2r}\setminus B_r}{|x|}^{-a{p}^{\ast }}{|u|}^{p^{\ast }},{\int }_{B_{2r}^c}V{|x|}^{-a{p}^{\ast }}{|u|}^p\}\le ϵ$.

2. 2.

   $\eta ={\eta }_r\in {\mathcal{C}}_0^{\mathrm{\infty }}(B_r^c)$ is such that $\eta \equiv 1$ in $B_{2r}^c$ and $0\le \eta \le 1$, $|\mathrm{\nabla }\eta |\le \frac{2}{r^d}$, for all $x\in R^N$.

Observe that condition 1 follows by integrability of ${|x|}^{-a{p}^{\ast }}{|u|}^{p^{\ast }}$ and $V{|x|}^{-a{p}^{\ast }}{|u|}^p$. Note that, when one of these conditions holds for some $r_0$, it also verifies for every $r\ge r_0$. Thus, we can choose an r that satisfies both conditions.

Remark 3.5 From now on, we consider the function g defined in (2) with $\overline{r}=r$ satisfying conditions 1 and 2 above. From the growth of g and the choice of r, we conclude:

1. 1.

   $g(x,t)=f(t)$, $G(x,t)=F(t)$ in $B_r$;

2. 2.

   $g(x,t)\le \frac{V}{k}{|x|}^{-a{p}^{\ast }}{|t|}^{p-2}t$, $G(x,t)\le \frac{V}{pk}{|x|}^{-a{p}^{\ast }}{|t|}^p$ in $B_r^c$;

3. 3.

   ${\int }_{B_{2r}^c}|ug(x,u)|\le {\int }_{B_{2r}^c}|u|\frac{V}{k}{|x|}^{-a{p}^{\ast }}{|u|}^{p-1}\le \frac{1}{k}{\int }_{B_{2r}^c}V{|x|}^{-a{p}^{\ast }}{|u|}^p<ϵ$.

Verification of claims

In all proofs, except for Claim 4, we consider separately integration in $B_{2r}$ and $B_{2r}^c$.

Claim 1: In $B_{2r}$, by combining the dominated convergence theorem with the compact embedding of E in $L_{\alpha }^r(B_{2r})$, $1\le r<p^{\ast }$ and $\alpha <(a+1)r+N(1-\frac{r}{p})$ (see [[34], Theorem 2.1]), we obtain ${\int }_{B_{2r}}{u}_{n}g(x,u_n)\to {\int }_{B_{2r}}ug(x,u)$. On the other hand, when integrating in $B_{2r}^c$ we do not have the compact embedding of E in $L_{\alpha }^r(B_{2r}^c)$. In this case, we first estimate ${\int }_{B_{2r}^c}{|x|}^{-ap}{|\mathrm{\nabla }{u}_n|}^p+V{|x|}^{-a{p}^{\ast }}{|u_n|}^p$, by using the cut-off function η defined before. As $(\eta u_n)$ is also bounded we have $J^{\mathrm{\prime }}(u_n)(\eta u_n)\to 0$, namely,

Since $\eta \equiv 0$ in $B_r$, equation (7) holds in $B_r^c$. Adding to this, the fact that $g(x,t)\le \frac{V}{k}{|x|}^{-a{p}^{\ast }}{|t|}^{p-2}t$ in $B_r^c$ we have

From this, we obtain

Thus, we have

(8)

Using the boundedness of $(u_n)$ in E, i.e., $\parallel u_n\parallel \le C$, strong convergence of $(u_n)$ in $L_{ap}^p(B_{2r}\setminus B_r)$ and Hölder’s inequality we conclude that

where ${\omega }_N$ is the volume of the unit sphere in $R^N$. Therefore, given $ϵ>0$, by the choice of r and by equations (9) and (8), we infer that

Hence,

Using this fact, we conclude that

Now, using Remark 3.5, we have ${lim\hspace{0.17em}sup}_{n\to \mathrm{\infty }}{\int }_{B_{2r}^c}|u_{n}g(x,u_n)-ug(x,u)|=0$.

Therefore, ${\int }_{B_{2r}^c}{u}_{n}g(x,u_n)\to {\int }_{B_{2r}^c}ug(x,u)$ and the proof of Claim 1 is completed.

Claim 2: The proof of this fact is made as in the proof of Claim 1.

Claim 3: In $B_{2r}$ the proof proceeds like in Claim 1. For integration in $B_{2r}^c$, we estimate the value of ${\int }_{B_{2r}}V{|x|}^{-a{p}^{\ast }}{|u_n|}^{p-2}{u}_{n}u$ by using the Hölder’s inequality

Using equations (10) and (11), we have

From this fact, we get ${\int }_{B_{2r}^c}V{|x|}^{-a{p}^{\ast }}{|u_n|}^{p-2}{u}_{n}u\to {\int }_{B_{2r}^c}V{|x|}^{-a{p}^{\ast }}{|u|}^p$ and the proof of this claim is completed.

Claim 4: Let $p^{\mathrm{\prime }}$ be dual of p. Since $u\in {\mathcal{D}}_a^{1,p}(R^N)=\{u:R^N\to R^N:{|x|}^{-a}u\in L^{p^{\ast }}(R^N)\text{and}{|x|}^{-a}\mathrm{\nabla }u\in L^p(R^N)\}$,^b we see that $h={|x|}^{-a}|\mathrm{\nabla }u|\in L^p(R^N)$ and $w_n={|x|}^{-a(p-1)}{|\mathrm{\nabla }{u}_n|}^{p-2}\mathrm{\nabla }{u}_n\in L^{p^{\mathrm{\prime }}}(R^N)$. As $\parallel u_n\parallel$ is bounded, we conclude that ${\parallel w_n\parallel }_{L^{p^{\mathrm{\prime }}}(R^N)}$ is also bounded. Moreover, $(u_n)$ satisfies the hypothesis of Lemma 3.6, below. So that we have $\mathrm{\nabla }{u}_n\to \mathrm{\nabla }u$ a.e. $x\in R^N$, which give us $w_n\to w={|x|}^{-a(p-1)}{|\mathrm{\nabla }u|}^{p-2}\mathrm{\nabla }u$ a.e. $x\in R^N$. Using a theorem [[35], Theorem 13.44], we conclude that $w_n\rightharpoonup w$ in $L^{p^{\mathrm{\prime }}}(R^N)$. Thus, we have ${\int }_{R^N}{w}_{n}h\to {\int }_{R^N}wh$, and hence ${\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }{u}_n|}^{p-2}\mathrm{\nabla }{u}_n\mathrm{\nabla }u\to {\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p$.

Lemma 3.6 Let E and J be respectively the space and functional defined in Section  2. Let$(u_n)\subset E$a bounded sequence such that$u_n\rightharpoonup u$in E and$J^{\mathrm{\prime }}(u_n)\to 0$. Then, passing to a subsequence if necessary, we have$\mathrm{\nabla }{u}_n\to \mathrm{\nabla }u$, a.e. $x\in R^N$.

The proof of this lemma follows using the same ideas made in [30] and [31], for a bounded domain. It can be found in [[28], Claim 1] and [[29], Lemma 1].

Using Lemmas 3.2, 3.3, 3.4 and the mountain pass theorem, in [[36], Theorem 2.4], we conclude that there exists $u\in E$ which is a critical point for the functional J, in the minimax level c. Moreover, u is the least energy solution to the problem (AP).

Now, our aim is to show that the solution found in the previous section is also a solution of the problem (P). It is sufficient to verify $f(u)\le \frac{V}{k}{|x|}^{-a{p}^{\ast }}{|u|}^{p-2}u$, for all $x\in B_r^c$.

Lemma 4.1 Any least energy solution u of (AP) satisfies the estimate${\parallel u\parallel }^p\le \frac{pk\overline{c}}{p-1}$.

Proof Since u is a critical point in the minimax level $c\le \overline{c}$, by Lemma 3.3, we have $\frac{(p-1)}{pk}{\parallel u\parallel }^p\le J(u)-\frac{1}{\theta }{J}^{\prime }(u)u=c\le \overline{c}$. So that ${\parallel u\parallel }^p\le \frac{pk\overline{c}}{p-1}$. □

Remark 4.2 The constant $\frac{pk\overline{c}}{p-1}$ depends only on $V_{\mathrm{\infty }}$, θ and f.

Lemma 4.3 Let h be such that${|x|}^{-a{p}^{\ast }}{|h|}^q$is integrable, with$pq>N$. Consider$H:R^N\times R\to R$, and$b:R^N\to R$nonnegative and continuous functions such that$|H(x,s)|\le h(x){|x|}^{-a{p}^{\ast }}{|s|}^{p-1}$, for all$s>0$. Let$v\in E$be a weak solution of (AP 2):

Then there exists a constant$M=M(q,{\parallel h\parallel }_{L_{a{p}^{\ast }}^q(R^N)})>0$such that${\parallel v\parallel }_{\mathrm{\infty }}\le M{\parallel {|x|}^{-a}v\parallel }_{p^{\ast }}$.

Proof Given $m\in N$ and $\beta >1$, set $A_m=\{x\in R^N:{|v|}^{\beta -1}\le m\}$, $B_m=R^N\setminus A_m$ and

Thus

Then $v_m\in E$ and using it as the test function in (AP 2). we have

By definition of $v_m$, we get

(13)

and

Using equations (13) and (14), we have

(15)

Putting

we have

Thus,

Now, taking into account (14), we get

Using (17), (13) and (16), we have

(18)

Combining (18), (15) and (12), we obtain

Let S be the best constant for inequality ${({\int }_{R^N}{|x|}^{-a{p}^{\ast }}{|u|}^{p^{\ast }})}^{\frac{p}{p^{\ast }}}\le S{\int }_{R^N}{|x|}^{-ap}{|\mathrm{\nabla }u|}^p$, for all $u\in {\mathcal{D}}_a^{1,p}(R^N)$. (See [32].) By the inequality (19), the boundedness of H and the definitions of $v_m$ and S, we get ${({\int }_{A_m}{|x|}^{-a{p}^{\ast }}{|w_m|}^{p^{\ast }})}^{\frac{p}{p^{\ast }}}\le S{\beta }^p{\int }_{R^N}h(x){|x|}^{-a{p}^{\ast }}{|v|}^{p\beta }$. Since $|w_m|={|v|}^{\beta }$ in $A_m$, we have

Making $m\to \mathrm{\infty }$ and using the monotone convergence theorem, we get

Since $pq>N$, $\sigma =\frac{N}{q_1(N-p)}>1$. Thus, we can consider $\beta ={\sigma }^j$ for $j=1,2,3,\dots$ and, using the Hölder’s inequality, we have

being $M_0=S{[{\int }_{R^N}{|x|}^{-a{p}^{\ast }}{|h(x)|}^q]}^{\frac{1}{q}}$. Note that $M_0$ is independent of j. Thus, we get