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Existence and symmetry breaking results for positive solutions of elliptic Hamiltonian systems

Published online by Cambridge University Press:  24 April 2024

Abbas Moameni*
Affiliation:
School of Mathematics and Statistics, Carleton University, Ottawa, ON, Canada e-mail: [email protected]
Kok Lin Wong
Affiliation:
School of Mathematics and Statistics, Carleton University, Ottawa, ON, Canada e-mail: [email protected]
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Abstract

In this paper, we are interested in positive solutions of

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)v^{p-1}, \quad &\text{ in } \Omega,\\ -\Delta v = b(x)u^{q-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial\Omega, \end{array} \right. \end{align*} $$
where $\Omega $ is a bounded annular domain (not necessarily an annulus) in ${\mathbb {R}}^N (N \ge 3)$ and $ a(x), b(x)$ are positive continuous functions. We show the existence of a positive solution for a range of supercritical values of p and q when the problem enjoys certain mild symmetry and monotonicity conditions. We shall also address the symmetry breaking phenomena where the system is fully symmetric. Indeed, as a consequence of our results, we shall show that problem (1) has $\Bigl \lfloor \frac {N}{2} \Bigr \rfloor $ (the floor of $\frac {N}{2}$) positive non-radial solutions when $ a(x)=b(x)=1$ and $\Omega $ is an annulus with certain assumptions on the radii. In general, for the radial case where the domain is an annulus, we prove the existence of a non-radial solution provided
$$ \begin{align*}(p-1)(q-1)> \Big(1+\frac{2N}{\lambda_H}\Big)^2\left(\frac{q}{p}\right),\end{align*} $$
where $\lambda _H$ is the best constant for the Hardy inequality on $\Omega .$ We remark that the best constant $\lambda _H$ for the Hardy inequality is just the characteristic of the domain, and is independent of the choices of p and $q.$ For this reason, the aforementioned inequality plays a major role to prove the existence and multiplicity of non-radial solutions when the problem is fully symmetric. Our proofs use a variational formulation on appropriate convex subsets for which the lack of compactness is recovered for the supercritical problem.

Type
Article
Copyright
© The Author(s), 2024. Published by Cambridge University Press on behalf of Canadian Mathematical Society

1 Introduction

The main purpose of the paper is to study the existence and multiplicity of positive solutions for the following system of supercritical nonlinear elliptic equations:

(1) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)v^{p-1}, \quad &\text{ in } \Omega,\\ -\Delta v = b(x)u^{q-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial\Omega, \end{array} \right. \end{align} $$

where $\Omega $ is a bounded annular domain (not necessarily an annulus) in $\mathbb{R} ^N, (N \geq 3), q\geq p> 2,$ and $a,b \in C(\bar \Omega )$ with $a(x)\geq a_0>0$ and $b(x)\geq b_0>0,$ where $a_0$ and $b_0$ are constants. In addition, for the case when $a(x)=b(x)=1$ and $\Omega $ is an annulus defined as

$$ \begin{align*}\Omega = \left\{x\in \mathbb{R}^N: R_1 < |x| < R_2\right\},\end{align*} $$

we shall address the symmetry breaking of the solutions by proving the existence and multiplicity of positive non-radial solutions provided that $R_1$ and $R_2$ satisfy certain conditions. Symmetry considerations dominate modern fundamental physics, both in quantum theory and in relativity. Such symmetry breaking is responsible for the existence of magnetism in which rotational invariance is broken.

Introduced independently by Mitidieri [Reference Mitidieri21] and Van der Vorst [Reference Van der Vorst31], the Sobolev critical hyperbola

(2) $$ \begin{align}\frac{1}{p}+\frac{1}{q}=1-\frac{2}{N}\end{align} $$

plays a crucial role in the analysis of (1). Our main contribution is to prove existence and multiplicity of positive solutions for the supercritical case by means of the Sobolev critical hyperbola $1/p+1/q=1-2/N$ .

Over the past 30 years, Hamiltonian systems have been widely studied with results including, but not limited to, existence, multiplicity, concentration phenomena, positivity, symmetry, and Liouville theorems. We redirect the interested reader to the surveys [Reference Bonheure, Moreira dos Santos and Tavares3, Reference de Figueiredo13, Reference Ruf25] for an overview of the topic and to the works [Reference Bonheure, Moreira dos Santos, Ramos and Tavares2, Reference Cardoso, do and Medeiros6, Reference Cassani and Zhang7, Reference Lange Ferreira Melo and Moreira dos Santos16] for some recent results. One of the first mathematical works studying systems of Hardy–Hénon-type equations were done by Calanchi and Ruf in [Reference Calanchi and Ruf5]. The system of Hardy–Hénon-type equations is given by

(3) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = |x|^\beta v^{q-1}, \quad &\text{ in } \Omega,\\ -\Delta v = |x|^\alpha u^{p-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial \Omega, \end{array} \right. \end{align} $$

where $\Omega $ is a bounded domain in $\mathbb{R} ^N, (N\geq 3),$ with $0 \in \Omega , p,q>2,$ and ${\alpha , \beta> -N.}$ The authors in [Reference Calanchi and Ruf5] presented existence and nonexistence of positive solutions along with symmetry breaking results for ground states when $\Omega $ is the unit ball in $\mathbb{R} ^N.$ Calanchi and Ruf remarked that systems of type (3) are closely related to the double weighted Hardy–Littlewood–Sobolev inequality (see [Reference Lieb18, Reference Stein and Weiss29] for instance). Later on, the authors Bonheure, Moreira dos Santos, and Ramos in [Reference Bonheure, Moreira dos Santos and Ramos1] presented qualitative properties of ground state solutions corresponding to the following system of equations:

(4) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = |x|^\beta|v|^{q-2}v, \quad &\text{ in } B,\\ -\Delta v = |x|^\alpha |u|^{p-2}u, \quad &\text{ in } B,\\ u=v=0, \quad &\text{ on } \partial B, \end{array} \right. \end{align} $$

where B denotes the open unit ball in $\mathbb{R} ^N, N\geq 1, \alpha , \beta \geq 0,$ and $p,q>1.$ Here, the authors describe the system (4) as a Lane–Emden system with Hénon-type weights. Consider the following Hénon equation:

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta u = |x|^\alpha |u|^{p-2}u, \quad &\text{ in } B, \\ u=0, \quad &\text{ on } \partial B, \end{array} \right. \end{align*} $$

where $\alpha>0,$ and $p>2.$ As $|x|^\alpha $ increases with respect to $|x|,$ we observe that reflection and symmetric arguments are inapplicable to prove radial symmetry of either positive or ground state solutions to the Hénon equation. According to [Reference Smets, Su and Willem26], the authors Smets, Su, and Willem proved that the radial symmetry holds for small values of $\alpha $ whereas the symmetry breaks for sufficiently large values of $\alpha .$ However, in [Reference Pacella23, Reference Smets and Willem27], the authors showed that the ground state solutions still possess a residual symmetry, namely, the foliated Schwarz symmetry.

We would like to remark that in the Hardy–Hénon system, one gets improved compactness due to the presence of the terms $|x|^\alpha $ and $|x|^\beta .$ In this paper, we assume that the functions a and b in (1) are strictly positive and away from zero. As a result, no improved compactness is induced from these functions.

As we are dealing with Hamiltonian systems, we highlight some further contributions on problems of type (4) presented in [Reference de Figueiredo, Peral and Rossi14, Reference Liu and Yang19]. As for nonexistence of solutions, we refer the interested reader to the works of [Reference de Figueiredo, Peral and Rossi14, Reference Liu and Yang19] and in particular, Theorem 2(a) in [Reference Calanchi and Ruf5]. Specifically speaking, Theorem 2(a) states that the problem (4) possesses no positive solutions, $u, v$ in the open unit ball B in $\mathbb{R} ^N$ for the case

$$ \begin{align*}\frac{N+\alpha}{p}+\frac{N+\beta}{q} \leq N-2, \quad \text{ provided that } p, q>1, N \geq 3.\end{align*} $$

As a result, this is a consequence of a suitable Pohoz̆aev-type identity. The authors in [Reference Bonheure, Moreira dos Santos and Ramos1] presented that the hyperbola

$$ \begin{align*}\frac{N+\alpha}{p}+\frac{N+\beta}{q} = N-2\end{align*} $$

is in fact, the exact threshold for the existence of positive solutions associated with (4).

Prior to introducing the main results of this paper, we conclude with some works pertaining to the Dirichlet problem for the generalized Hénon equation

(5) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u + \kappa u = |x|^\alpha |u|^{p-2}u, \quad &\text{ in } \Omega,\\ u=0, \quad &\text{ on } \partial\Omega, \end{array} \right. \end{align} $$

and its corresponding problem for a Hénon–Schrödinger system

(6) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u + \kappa_1 u = |x|^{\alpha} \partial_{u} F(u,v), \quad &\text{ in } \Omega,\\ -\Delta v + \kappa_2 v = |x|^{\alpha} \partial_{v} F(u,v), \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial{\Omega}, \end{array} \right. \end{align} $$

where $\Omega $ is the unit ball in $\mathbb{R} ^N, N\geq 2, \kappa , \kappa _1, \kappa _2\geq 0, p>2, \alpha >-1$ and where ${F:\mathbb{R} ^2\to \mathbb{R}} $ is homogeneous of degree $p>2.$

We remark that problem (5) is called the Hénon equation when $\kappa \equiv 0.$ In [Reference Lou, Weth and Zhang20], Lou, Weth, and Zhang observed that the Morse index of nontrivial radial solutions corresponding to (6) (positive or sign-changing) tends to infinity as $\alpha $ tends to infinity. Moreover in [Reference Clapp and Soares9], Clapp and Soares studied a related problem

$$ \begin{align*} -\Delta u_i + u_{i} =\sum_{j=1}^l \beta_{ij}|u_j|^{p}|u_i|^{p-2}u_i, \quad u_i\in H^1(\mathbb{R}^{N}), \quad i=1,\dots, l, \end{align*} $$

where $N\geq 4, 1<p<N/(N-2),$ and $(\beta _{ij})$ represents a symmetric matrix admitting a block decomposition with entries either positive or zero within each block and negative for all remaining entries. The authors resulted in the existence of fully nontrivial solutions, that is, nontrivial solutions component-wise, provided certain conditions are satisfied for the symmetric matrix $(\beta _{ij}).$ Furthermore, the authors derived the existence of solutions with positive and non-radial sign-changing components to the system of singularly perturbed elliptic equations

$$ \begin{align*} -\epsilon^2 \Delta u_i + u_i = \sum_{j=1}^l\beta_{ij}|u_j|^p|u_i|^{p-2}u_i, \quad u_i \in H_0^1(B_1(0)), \quad i=1,\dots, l, \end{align*} $$

where $B_1(0)$ is the unit ball exhibiting two different kinds of asymptotic behavior—the first being solutions whose components decouple as $\epsilon \to 0,$ while the second behavior being solutions whose components remain coupled up to their limit.

In this work, we are concerned with domains $\Omega \subset \mathbb{R} ^N$ that are invariant by the group action $O(m)\times O(n)$ for $N=m+n$ and $m,n\geq 1$ . We refer to Section 2 for the official definitions and further details. Here, we briefly introduce this class of domains in order to be able to state our main results in this paper. Inspired by the work [Reference Cabré and Ros-Oton4], for each $x=(x_1, x_2,\dots ,x_N)\in \Omega \subset \mathbb{R} ^N=\mathbb{R} ^m \times \mathbb{R} ^n, $ we shall consider the change of variable

$$ \begin{align*}s:= \{x_1^2 + \cdots + x_m^2\}^{\frac{1}{2}}, \quad t:= \{x_{m+1}^2 + \cdots + x_N^2\}^{\frac{1}{2}}.\end{align*} $$

Thus the domain $\Omega $ can be represented in the $(s,t)$ variable as follows:

$$ \begin{align*} \widehat \Omega = \{(s,t)\in U: s>0, t>0\}, \end{align*} $$

for some appropriate domain $U \in \mathbb{R} ^2$ . Using polar coordinates, we can set $s=r\cos (\theta ), t=r\sin (\theta ),$ where $r=|x|=|(s,t)|$ and $\theta $ the usual polar angle in the $(s,t)$ -plane. To describe the domains in terms of the above polar coordinates, we write

(7) $$ \begin{align} \widetilde \Omega := \{(\theta, r): (s,t)\in\widehat \Omega\}. \end{align} $$

We say that $\Omega $ is an annular domain if its associated domain given by $\widehat \Omega $ in the $(s,t)$ -plane in $\mathbb{R} ^2$ is of the form

$$ \begin{align*}\widetilde \Omega = \Big\{(\theta, r): g_1(\theta)<r<g_2(\theta), \theta\in\Big(0,\frac{\pi}{2}\Big)\Big\}\end{align*} $$

in polar coordinates. Here, $g_i>0$ is smooth on $\left [0,\frac {\pi }{2}\right ]$ with $g_i'(0)=g_i'(\frac {\pi }{2})=0$ and $g_2(\theta )>g_1(\theta )$ on $\left [0,\frac {\pi }{2}\right ].$ Moreover, we say that $\Omega $ is an annular domain with monotonicity if $g_1$ is increasing and $g_2$ is decreasing on $\left (0,\frac {\pi }{2}\right ).$ The class of annular domains with monotonicity is indeed quite rich. For instance, a regular annulus

$$ \begin{align*}\Omega = \left\{x \in \mathbb{R}^N: R_1<|x|<R_2\right\},\end{align*} $$

is an annular domain with monotonicity. We can also consider a slightly more general version where the inner and outer boundaries are replaced with ellipsoids instead of balls. Take $ \Omega $ to have outer boundary given by the ellipsoid

$$ \begin{align*} \sum_{k=1}^{m} \frac{x_k^2}{A^2}+ \sum_{k=m+1}^{N} \frac{x_k^2}{B^2} =1,\end{align*} $$

and the inner boundary given by

$$ \begin{align*}\sum_{k=1}^{m} \frac{x_k^2}{C^2}+ \sum_{k=m+1}^{N} \frac{x_k^2}{D^2} =1,\end{align*} $$

where $ A,B,C,D>0$ are chosen such that the resulting domain is an annular region.

We also assume that the function a (resp. b) is a continuous and strictly positive function of $(s,t)$ that is $a(x)=a(s,t).$ Moreover, we say that a (resp. b) satisfies ( $\mathcal {A}$ ) if a (resp. b) is a continuously differentiable function with respect to $(s,t)$ and $sa_{t}-ta_s \leq 0$ (resp. $sb_{t}-tb_s \leq 0$ ) in $\widehat \Omega .$

As observed in [Reference Clapp and Pistoia8], for problems having the $O(m)\times O(n)$ symmetry (with ${N=m+n}$ ) on an annular domain that is also invariant by $O(m)\times O(n)$ , the hyperbola

$$ \begin{align*}\frac{1}{p}+\frac{1}{q} = 1-\frac{2}{N},\end{align*} $$

is no longer the critical hyperbola, as one has the required compactness for the following improved inequality:

$$ \begin{align*}\frac{1}{p}+\frac{1}{q} \geq \max\Big \{1-\frac{2}{n+1}, 1-\frac{2}{m+1}\Big\}.\end{align*} $$

Our main contribution in this paper is to go well beyond the latter inequality for the lower bound of $1/p+1/q$ and to prove the existence for

$$ \begin{align*}\frac{1}{p}+\frac{1}{q} \geq \min\Big\{1-\frac{2}{n+1}, 1-\frac{2}{m+1}\Big\}.\end{align*} $$

We begin with the statement of the first main result arising in this paper.

Theorem 1.1 Suppose $\Omega $ is an annular domain with monotonicity in $\mathbb{R} ^N$ for $N\geq 3.$ Let $N=m+n$ for $1\leq n\leq m.$ In addition, assume that a and b satisfy $(\mathcal {A}).$ Let $q\geq p> 2.$ If

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}> 1-\frac{2}{n+1} = \min\left\{1-\frac{2}{n+1}, 1-\frac{2}{m+1}\right\} \quad \text{ for } n> \frac{p+1}{p-1},\end{align*} $$

then equation (1) has a positive weak solution $(u,v)$ that is invariant under the group action $O(m)\times O(n)$ .

We would like to remark that in Theorem 1.1, we are not imposing any lower bound condition on $1/p+1/q$ for the case where $n\leq (p+1)/(p-1).$ We would also like to remind the reader that the functions a and b do not add any compactness to the problem. In addition, we note that the same proof in Theorem 1.1 is valid for the case when $a=b=1.$ Similar results have been proved in an influential paper by Y. Y. Li [Reference Li17] in the scalar version.

As for our remaining results, we consider a specific problem of (1) given by

(8) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = v^{p-1}, \quad &\text{ in } \Omega,\\ -\Delta v = u^{q-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial\Omega, \end{array} \right. \end{align} $$

where the conditions in problem (1) are carried over to problem (8) with the exception that $a=b=1$ and $\Omega $ is an annulus defined as

$$ \begin{align*}\Omega = \left\{x \in \mathbb{R}^N: R_1<|x|<R_2\right\},\end{align*} $$

where the radii $R_1$ and $R_2$ satisfy certain conditions. We shall see in the following theorem that the solution obtained from Theorem 1.1 is non-radial.

Theorem 1.2 Let $m,n \geq 1$ with $N=m+n,$ and $q\geq p> 2$ . Suppose $(u,v)$ is the solution of (8) obtained in Theorem 1.1 that is invariant under the group action $O(m)\times O(n)$ . Define

$$ \begin{align*}\lambda_H := \inf_{0\neq \eta \in H_0^1(\Omega)} \frac{\int_\Omega |\nabla \eta|^2}{\int_\Omega \frac{|\eta|^2}{|x|^2}}dx.\end{align*} $$

If

$$ \begin{align*}(p-1)(q-1)> \Big(1+\frac{2N}{\lambda_H}\Big)^2\left(\frac{q}{p}\right),\end{align*} $$

then $(u,v)$ is non-radial.

We remark that $\lambda _H$ is the optimal constant in the classical Hardy inequality on $\Omega ,$ and is independent of the choices of p and $q.$ Indeed, $\lambda _H$ is the characteristic of the domain $\Omega $ and not the supercritical nonlinearities in the system of equations (1). The following theorem addresses the multiplicity of positive solutions corresponding to problem (8).

Theorem 1.3 For each $1 \leq k \leq \lfloor \frac {N}{2}\rfloor ,$ where $\lfloor x\rfloor $ is the floor function of $x,$ and $q\geq p> 2,$ the equation (8) has k distinct positive non-radial solutions if

$$ \begin{align*}(p-1)(q-1)>\Big(1+\frac{2N}{\lambda_H}\Big)^2\left(\frac{q}{p}\right)\end{align*} $$

and either of the following two conditions hold:

  1. 1. $k>(p+1)/(p-1)$ and

    $$ \begin{align*}\frac{1}{p}+\frac{1}{ q}> 1-\frac{2}{k+1}\end{align*} $$
    or;
  2. 2. $k\leq (p+1)/(p-1)$ and no lower bound condition imposed for $1/p+1/q.$

The following corollary states that under certain conditions on the radii, we conclude that there is a range of p and q for which $\lambda _H$ becomes sufficiently large. We intend to use Theorem 1.3 to validate this corollary.

Corollary 1.4 The following assertions hold:

  1. 1. For $0<R_1<R_2 <\infty $ and sufficiently large $(p-1)(q-1)(p/q),$ there are at least $\lfloor \frac {p+1}{p-1}\rfloor $ distinct positive non-radial solutions of (8).

  2. 2. For fixed

    $$ \begin{align*}\frac{1}{p}+\frac{1}{q}> 1-\frac{2}{\lfloor \frac{N}{2}\rfloor+1}\end{align*} $$
    and
    $$ \begin{align*}(p-1)(q-1)> \frac{q}{p}\end{align*} $$
    with $\lambda _H$ sufficiently large, there are $\lfloor \frac {N}{2}\rfloor $ distinct positive non-radial solutions of (8). For instance, under either of the following conditions, $\lambda _H$ can be sufficiently large and therefore there are $\lfloor \frac {N}{2}\rfloor $ distinct positive non-radial solutions of (8):
    1. 2.(a): Let $R_1=R$ and $R_2=R+1.$ Then $\lambda _H$ is sufficiently large for large values of $R.$ Note by scaling, we can take $R_1=1$ and $R_2= 1+\frac {1}{R}$ and obtain the same result for large $R.$

    2. 2.(b): Let $R < \gamma (R)$ with $\frac {\gamma (R)}{R} \to 1$ as $R\to \infty .$ With $\Omega _R = \{x\in \mathbb{R} ^N: R<|x|<\gamma (R) \},$ we have that for R large enough, the $\lambda _H$ corresponding to $\Omega _R$ is sufficiently large.

The structure of the paper is presented as follows. In Section 2, we present some fundamental background on domains of double revolution along with some important definitions and results arising from convex analysis and minimax principles for lower semi-continuous functions. Afterward in Section 3, we use a variational formulation on convex closed subsets of an appropriate Sobolev space that plays a detrimental role in proving our main results of the paper. We conclude the paper with Section 4 on the proofs of the remaining results which deal with multiplicity results of positive non-radial solutions when $\Omega $ is an annulus.

2 Preliminaries

2.1 Domains of double revolution

We dedicate this section to introduce some fundamental background on domains of double revolution. Unless otherwise stated, we assume that our domain is of double revolution. We begin with some notations. Let $\mathbb{R} ^N = \mathbb{R} ^m \times \mathbb{R} ^n,$ where $m,n \geq 1$ and $m+n = N.$ For each $x=(x_1, x_2,\dots ,x_N)\in \Omega \subset \mathbb{R} ^N, $ we shall consider the change of variables in terms of s and t as

$$ \begin{align*}s := \{x_1^2 + \cdots + x_m^2\}^{\frac{1}{2}}, \quad t := \{x_{m+1}^2 + \cdots + x_N^2\}^{\frac{1}{2}}.\end{align*} $$

Definition 2.1 We say that $\Omega \subset \mathbb{R} ^N$ is a domain of double revolution if it is invariant under rotations of the first m variables and invariant under rotations of the last n variables. Equivalently, $\Omega $ is of the form $\Omega = \{x \in \mathbb{R} ^N: (s,t)\in U\}$ , where U is a domain in $\mathbb{R} ^2$ which is symmetric with respect to the two coordinate axes. In fact,

$$ \begin{align*}U = \{(s,t)\in \mathbb{R}^2: x=(x_1 = s, x_2=0, \dots, x_m=0, x_{m+1}=t,\dots, x_N=0)\in \Omega\},\end{align*} $$

is the intersection of $\Omega $ with the $(x_1, x_{m+1})$ -plane.

We remark that U is smooth if and only if $\Omega $ is smooth. Next, we denote $\widehat \Omega $ to be the intersection of U with the first quadrant of $\mathbb{R} ^2,$ in other words,

(9) $$ \begin{align} \widehat \Omega = \{(s,t)\in U: s>0, t>0\}. \end{align} $$

Using polar coordinates, we can set ${s=r\cos (\theta ), t=r\sin (\theta )}$ where $r=|x|=|(s,t)|$ and $\theta $ the usual polar angle in the $(s,t)$ -plane.

In this paper, we consider domains to be annular with a certain monotonicity (or convexity) assumption with respect to the polar angle. In addition, all domains under consideration will be bounded in $\mathbb{R} ^N$ with smooth boundary unless explicitly stated. We describe the domains in terms of the above polar coordinates by

(10) $$ \begin{align} \widetilde \Omega := \{(\theta, r): (s,t)\in\widehat \Omega\}. \end{align} $$

Now, we can formally define an annular domain stated as follows.

Definition 2.2 Let $\Omega \subset \mathbb{R} ^N$ be a domain of double revolution in $\mathbb{R} ^N$ with $N=m+n$ for $m,n\geq 1.$ We say that $\Omega $ is an annular domain if its associated domain given by $\widehat \Omega $ in the $(s,t)$ -plane in $\mathbb{R} ^2$ is of the form

$$ \begin{align*}\widetilde \Omega = \Big\{(\theta, r): g_1(\theta)<r<g_2(\theta), \theta\in\Big(0,\frac{\pi}{2}\Big)\Big\}\end{align*} $$

in polar coordinates. Here, $g_i>0$ is smooth on $\left [0,\frac {\pi }{2}\right ]$ with $g_i'(0)=g_i'(\frac {\pi }{2})=0$ and $g_2(\theta )>g_1(\theta )$ on $\left [0,\frac {\pi }{2}\right ].$ Moreover, we say that $\Omega $ is an annular domain with monotonicity if $g_1$ is increasing and $g_2$ is decreasing on $\left (0,\frac {\pi }{2}\right ).$

We refer the interested reader to the paper [Reference Cowan and Moameni11] and [Reference Cowan and Moameni12] for further explicit examples of annular domains. Now, we provide some assumptions on the functions a and b in which we encounter later in the paper.

Definition 2.3 We assume that a and b are continuous and strictly positive functions of $(s,t)$ that is $a(x)=a(s,t)$ (resp. $b(x)=b(s,t)$ ). Moreover, we say that a (resp. b) satisfies ( $\mathcal {A}$ ) if a (resp. b) is a continuously differentiable function with respect to $(s,t)$ and $sa_{t}-ta_s \leq 0$ (resp. $sb_{t}-tb_s \leq 0$ ) in $\widehat \Omega .$

2.2 Convex analysis and minimax principles for lower semi-continuous functions

In this section, we lay out some important definitions and fundamental results from convex analysis and minimax principles for lower semi-continuous functions. Consider V to be a real Banach space, $V^*$ to be its topological dual, and we denote the pairing of V and $V^*$ by $\langle \cdot , \cdot \rangle .$ We denote the weak topology on V induced by the pairing $\langle \cdot , \cdot \rangle $ to be $\sigma (V, V^*).$ We say a function $\Psi : V\to \mathbb{R} $ is weakly lower semi-continuous if for each $u \in V$ and for any sequence $\{u_n\}_{n=1}^\infty $ approaching u in the weak topology $\sigma (V, V^*),$

$$ \begin{align*}\Psi(u) \leq \liminf_{n\to\infty}\Psi(u_n).\end{align*} $$

Consider $\Phi : V\to \mathbb{R} \cup \{\infty \}$ to be a proper convex function. We define the subdifferential $\partial \Psi $ of $\Psi $ to be the following set-valued operator: if $u\in Dom(\Psi )=\{v\in V: \Psi (v) < \infty \},$ then we set

$$ \begin{align*}\partial \Psi(u) = \{u^*\in V^*; \langle u^*, v-u\rangle + \Psi(u) \leq \Psi(v), \forall v \in V\}\end{align*} $$

and if $u \notin Dom(\Psi ),$ we set $\partial \Psi (u)=\emptyset .$ If $\Psi $ is Gâteaux differentiable at $u,$ then we denote the derivative of $\Psi $ at u by $D\Psi (u).$ In this case, $\partial \Psi (u) = \{D\Psi (u)\}.$

Now, we arrive to the topic on minimax principles for lower semi-continuous functions. We begin with the definition of a critical point arising in Szulkin [Reference Szulkin30].

Definition 2.4 Let V be a real Banach space, $\Phi \in C^1(V,\mathbb{R} ),$ and $\Psi : V \to (-\infty , \infty ]$ be a proper (i.e., $Dom(\Psi ) \neq \emptyset $ ), convex and lower semi-continuous function. A point $u\in V$ is said to be a critical point of

$$ \begin{align*}I:= \Psi-\Phi\end{align*} $$

if $u\in Dom(\Psi )$ and if it satisfies the inequality

$$ \begin{align*}\langle D\Phi(u), u-v\rangle + \Psi(v)-\Psi(u) \geq 0, \quad \forall v\in V.\end{align*} $$

We utilize the following important property of uniformly convex spaces.

Proposition 2.1 Suppose that V is a uniformly convex Banach space. Let $\{u_n\}_{n=1}^\infty $ be a sequence in V such that $u_n \rightharpoonup u$ weakly $\sigma (V, V^*)$ and

$$ \begin{align*}\limsup_{n\to\infty}\|u_n\| \leq \|u\|.\end{align*} $$

Then $u_n \to u$ strongly.

The following definition leads to the mountain pass theorem in which we primarily use to prove our first main result.

Definition 2.5 We say that I satisfies the Palais–Smale compactness condition (PS) if for every sequence $\{u_n\}_{n=1}^\infty $ such that:

  1. (i) $I(u_n) \to c \in \mathbb{R} ,$

  2. (ii) $\langle D\Phi (u_n), u_n-v\rangle + \Psi (v)-\Psi (u_n) \geq -\epsilon _n \|v-u_n\|, \quad \forall v \in V,$

where $\epsilon _n \to 0,$ we have $\{u_n\}_{n=1}^\infty $ possessing a convergent subsequence.

Now, we present the mountain pass theorem provided by Szulkin [Reference Szulkin30].

Theorem 2.6 (Mountain Pass Theorem)

Let $I: V\to (-\infty , \infty ]$ be of the form

$$ \begin{align*}I:= \Psi-\Phi,\end{align*} $$

where $\Psi : V \to (-\infty , \infty ]$ is a proper convex and lower semi-continuous function and $\Phi \in C^1(V,\mathbb{R} ).$ Suppose that I satisfies the Palais–Smale condition and the mountain pass geometry (MPG):

  1. (i) $I(0)=0,$

  2. (ii) there exists $e \in V$ such that $I(e) \leq 0,$

  3. (iii) there exists some $\rho $ such that $0< \rho < \|e\|$ and for every $u\in V$ with $\|u\| = \rho $ one has $I(u)> 0.$

Then I has a critical value $c>0$ which is characterized by

$$ \begin{align*}c= \inf_{\gamma \in \Gamma} \sup_{t\in [0,1]} I[\gamma(t)],\end{align*} $$

where $\Gamma = \{\gamma \in C([0,1], V): \gamma (0)=0, \gamma (1)=e\}.$

3 A variational formulation and the proof of Theorem 1.1

Our interest in this paper lies within solving the following system:

(11) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)v^{p-1}, \quad &\text{ in } \Omega,\\ -\Delta v = b(x)u^{q-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial\Omega, \end{array} \right. \end{align} $$

where $\Omega $ is a bounded annular domain (not necessarily an annulus) in $\mathbb{R} ^N, (N \geq 3), q\geq p> 2,$ and $a,b \in C(\bar \Omega )$ with $a(x)\geq a_0>0$ and $b(x)\geq b_0>0$ where $a_0$ and $b_0$ are constants. Let $p'=p/(p-1)$ and consider the Banach space $V=W^{2,p'}(\Omega ) \cap W_0^{1, p'}(\Omega ) \cap L^q(\Omega )$ equipped with the following norm:

$$ \begin{align*}\|u\|_V = \|u\|_{W^{2,p'}(\Omega)} + \|u\|_{W_0^{1,p'}(\Omega)} + \|u\|_{L^q(\Omega)}.\end{align*} $$

Recall the duality pairing between V and its dual space $V^*$ is defined by

$$ \begin{align*}\langle u,u^*\rangle = \int_\Omega u(x)u^*(x)dx, \quad \forall u\in V, u^* \in V^*.\end{align*} $$

Following for instance the work by Wang [Reference Wang32], one can get from (11) that

$$ \begin{align*}v=(-\Delta u)^{\frac{1}{p-1}}a(x)^{-\frac{1}{p-1}}.\end{align*} $$

Inserting this equation into the second equation of (11) results in the following scalar equation corresponding to the u-component:

$$ \begin{align*} -\Delta\left((-\Delta u)^{\frac{1}{p-1}}a(x)^{-\frac{1}{p-1}}\right) = b(x) u^{q-1}. \end{align*} $$

Considering the fact that $p'-1=1/(p-1)$ we arrive at

(12) $$ \begin{align}-\Delta\left((-\Delta u)^{p'-1}a(x)^{-(p'-1)}\right) = b(x) u^{q-1}.\end{align} $$

Formally, the Euler–Lagrange functional associated with problem (12) is given by

$$ \begin{align*}I(u) := \frac{1}{p'}\int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{q}\int_\Omega b(x)|u|^q dx.\end{align*} $$

We define $\Psi : V \to \mathbb{R} $ and $\Phi : V \to \mathbb{R} $ by

$$ \begin{align*}\Psi(u) = \frac{1}{p'}\int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx\end{align*} $$

and

$$ \begin{align*}\Phi(u) = \frac{1}{q}\int_\Omega b(x)|u|^q dx,\end{align*} $$

respectively. Let K be a convex subset of $V.$ Finally, we introduce the functional ${I_K: V \to (-\infty , \infty ]}$ to be defined by

(13) $$ \begin{align} I_K(u) := \Psi_K(u) - \Phi(u), \end{align} $$

where the restriction of $\Psi $ on K at $u,$ denoted by $\Psi _K(u)$ is defined by

$$ \begin{align*}\Psi_K(u)=\left\{ \begin{array}{@{}cc} \frac{1}{p'}\int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx,& \quad u \in K,\\ +\infty, & \quad u \not \in K. \end{array} \right. \end{align*} $$

We denote the functional $I_K$ the Euler–Lagrange functional corresponding to (12) restricted on $K.$

The following proposition states the existence of a critical point for the functional $I_K$ and we use Theorem 2.6 to prove the proposition.

Proposition 3.1 Let $\Omega $ be a domain in $\mathbb{R} ^N$ , and let $q\geq p> 2.$ Let $a,b \in C(\bar \Omega )$ with $a(x)\geq a_0>0$ and $b(x)\geq b_0>0$ where $a_0$ and $b_0$ are constants. Consider the Euler–Lagrange functional $I: V \to \mathbb{R} $ associated with problem (12)

$$ \begin{align*}I(u) := \frac{1}{p'}\int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{q}\int_\Omega b(x)|u|^q dx.\end{align*} $$

Let K be a weakly closed convex subset of $W^{2,p'}(\Omega )\cap W_0^{1, p'}(\Omega ) $ which is compactly embedded in $L^q(\Omega ).$ Then the functional I has a critical point $\bar u$ on K by means of Definition 2.4.

Proof Note that the function a is bounded from above, and is also away from zero. Thus, an equivalent norm on $W^{2,p'}(\Omega )\cap W_0^{1, p'}(\Omega ) $ can be defined by

$$ \begin{align*}\|u\|_{W^{2,p'}(\Omega)}^{p'} = \int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx, \qquad \forall u \in W^{2,p'}(\Omega)\cap W_0^{1, p'}(\Omega).\end{align*} $$

By assumption, K is compactly embedded in $L^q(\Omega ).$ So there exists a constant $C>0$ such that

(14) $$ \begin{align} \|u\|_{W^{2,p'}(\Omega)} \leq \|u\|_V \leq C\|u\|_{W^{2,p'}(\Omega)} \quad \forall u\in K. \end{align} $$

In order to satisfy the mountain pass theorem, we must satisfy the (PS)-compactness condition and the mountain pass geometry. We begin by verifying the (PS)-compactness condition. Suppose that $\{u_n\}_{n=1}^\infty $ is a sequence in K such that $I(u_n) \to c \in \mathbb{R} , \epsilon _n \to 0,$ and

(15) $$ \begin{align} \Psi_K(v) - \Psi_K(u_n) + \langle D\Phi(u_n), u_n-v \rangle \geq -\epsilon_n \|v-u_n\|_V \quad \forall v\in V. \end{align} $$

We want to prove that $\{u_n\}_{n=1}^\infty $ has a converging subsequence in $V.$ First, we prove that $\{u_n\}_{n=1}^\infty $ is bounded in $W^{2,p'}(\Omega ).$ Since $I(u_n) \to c,$ it follows that for large values of $n,$ we obtain

(16) $$ \begin{align} I(u_n) &= \frac{1}{p'}\int_\Omega \frac{|-\Delta u_n|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{q}\int_\Omega b(x)|u_n|^q dx \nonumber\\ &= \frac{1}{p'}\|u_n\|_{W^{2,p'}(\Omega)}^{p'} - \frac{1}{q}\int_\Omega b(x)|u_n|^q dx \nonumber\\ &\leq c+1. \end{align} $$

Note that

$$ \begin{align*}\langle D\Phi(u_n), u_n\rangle = \int_\Omega b(x)|u_n|^{q-1}u_n \cdot u_n dx = \int_\Omega b(x)|u_n|^q dx.\end{align*} $$

Since $q>2>p',$ there exists $\delta>0$ such that

$$ \begin{align*}\delta+1>\big(1+\frac{\delta}{q}\big)^{p'}.\end{align*} $$

Setting $v=ru_n$ in (15) with $r=1+\delta /q,$ we get

(17) $$ \begin{align} &\frac{1}{p'}\int_\Omega \frac{|-\Delta ru_n|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{p'}\int_\Omega \frac{|-\Delta u_n|^{p'}}{a(x)^{p'-1}} dx \nonumber\\&\quad+ \int_\Omega b(x)|u_n|^{q-2}u_n\cdot (u_n-ru_n) dx \geq -\epsilon_n \|ru_n-u_n\|_V \nonumber\\ \implies &\frac{r^{p'}}{p'}\int_\Omega \frac{|-\Delta u_n|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{p'}\int_\Omega \frac{|-\Delta u_n|^{p'}}{a(x)^{p'-1}} dx\nonumber\\&\quad + \int_\Omega b(x)|u_n|^{q-2}u_n\cdot (u_n-ru_n) dx \geq -(r-1)\epsilon_n \|u_n\|_V \nonumber\\\implies &\frac{r^{p'}-1}{p'}\|u_n\|_{W^{2,p'}(\Omega)}^{p'} + (1-r)\int_\Omega b(x)|u_n|^q dx \geq -(r-1)\epsilon_n \|u_n\|_V \nonumber \\ \implies &\frac{1-r^{p'}}{p'}\|u_n\|_{W^{2,p'}(\Omega)}^{p'} + (r-1)\int_\Omega b(x)|u_n|^q dx \leq (r-1)\epsilon_n \|u_n\|_V. \end{align} $$

Multiplying (16) by $\delta $ and adding the result by (17) yield that

$$ \begin{align*} \Big(\frac{\delta}{p'}+\frac{1-r^{p'}}{p'}\Big)\|u_n\|_{W^{2,p'}(\Omega)}^{p'} \leq \delta c + \delta+ \frac{\epsilon_n \delta }{q}\|u_n\|_V. \end{align*} $$

Note that for n large enough, by applying (14), we obtain

$$ \begin{align*} \|u_n\|_{W^{2,p'}(\Omega)}^{p'} &< C_0(1+\|u_n\|_V) \\ &\leq C_0\Big(1+C\|u_n\|_{W^{2,p'}(\Omega)}\Big), \end{align*} $$

for a constant $C_0.$ Thus, we conclude that $\{u_n\}_{n=1}^\infty $ is bounded in $W^{2,p'}(\Omega ).$ Since $\{u_n\}_{n=1}^\infty $ is bounded in $W^{2,p'}(\Omega ),$ it follows that, up to a subsequence, there exists ${\bar u \in W^{2,p'}(\Omega )}$ such that $u_n \rightharpoonup \bar u$ weakly in $W^{2,p'}(\Omega )$ and $u_n \to \bar u$ a.e.. By assumption that K is compactly embedded in $L^q(\Omega ),$ we can deduce from boundedness of $\{u_n\}_{n=1}^\infty \subset K$ in $W^{2,p'}(\Omega )$ strong convergence of $u_n$ to $\bar u$ in $L^q(\Omega ).$ Setting $v=\bar u$ in (15), we get

(18) $$ \begin{align} \frac{1}{p'}\Big(\|\bar u\|_{W^{2,p'}(\Omega)}^{p'} - \|u_n\|_{W^{2,p'}(\Omega)}^{p'}\Big) + \int_\Omega b(x)|u_n|^{q-2}u_n \cdot(u_n - \bar u) dx \geq -\epsilon_n\|u_n - \bar u\|_V. \end{align} $$

Taking $\limsup _{n\to \infty }$ on both sides of (18), we obtain

$$ \begin{align*}\frac{1}{p'}\Big(\limsup_{n\to \infty} \|u_n\|_{W^{2,p'}(\Omega)}^{p'} - \|\bar u\|_{W^{2,p'}(\Omega)}^{p'}\Big) \leq 0.\end{align*} $$

By Proposition 2.1, we have

$$ \begin{align*}u_n \to \bar u \quad \text{ strongly in } W^{2,p'}(\Omega),\end{align*} $$

and therefore, we conclude that $u_n \to \bar u$ strongly in $V,$ as desired. Now, we verify the mountain pass geometry for the functional $I_K.$ Clearly, $I_K(0)=0$ which satisfies condition $(i).$ For condition $(ii),$ let $u\in K.$ Then for $t\geq 0,$

$$ \begin{align*} I_K(tu) &= \frac{1}{p'}\int_\Omega \frac{|-\Delta tu|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{q}\int_\Omega b(x)|tu|^q dx \\ &=\frac{t^{p'}}{p'}\int_\Omega \frac{|-\Delta u|^{p'}}{a(x)^{p'-1}} dx - \frac{t^q}{q}\int_\Omega b(x)|u|^q dx. \end{align*} $$

Since $q> 2>p',$ it follows that for t large enough, we obtain $I_K(tu) < 0$ and setting $e:= tu,$ condition $(ii)$ holds. To satisfy condition $(iii),$ take $u\in K$ with $\|u\|_V = \rho>0.$ Then

$$ \begin{align*}I_K(u) = \frac{1}{p'}\|u\|_{W^{2,p'}(\Omega)}^{p'} -\frac{1}{q}\int_\Omega b(x)|u|^q dx.\end{align*} $$

By (14), there exists a constant $C>0$ such that for all $u\in K,$ we have

(19) $$ \begin{align} \|u\|_{W^{2,p'}(\Omega)} \leq \|u\|_V \leq C \|u\|_{W^{2,p'}(\Omega)}. \end{align} $$

In addition, we have

$$ \begin{align*}\int_\Omega b(x)|u|^q dx \leq C_1\|u\|_V^q,\end{align*} $$

for some constant $C_1>0.$ So,

$$ \begin{align*} I_K(u) &= \frac{1}{p'}\|u\|_{W^{2,p'}(\Omega)}^{p'} - \frac{1}{q}\int_\Omega b(x)|u|^q dx\\ &\geq \frac{1}{p'}\|u\|_{W^{2,p'}(\Omega)}^{p'} - \frac{C_1}{q}\|u\|_V^q \\ &\geq \frac{1}{{p'}C^{p'}}\|u\|_V^{p'} - \frac{C_1}{q}\|u\|_V^q \\ &= \frac{1}{{p'}C^{p'}}\rho^{p'} - \frac{C_1}{q}\rho^q>0, \end{align*} $$

provided $\rho $ is small enough as $q> 2>p'.$ Note that if $u\not \in K,$ then $I_K(u)>0$ by definition of $\Psi _K(u).$ Thus, the mountain pass geometry holds for the functional $I_K.$ By the mountain pass theorem, $I_K$ has a critical point $\bar u \in K$ with $I_K(\bar u) = c,$ where $c>0$ is the critical value characterized by

$$ \begin{align*}c=\inf_{\gamma \in \Gamma} \sup_{t\in[0,1]} I(\gamma(t)),\end{align*} $$

where $\Gamma = \{\gamma \in C([0,1], V): \gamma (0)=0, \gamma (1)=e, I_K(\gamma (1))\leq 0\}.$

Lemma 3.1 Let V be a reflexive Banach space, and let $f: V \to \mathbb{R} $ be a convex and differentiable functional. If

(20) $$ \begin{align} f(u)-f(\bar u) \geq \langle Df(u), u-\bar u\rangle, \end{align} $$

then $Df(u)=Df(\bar u), $ where $\langle .,.\rangle $ is the duality pairing between V and $V^*.$ In particular, if f is strictly convex, then $u=\bar u.$

Proof By the convexity of $f,$

(21) $$ \begin{align} f(\bar u)-f(u) \geq \langle Df(u), \bar u-u\rangle \implies f(u)-f(\bar u) \leq \langle Df(u), u-\bar u\rangle. \end{align} $$

So, (20) and (21) implies that

$$ \begin{align*}f(u)-f(\bar u) = \langle Df(u), u-\bar u\rangle.\end{align*} $$

Note that for all $v\in V,$

$$ \begin{align*}f(v)-f(u) \geq \langle Df(u), v-u\rangle.\end{align*} $$

Equivalently,

$$ \begin{align*} f(v) \geq f(u) + \langle Df(u), v-u\rangle &\implies f(v) \geq f(u) + \langle Df(u), v \rangle - \langle Df(u), u\rangle \\ &\implies f(v) - \langle Df(u), v\rangle \geq f(u) - \langle Df(u), u\rangle. \end{align*} $$

Let $G(v) = f(v) -\langle Df(u), v\rangle .$ Then for all $v \in V,$

$$ \begin{align*}G(v) = f(v) -\langle Df(u),v\rangle \geq f(u) - \langle Df(u), u\rangle=G(u),\end{align*} $$

and when $v=\bar u,$

$$ \begin{align*}G(\bar u) = f(\bar u)-\langle Df(u), \bar u\rangle = f(u) - \langle Df(u),u\rangle=G(u).\end{align*} $$

So G attains its minimum at $v =\bar u,$ i.e., $DG(\bar u)=0.$ Thus,

$$ \begin{align*}Df(\bar u) - Df(u) = 0.\end{align*} $$

Now, we show that $u=\bar u$ provided that f is strictly convex. Indeed, it follows that

$$ \begin{align*}\langle Df(u)-Df(\bar u), u-\bar u\rangle = 0,\end{align*} $$

from which we obtain the desired result.

Inspired by an argument in [Reference Moameni22], the following proposition links the critical points of $I_K$ to the solutions of the system (11).

Proposition 3.2 Let $\bar u$ be a critical point of the functional $I_K.$ If there exists $\tilde u\in K$ and $\tilde v\in W^{2,q'}(\Omega )\cap W_0^{1, q'}(\Omega ),$ where $1/q + 1/q' = 1$ such that

(22) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta \tilde u = a(x)|\tilde v|^{p-2}\tilde v,\\ -\Delta \tilde v = b(x)|\bar u|^{q-2}\bar u, \end{array} \right. \end{align} $$

then $\bar u=\tilde u$ , and $(\tilde u,\tilde v)$ is a solution of

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)|v|^{p-2}v,\\ -\Delta v = b(x)|u|^{q-2}u. \end{array} \right. \end{align*} $$

Proof Define the functional $F: W^{2,p'}(\Omega )\cap W_0^{1, p'}(\Omega ) \to \mathbb{R} $ by

$$ \begin{align*}F(w) = \frac{1}{p'}\int_\Omega \frac{|-\Delta w|^{p'}}{a(x)^{p'-1}} dx - \int_\Omega b(x)|\bar u|^{q-2}\bar u wdx.\end{align*} $$

We first show that $\tilde u$ is a critical point of $F.$ By (22), we have that

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta \tilde u = a(x)|\tilde v|^{p-2}\tilde v,\\ -\Delta \tilde v = b(x)|\bar u|^{q-2}\bar u. \end{array} \right. \end{align*} $$

Therefore,

(23) $$ \begin{align}\left\{ \begin{array}{@{}ll} \tilde v = \frac{1}{a(x)^{p'-1}}|-\Delta \tilde u|^{p'-2}(-\Delta \tilde u),\\ \bar u = \frac{1}{b(x)^{q'-1}}|-\Delta \tilde v|^{q'-2}(-\Delta \tilde v). \end{array} \right. \end{align} $$

Now, take $\eta \in W^{2,p'}(\Omega ) \cap W_0^{1,p'}(\Omega ).$ It follows that

$$ \begin{align*} \langle F'(\tilde u),\eta\rangle &= \int_\Omega \frac{1}{a(x)^{p'-1}}|-\Delta \tilde u|^{p'-2}(-\Delta \tilde u)(-\Delta \eta) dx - \int_\Omega b(x)|\bar u|^{q-2}\bar u \eta dx\\ &= \int_\Omega \tilde v (-\Delta \eta)dx - \int_\Omega b(x)|\bar u|^{q-2} \bar u \eta dx, \qquad (\text{as a result of } (23))\\&= \int_\Omega (-\Delta \tilde v)\eta dx - \int_\Omega b(x)|\bar u|^{q-2}\bar u \eta dx\\ &= \int_\Omega b(x)|\bar u|^{q-2}\bar u \eta dx - \int_\Omega b(x)|\bar u|^{q-2}\bar u \eta dx, \qquad (\text{as a result of } (22))\\&=0. \end{align*} $$

Thus, $\tilde u$ is a critical point of F. It then follows that

$$ \begin{align*} 0&=\langle F'(\tilde u), \tilde u-\bar u\rangle \\&\quad= \int_\Omega \frac{1}{a(x)^{p'-1}}|-\Delta \tilde u|^{p'-2}(-\Delta \tilde u)(-\Delta (\tilde u-\bar u)) dx - \int_\Omega b(x)|\bar u|^{q-2}\bar u (\tilde u-\bar u) dx, \end{align*} $$

from which we obtain

(24) $$ \begin{align} \int_\Omega \frac{1}{a(x)^{p'-1}}|-\Delta \tilde u|^{p'-2}(-\Delta \tilde u)(-\Delta (\tilde u-\bar u)) dx = \int_\Omega b(x)|\bar u|^{q-2}\bar u (\tilde u-\bar u) dx. \end{align} $$

Since $\bar u$ is a critical point on $I_K,$ by definition of a critical point, we have

(25) $$ \begin{align} \frac{1}{p'}\int_\Omega \frac{|-\Delta w|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{p'} \int_\Omega \frac{|-\Delta \bar u|^{p'}}{a(x)^{p'-1}} dx \geq \langle b(x)|\bar u|^{q-2}\bar u, w-\bar u\rangle, \quad \forall w\in K. \end{align} $$

Plugging (24) into (25) for $w = \tilde u,$ we get

$$ \begin{align*}\frac{1}{p'}\int_\Omega \frac{|-\Delta \tilde u|^{p'}}{a(x)^{p'-1}} dx - \frac{1}{p'} \int_\Omega \frac{|-\Delta \bar u|^{p'}}{a(x)^{p'-1}} dx \geq \int_\Omega \frac{1}{a(x)^{p'-1}}|-\Delta \tilde u|^{p'-2}(-\Delta \tilde u)(-\Delta (\tilde u-\bar u)) dx.\end{align*} $$

Thus, by Lemma 3.1, we obtain

$$ \begin{align*}\tilde u = \bar u.\end{align*} $$

The result now follows from (22) considering $\tilde u = \bar u.$

So far, we have considered K to be a weakly closed convex subset of $W^{2, p'}(\Omega )$ which is compactly embedded in $L^q(\Omega ).$ Now, we explicitly define our convex set K to be given by

(26) $$ \begin{align} K=K(m,n):=\left\{0\leq u=u(s,t) \in W_{G}^{2,p'}(\Omega)\cap W_0^{1,p'}(\Omega): su_t - tu_s \leq 0 \text{ a.e. in } \widehat \Omega\right\}, \end{align} $$

where $W_G^{2,p'}(\Omega ) :=\{u \in W^{2, p'}(\Omega ): gu = u, \quad \forall g \in G\}$ where $G:= O(m) \times O(n).$ Here, $O(k)$ is the orthogonal group in $\mathbb{R} ^k$ with $gu(x):=u(g^{-1}x).$ We remind the reader that we can express K as functions u such that if we write $(s,t)$ in terms of polar coordinates, we have $u_\theta \leq 0$ on $\widetilde \Omega $ defined in (10). Before we introduce the embedding theorem for annular domains, for the convenience of the reader, we recall the following standard embedding theorem for which we make frequent use in this paper.

Theorem 3.2 Let $\mathcal {O}$ be a bounded domain in $\mathbb{R} ^k.$ Let $j \geq 1$ be an integer, and let ${1\leq \mathcal {P} < \infty .}$ Suppose $\mathcal {O}$ satisfies the cone condition. Then the following embeddings are compact:

  1. (i) If $j \mathcal {P}< k,$ then

    $$ \begin{align*}W^{j,\mathcal{P}}(\mathcal{O}) \hookrightarrow L^d(\mathcal{O}), \quad \text{ for } 1\leq d < \mathcal{P}^*=k\mathcal{P}/(k-j\mathcal{P}).\end{align*} $$
  2. (ii) If $j\mathcal {P} \geq k,$ then

    $$ \begin{align*}W^{j,\mathcal{P}}(\mathcal{O}) \hookrightarrow L^d(\mathcal{O}), \quad \text{ for } 1\leq d< \infty.\end{align*} $$

Theorem 3.3 Let $\Omega \subset \mathbb{R} ^N=\mathbb{R} ^{m+n}$ be an annular domain of double revolution.

  1. (i) (Embedding without monotonicity). Let $\mathcal {P}>1.$ Suppose $\Omega $ has no monotonicity and

    $$ \begin{align*}1 \leq d < \min\left\{\frac{(m+1)\mathcal{P}}{(m+1)-2\mathcal{P}},\frac{(n+1)\mathcal{P}}{(n+1)-2\mathcal{P}}\right\}.\end{align*} $$
    Then the embedding $W_{G}^{2,\mathcal {P}}(\Omega ) \hookrightarrow L^d(\Omega )$ is compact with the obvious interpretation if $(m+1)-2\mathcal {P} \leq 0$ and $(n+1)-2\mathcal {P} \leq 0.$
  2. (ii) (Embedding with monotonicity). Let $p'>1$ and suppose $\Omega $ is a domain of double revolution with monotonicity, $n\leq m$ and

    $$ \begin{align*}1 \leq d < \frac{(n+1)p'}{(n+1)-2p'} = \max\left\{\frac{(m+1)p'}{(m+1)-2p'},\frac{(n+1)p'}{(n+1)-2p'}\right\}.\end{align*} $$
    In addition, let
    $$ \begin{align*}K:=\left\{0\leq u=u(s,t) \in W_{G}^{2,p'}(\Omega)\cap W_0^{1,p'}(\Omega): su_t - tu_s \leq 0 \text{ a.e. in } \widehat \Omega\right\}.\end{align*} $$
    Then the embedding $K \hookrightarrow L^d(\Omega )$ is compact with the obvious interpretation if $(n+1)-2p' \leq 0.$

Proof We begin by proving $(i).$ Assume that $N=m+n.$ Then, expressing in terms of s and $t,$ i.e., $u(x) = u(s,t),$ we obtain

$$ \begin{align*}\int_\Omega |u|^d dx = c\int_{\widehat \Omega} |u(s,t)|^d s^{m-1}t^{n-1} dsdt.\end{align*} $$

Take $\delta $ small enough so that $t\geq \delta $ if and only if $s \leq \delta .$ So

(27) $$ \begin{align}&\int_{\widehat \Omega}|u(s,t)|^d s^{m-1}t^{n-1} dsdt \\&\quad= \int_{\{\widehat \Omega, t\geq \delta\}} |u(s,t)|^d s^{m-1}t^{n-1} dsdt + \int_{\{\widehat \Omega, s\geq \delta\}} |u(s,t)|^d s^{m-1}t^{n-1} dsdt.\nonumber\end{align} $$

Looking at the first term on the right-hand side of (27),

$$ \begin{align*}\int_{\{\widehat \Omega, t\geq \delta\}} |u(s,t)|^d s^{m-1}t^{n-1} dsdt \leq c_1 \int_{\widehat \Omega} |u(s,t)|^ds^{m-1} dsdt.\end{align*} $$

Let $u(s,t) = u(y,z),$ where $s=|y|$ and $t=|z|.$ Then by change of variables,

$$ \begin{align*}\int_{\widehat \Omega} |u(s,t)|^d s^{m-1}dsdt = c_0\int_{\Omega_1} |u(y,t)|^d dydt,\end{align*} $$

where $\Omega _1 =\{(y,t): (|y|,t)\in \widehat \Omega \}\in \mathbb{R} ^m \times \mathbb{R} .$ Note that $\Omega _1 \subset \mathbb{R} ^{m+1}.$ If

$$ \begin{align*}d < \frac{(m+1)\mathcal{P}}{(m+1)-2\mathcal{P}},\end{align*} $$

then by Theorem 3.2,

$$ \begin{align*} \Big(\int_{\Omega_1} |u(y,t)|^d dydt\Big)^{\mathcal{P}/d} &\leq c_2 \|u\|^{\mathcal{P}}_{W^{2,\mathcal{P}}(\Omega_1)}\\ &\leq c_3 \int_{\Omega_1} \Big(|D^2 u(y,t)|^{\mathcal{P}}+|\nabla u(y,t)|^{\mathcal{P}} + |u(y,t)|^{\mathcal{P}}\Big)t^{n-1}dydt\\ &\leq c_4 \int_\Omega \Big(|D^2 u(y,z)|^{\mathcal{P}}+|\nabla u(y,z)|^{\mathcal{P}} + |u(y,z)|^{\mathcal{P}}\Big) dydz\\ &= c_4 \|u\|_{W^{2,\mathcal{P}}(\Omega)}^{\mathcal{P}}. \end{align*} $$

So we have the compact embedding $W_{G}^{2,\mathcal {P}}(\Omega ) \hookrightarrow L^d(\Omega )$ for

$$ \begin{align*}d< \frac{(m+1)\mathcal{P}}{(m+1)-2\mathcal{P}}.\end{align*} $$

For the second term on the right-hand side of (27), we have that

$$ \begin{align*} \int_{\{\widehat \Omega, s\geq \delta\}} |u(s,t)|^d s^{m-1}t^{n-1} dsdt &\leq c'_1 \int_{\widehat \Omega} |u(s,t)|^dt^{n-1} dsdt\\ &=c_1^{"}\int_{\Omega_2}|u(s,z)|^d dsdz, \end{align*} $$

where $\Omega _2 = \{(s,z): (s,|z|)\in \widehat \Omega \} \in \mathbb{R} ^n \times \mathbb{R} .$ Note that $\Omega _2 \subset \mathbb{R} ^{n+1}.$ If

$$ \begin{align*}d< \frac{(n+1)\mathcal{P}}{(n+1)-2\mathcal{P}},\end{align*} $$

then by Theorem 3.2,

$$ \begin{align*} \Big(\int_{\Omega_2} |u(s,z)|^d dsdz\Big)^{\mathcal{P}/d} &\leq c'_2 \|u\|^{\mathcal{P}}_{W^{2,\mathcal{P}}(\Omega_2)} \\ &\leq c'_3 \int_{\Omega_2}\Big(|D^2 u(s,z)|^{\mathcal{P}}+|\nabla u(s,z)|^{\mathcal{P}} + |u(s,z)|^{\mathcal{P}}\Big)s^{m-1}dsdz\\ &\leq c'_4 \int_\Omega \Big(|D^2u(y,z)|^{\mathcal{P}}+|\nabla u(y,z)|^{\mathcal{P}} + |u(y,z)|^{\mathcal{P}}\Big) dydz\\ &= c'_4 \|u\|_{W^{2,\mathcal{P}}(\Omega)}^{\mathcal{P}}. \end{align*} $$

So we have the embedding $W_G^{2,\mathcal {P}}(\Omega ) \hookrightarrow L^d(\Omega )$ is compact for

$$ \begin{align*}d< \frac{(n+1)\mathcal{P}}{(n+1)-2\mathcal{P}}.\end{align*} $$

Taking

$$ \begin{align*}\min\left\{\frac{(m+1)\mathcal{P}}{(m+1)-2\mathcal{P}},\frac{(n+1)\mathcal{P}}{(n+1)-2\mathcal{P}}\right\},\end{align*} $$

we obtain the desired result in part (i). Now, we proceed with proving part $(ii).$ Let $1\leq n \leq m$ and

$$ \begin{align*}d < \frac{(n+1)p'}{(n+1)-2p'}.\end{align*} $$

Using polar coordinates with $s=r\cos (\theta )$ and $t=r\sin (\theta ),$ we obtain

$$ \begin{align*}\int_{\widehat \Omega} u(s,t)^d s^{m-1}t^{n-1} dsdt = \int_0^{\pi/2}\int_{g_1}^{g_2} r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}(\theta)u(r,\theta)^drdrd\theta.\end{align*} $$

For $\theta \in [\pi /3, \pi /2]$ , we have that $\sin (\theta ) \leq c\sin (\theta -\pi /4)$ for some constant $c>0.$ According to the monotonicity properties of $g_1, g_2$ and $\theta \mapsto u(r,\theta ),$ we obtain that

$$ \begin{align*} &\int_{\pi/3}^{\pi/2}\int_{g_1(\theta)}^{g_2(\theta)} r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}u(r,\theta)^d rdrd\theta\\ &\leq c^{n-1} \int_{\pi/3}^{\pi/2}\int_{g_1(\theta-\pi/4)}^{g_2(\theta-\pi/4)}r^{m-1}\cos^{m-1}(\theta-\pi/4)r^{n-1}\sin^{n-1}(\theta-\pi/4)u(r,\theta-\pi/4)^drdrd\theta\\ &=c^{n-1}\int_{\pi/12}^{\pi/4}\int_{g_1(\theta)}^{g_2(\theta)} r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}(\theta)u(r,\theta)^drdrd\theta. \end{align*} $$

Thus, there is a constant $C_1>0$ such that

$$ \begin{align*}&\int_0^{\pi/2}\int_{g_1}^{g_2}r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}(\theta)u(r,\theta)^drdrd\theta \\&\quad\leq C_1\int_0^{\pi/3}\int_{g_1}^{g_2}r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}(\theta)u(r,\theta)^drdrd\theta.\end{align*} $$

On the other hand,

$$ \begin{align*}\int_0^{\pi/3}\int_{g_1}^{g_2}r^{m-1}\cos^{m-1}(\theta)r^{n-1}\sin^{n-1}(\theta)u(r,\theta)^drdrd\theta = \int_{\{\widehat \Omega, s\geq \beta\}}u(s,t)^ds^{m-1}t^{n-1}dsdt\end{align*} $$

for some positive constant $\beta .$ Hence,

$$ \begin{align*}\Big(\int_{\{\widehat \Omega, s\geq \beta\}}u(s,t)^ds^{m-1}t^{n-1}dsdt\Big)^{p'/d} \leq C_2 \Big(\int_{\{\widehat \Omega, s\geq \beta\}}u(s,t)^dt^{n-1}dsdt\Big)^{p'/d}.\end{align*} $$

Thus, by part $(i),$ we have

$$ \begin{align*} &\Big(\int_{\{\widehat \Omega, s\geq \beta\}}u(s,t)^dt^{n-1}dsdt\Big)^{p'/d} \\&\quad\leq C_3\int_{\{\widehat \Omega, s\geq \beta\}}\Big(|D^2 u(s,t)|^{p'}+|\nabla u(s,t)|^{p'} + |u(s,t)|^{p'}\Big)t^{n-1}dsdt\\ &\quad\leq C_4 \int_{\{\widehat \Omega, s\geq \beta\}}\Big(|D^2 u(s,t)|^{p'}+|\nabla u(s,t)|^{p'} + |u(s,t)|^{p'}\Big)t^{n-1}s^{m-1}dsdt\\ &\quad\leq C_5\int_{\widehat \Omega}\Big(|D^2 u(s,t)|^{p'}+|\nabla u(s,t)|^{p'} + |u(s,t)|^{p'}\Big)t^{n-1}s^{m-1}dsdt\\ &\quad= C_6 \int_\Omega \Big(|D^2 u|^{p'}+|\nabla u|^{p'} + |u|^{p'}\Big) dx \\ &\quad= C_6 \|u\|_{W^{2,{p'}}(\Omega)}^{p'}. \end{align*} $$

This completes the proof.

Remark 3.4 Let $p>1$ , and let $p'$ be the conjugate of $p,$ that is,

$$ \begin{align*}\frac{1}{p} + \frac{1}{p'} = 1.\end{align*} $$

Suppose $\Omega $ is an annular domain with monotonicity, and $n\leq m.$ We can rewrite the condition in Theorem 3.3(ii) given by

$$ \begin{align*} 1\leq d < \frac{(n+1)p'}{(n+1)-2p'} = \max\left\{\frac{(m+1)p'}{(m+1)-2p'}, \frac{(n+1)p'}{(n+1)-2p'}\right\}, \quad &\text{ for } n>2p'-1,\\ 1\leq d < \infty, \quad &\text{ for } n\leq 2p'-1, \end{align*} $$

as follows:

$$ \begin{align*} \frac{1}{p}+\frac{1}{d}> 1-\frac{2}{n+1}=\min\left\{1-\frac{2}{m+1}, 1-\frac{2}{n+1}\right\}, \quad &\text{ for } n>\frac{p+1}{p-1},\\ \text{no lower bound condition imposed on } \frac{1}{p}+\frac{1}{d}, \quad &\text{ for } n\leq \frac{p+1}{p-1}. \end{align*} $$

Proof By Theorem 3.3 $(ii)$ , we have compactness when

$$ \begin{align*}1\leq d < \frac{(n+1)p'}{(n+1)-2p'} = \max\left\{\frac{(m+1)p'}{(m+1)-2p'},\frac{(n+1)p'}{(n+1)-2p'}\right\}, \quad \text{ for } n+1-2p'>0,\end{align*} $$

and

$$ \begin{align*}1\leq d < \infty, \quad \text{ for } n+1-2p'\leq 0.\end{align*} $$

Equivalently,

$$ \begin{align*}1\leq d < \frac{(n+1)p}{(n+1)(p-1)-2p}, \quad \text{ for } (n+1)(p-1)-2p>0,\end{align*} $$

and

$$ \begin{align*}1\leq d < \infty, \quad \text{ for } (n+1)(p-1)-2p \leq 0.\end{align*} $$

Simplifying, we obtain

$$ \begin{align*}\frac{1}{p} +\frac{1}{d}>1-\frac{2}{n+1}, \quad \text{ for } (n+1)(p-1)-2p > 0,\end{align*} $$

and with no lower bound condition on $1/p+1/d$ for $(n+1)(p-1)-2p \leq 0.$ On the other hand,

$$ \begin{align*}(n+1)(p-1)-2p \leq 0 \iff n\leq \frac{p+1}{p-1}.\end{align*} $$

Therefore, we conclude that

$$ \begin{align*} \frac{1}{p}+\frac{1}{d}> 1-\frac{2}{n+1}=\min\left\{1-\frac{2}{m+1},1-\frac{2}{n+1}\right\}, \quad &\text{ for } n > \frac{p+1}{p-1},\\ \text{ no lower bound condition imposed on } \frac{1}{p}+\frac{1}{d}, \quad &\text{ for } n\leq \frac{p+1}{p-1}. \\[-40pt]\end{align*} $$

We require the following proposition arising from Cowan and Moameni in [Reference Cowan and Moameni11].

Proposition 3.3 Suppose $\Omega \subset \mathbb{R} ^m \times \mathbb{R} ^n$ is an annular domain with monotonicity (see Definition 2.2), and assume that $\kappa (x)$ satisfies ( $\mathcal {A}$ ) as in Definition 2.3. Let $0 \leq \tilde u\in H_{0,G}^1(\Omega )\cap L^{\mathcal {P}}(\Omega )$ with $s\tilde u_t - t\tilde u_s \leq 0$ a.e. on $\widehat \Omega $ where $\mathcal {P}>2,$ and

$$ \begin{align*}H_{0,G}^1(\Omega) :=\big \{u \in H_{0}^1(\Omega): gu = u, \quad \forall g \in G=O(m) \times O(n)\big \}.\end{align*} $$

Suppose that $\tilde v$ is the solution of

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta \tilde v = \kappa(x) \tilde u^{\mathcal{P}-1}, &\quad \text{ in } \Omega,\\ \tilde v = 0, &\quad \text { on } \partial \Omega. \end{array} \right. \end{align*} $$

Then $0\leq \tilde v\in H_{0,G}^1(\Omega )\cap L^{\mathcal {P}}(\Omega )$ with $s\tilde v_t - t\tilde v_s \leq 0$ a.e. on $\widehat \Omega .$

Now, we can prove the first main result of the paper.

Proof of Theorem 1.1.

First, we recall the convex cone $K:=K(m,n)$ as in (26), namely,

$$ \begin{align*} K=K(m,n):=\left\{0\leq u=u(s,t) \in W_{G}^{2,p'}(\Omega)\cap W_0^{1,p'}(\Omega): su_t - tu_s \leq 0 \text{ a.e. in } \widehat \Omega\right\}, \end{align*} $$

where $W_G^{2,p'}(\Omega ) :=\{u \in W^{2, p'}(\Omega ): gu = u, \quad \forall g \in G\},$ where $G:= O(m) \times O(n)$ , and where $O(k)$ is the orthogonal group in $\mathbb{R} ^k$ with $gu(x):=u(g^{-1}x).$ By Theorem 3.3 $(ii)$ , we have that the embedding $K\hookrightarrow L^q(\Omega )$ is compact for

$$ \begin{align*} 1\leq q < \frac{(n+1)-p'}{(n+1)-2p'}, \quad &\text{ if } (n+1)-2p'>0,\\ 1\leq q < \infty, \quad &\text{ if } (n+1)-2p' \leq 0. \end{align*} $$

By Remark 3.4, this can be rewritten as

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}> 1-\frac{2}{n+1} = \min\left\{1-\frac{2}{m+1}, 1-\frac{2}{n+1}\right\}, \quad \text{ for } n>\frac{p+1}{p-1}\end{align*} $$

with no condition on the lower bound of

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}, \quad \text{ for } 1\leq n \leq \frac{p+1}{p-1}.\end{align*} $$

It follows from Proposition 3.1 that $I_K$ has a critical point $\bar u$ in K with $I_K(\bar u)=c,$ where $c>0$ is the critical value characterized by

$$ \begin{align*}c=\inf_{\gamma \in \Gamma}\sup_{t \in [0,1]} I(\gamma(t)),\end{align*} $$

where $\Gamma = \{\gamma \in C([0,1], V): \gamma (0) = 0, \gamma (1) = e, I_K(\gamma (1))\leq 0.\}$ Since $I_K(\bar u)>0,$ it follows that $\bar u$ is nonzero. Now, we want to show that there exists $\tilde u\in K$ and $\tilde v \in W^{2,q'}(\Omega )\cap W_0^{1,q}(\Omega )$ satisfying

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta \tilde u = a(x)|\tilde v|^{p-2}\tilde v,\\ -\Delta \tilde v = b(x)|\bar u|^{q-2}\bar u, \end{array} \right. \end{align*} $$

so that we can conclude by Proposition 3.2 that $(\tilde u, \tilde v)$ is a solution of

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)|v|^{p-2}v,\\ -\Delta v = b(x)|u|^{q-2}u. \end{array} \right. \end{align*} $$

Indeed, it follows from Proposition 3.3 that there exists $\tilde v \in K$ such that

$$ \begin{align*}-\Delta \tilde v = \tilde b(x) |\bar u|^{q-2}\bar u.\end{align*} $$

Applying Proposition 3.3 once again, there exists $\tilde u \in K$ satisfying

$$ \begin{align*}-\Delta \tilde u = \tilde a(x)|\tilde v|^{p-2}\tilde v.\end{align*} $$

Thus, $(\tilde u, \tilde v)$ satisfies the equation

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta \tilde u = a(x)|\tilde v|^{p-2}\tilde v,\\ -\Delta \tilde v = b(x)|\bar u|^{q-2}\bar u, \end{array} \right. \end{align*} $$

and by Proposition 3.2, we conclude that $(\tilde u, \tilde v)$ is a solution of

$$ \begin{align*}\left\{ \begin{array}{@{}ll} -\Delta u = a(x)|v|^{p-2}v,\\ -\Delta v = b(x)|u|^{q-2}u. \end{array} \right. \end{align*} $$

Note that both $\tilde u $ and $\tilde v $ are nonzero and nonnegative. It now follows from the strong maximum principle [Reference Gilbarg and Trudinger15, Theorem 8.19] that both $\tilde u$ and $\tilde v$ are strictly positive.

4 Non-radial solutions when $\Omega $ is an annulus

In this section, we discuss the case when $a(x)=b(x)=1$ , and $\Omega $ is an annulus, that is, $\Omega =\{x:\, R_1< |x|<R_2\}, $

(28) $$ \begin{align}\left\{ \begin{array}{@{}ll} -\Delta u = v^{p-1}, \quad &\text{ in } \Omega,\\ -\Delta v = u^{q-1}, \quad &\text{ in } \Omega,\\ u,v>0, \quad &\text{ in } \Omega,\\ u=v=0, \quad &\text{ on } \partial\Omega. \end{array} \right. \end{align} $$

We shall prove that the solution obtained in Theorem 1.1 is non-radial when radii $R_1, R_2$ satisfy certain conditions. We first begin with the following general result for positive solutions of (28).

Theorem 4.1 Let $q\geq p\geq 2.$ Assume that $(u,v)$ is a positive solution of (28). The following assertion hold:

(29) $$ \begin{align} \inf_{0 \neq \eta \in H^1_0(\Omega)} \frac{\int_{\Omega} |\nabla \eta|^2\, dx }{\int_\Omega \eta^2 v(x)^{\frac{p-2}{2}}u(x)^{\frac{q-2}{2}}\, dx }\leq \sqrt{\frac{q}{p}}. \end{align} $$

Proof We first prove that

(30) $$ \begin{align} q v(x)^p \geq p u (x)^q, \qquad \forall x \in \Omega. \end{align} $$

Let $\sigma =p/q \in (0,1]$ and $e=\sigma ^{-\frac {1}{q}}.$ Define $z(x)=u(x)-e v(x)^\sigma .$ It follows that

$$ \begin{align*} \Delta z & = \Delta u-e\sigma v^{\sigma-1}\Delta v-e \sigma (\sigma-1)v^{\sigma-2}|\nabla v|^2\\ &\geq \Delta u-e\sigma v^{\sigma-1}\Delta v\\ &= v^{\sigma-1}\left(\frac{u^{q-1}}{e^{q-1}}-v^{\sigma (q-1)} \right), \end{align*} $$

from which we obtain that $\Delta z\geq 0$ on the set

$$ \begin{align*}\{ x\in \Omega: z(x)\geq 0\}.\end{align*} $$

Take $\epsilon>0.$ It follows that

$$ \begin{align*}(z-\epsilon)^+\Delta z \geq 0,\end{align*} $$

and therefore

$$ \begin{align*}\int_\Omega |\nabla (z-\epsilon )^+|^2\, dx \leq 0.\end{align*} $$

This implies that $z \leq \epsilon ,$ and since $\epsilon $ is arbitrary the inequality (30) follows.

We shall now prove inequality (29). It follows from inequality (30) that

$$ \begin{align*} v \geq \left(\frac{p}{q}\right)^{\frac{1}{p}}u ^{\frac{q}{p}}.\end{align*} $$

Therefore,

$$ \begin{align*}v^{\frac{p-2}{2}}u^{\frac{q-2}{2}} v^2=u^{\frac{q-2}{2}} v^{\frac{p}{2}}v \geq \sqrt{\frac{p}{q}}u^{\frac{q-2}{2}} u^{\frac{q}{2}}v= \sqrt{\frac{p}{q}}u^{q-1}v.\end{align*} $$

It then follows that

$$ \begin{align*} \inf_{0 \neq \eta \in H^1_0(\Omega)} \frac{\int_{\Omega} |\nabla \eta|^2\, dx }{\int_\Omega \eta^2 v(x)^{\frac{p-2}{2}}u(x)^{\frac{q-2}{2}}\, dx }\leq \frac{\int_{\Omega} |\nabla v|^2\, dx }{\int_\Omega v^2 v(x)^{\frac{p-2}{2}}u(x)^{\frac{q-2}{2}}\, dx } \leq \frac{\int_{\Omega} u^{q-1}v\, dx }{\int_\Omega\sqrt{\frac{p}{q}}u^{q-1}v\, dx }=\sqrt{\frac{q}{p}.} \end{align*} $$

Remark 4.2 We would like to remark that inequalities of the type (30) were first developed to study Liouville-type theorems for stable Lane–Emden systems and Hardy–Hénon elliptic systems on $\mathbb{R} ^N$ . We refer the interested reader to [Reference Cowan10, Reference Phan24, Reference Souplet28].

Let $w(x)=w(s,t)$ be a function of $(s, t).$ If we write w in terms of polar coordinates (recall we have $ s=r\cos (\theta ), t = r \sin (\theta )$ ), we obtain that $w(x)=w(r, \theta )$ . Writing the Laplace operator in polar coordinates gives

(31) $$ \begin{align} -\Delta w(x)= -w_{rr} -\frac{(N-1) w_r}{r}- \frac{w_{\theta \theta}}{r^2} + \frac{w_\theta}{r^2} h(\theta), \end{align} $$

where

(32) $$ \begin{align} h(\theta)= (m-1) \tan(\theta) - \frac{(n-1)}{\tan(\theta)}. \end{align} $$

Let $ (\mu _1,\psi _1)$ be the second eigenpair of the following eigenvalue problem:

(33) $$ \begin{align} \left\{\begin{array}{@{}ll} -\psi_1"(\theta) + \psi_1'(\theta)h(\theta)= \mu_1 \psi_1(\theta),& \text{ in } (0, \frac{\pi}{2}), \\ \psi'(\theta)>0, & \text{ in } (0, \frac{\pi}{2}), \\ \psi_1'(0)= \psi_1'(\frac{\pi}{2})=0, & \end {array} \right. \end{align} $$

and note that the first eigenpair is given by $ (\mu _0,\psi _0)=(0,1)$ . Note in this problem, one can find an explicit solution given by

$$ \begin{align*} \mu_1=2N, \quad \psi_1(\theta)= \frac{m-n}{N} - \cos(2 \theta),\end{align*} $$

and note we can apply Sturm–Liouville theory and count the number of zeros of $ \psi _1$ to see it is in fact the second pair.

Proof of Theorem 1.2.

Let us assume the solution $(u,v)$ of (28) obtained in Theorem 1.1 is radial. Let $(\lambda _1, \varphi ) $ be the first eigenpair of the following eigenvalue problem:

$$ \begin{align*} \left\{\begin{array}{@{}ll} -\varphi"(r)-\frac{(N-1)\varphi'(r)}{r}+\frac{2N \varphi(r)}{r^2}=\lambda_1v(r)^{\frac{p-2}{2}}u(r)^{\frac{q-2}{2}}\varphi(r),& r \in (R_1,R_2), \\ \varphi(r)=0, & r \in \{R_1, R_2\}. \end {array} \right. \end{align*} $$

Set $w(x)=\varphi (r)\psi _1(\theta )$ and note that

$$ \begin{align*} -\Delta w(x)&= -w_{rr} -\frac{(N-1) w_r}{r}- \frac{w_{\theta \theta}}{r^2} + \frac{w_\theta}{r^2} h(\theta)\\ &= -\varphi_{rr}(r)\psi_1(\theta) -\frac{(N-1) \varphi_r(r)\psi_1(\theta)}{r}- \frac{\varphi(r)\psi_1"( \theta)}{r^2} + \frac{\varphi(r)\psi_1'(\theta)}{r^2} h(\theta)\\ &=-\varphi_{rr}(r)\psi_1(\theta) -\frac{(N-1) \varphi_r(r)\psi_1(\theta)}{r}+\frac{2N\varphi(r)\psi_1( \theta)}{r^2}\\ &= \lambda_1v(|x|)^{\frac{p-2}{2}}u(|x|)^{\frac{q-2}{2}}w(x). \end{align*} $$

Recall that $I_K(u)= c>0,$ where the critical value c is characterized by

$$ \begin{align*}c= \inf_{\gamma\in \Gamma}\max_{\tau\in [0,1] }I_K[\gamma(\tau)],\end{align*} $$

where

$$ \begin{align*}\Gamma= \{\gamma\in C([0,1], V) : \gamma(0)=0\neq \gamma(1), I_K(\gamma(1))\leq 0\}.\end{align*} $$

For the sake of simplifying the notations, we use I instead of $I_K$ in the rest of the proof.

Set $\gamma _\sigma (\tau )= \tau ({u}+ \sigma w)l$ , where $l>0$ is chosen in such a way that $I\big ( ({u}+ \sigma w)l\big )\leq 0$ for all $|\sigma |\leq 1$ . Note that $\gamma _{\sigma }\in \Gamma $ . We shall show that there exists $\sigma>0$ such that for every $\tau \in [0,1]$ one has $I(\gamma _\sigma (\tau ))< I({u})$ , and therefore,

$$ \begin{align*}c\leq \max_{\tau\in[0,1]} I(\gamma_\sigma(\tau))< I({u}),\end{align*} $$

which leads to a contradiction since $I(u)=c.$ Note first that there exists a unique twice differentiable real function g on a small neighborhood of zero with $g'(0)=0$ and $g(0)=1/l$ such that $\max _{\tau \in [0,1]} I(\gamma _\sigma (\tau ))=I\big (g(\sigma )({u}+ \sigma w)l\big ).$ We now define $h: \mathbb{R} \to \mathbb{R} $ by

$$ \begin{align*}h(\sigma)=I\big (g(\sigma)({u}+ \sigma w)l\big)-I(u).\end{align*} $$

Clearly, we have $h(0)=0$ . Note also that $h'(0)=0$ due to the fact that $I'(u)=0$ . We now show that $h"(0)<0$ . Indeed,

$$ \begin{align*} h"(0)&=(p'-1)\int_\Omega |\Delta u|^{p'-2}(-\Delta w)^2\, dx-(q-1)\int_\Omega | u|^{q-2}(w)^2\, dx\\ &=(p'-1)\lambda_1^2\int_\Omega |\Delta u|^{p'-2} v(|x|)^{p-2}u(|x|)^{q-2} w^2(x)\, dx-(q-1)\int_\Omega | u|^{q-2}(w)^2\, dx\\ &=(p'-1)\lambda_1^2\int_\Omega \big ( v(|x|)^{p-1}\big)^{p'-2} v(|x|)^{p-2}u(|x|)^{q-2} w^2(x)\, dx-(q-1)\int_\Omega | u|^{q-2}(w)^2\, dx\\ &=(p'-1)\lambda_1^2\int_\Omega u(|x|)^{q-2} w^2(x)\, dx-(q-1)\int_\Omega | u|^{q-2}(w)^2\, dx\\ &=\Big ((p'-1)\lambda_1^2-(q-1)\Big )\int_\Omega u(|x|)^{q-2} w^2(x)\, dx. \end{align*} $$

Note that

$$ \begin{align*} (p'-1)\lambda_1^2-(q-1)<0 \qquad \text{ if and only if }\qquad \lambda_1^2 < (p-1)(q-1).\end{align*} $$

Let $\lambda _H$ denote the best constant in the Hardy inequality

$$ \begin{align*}\lambda_H=\inf_{0 \neq \eta \in H^1_0(\Omega)}\frac{\int_{\Omega} |\nabla \eta|^2 \,dx}{\int_{\Omega} \frac{| \eta|^2 }{|x|^2}\,dx}.\end{align*} $$

It follows that

$$ \begin{align*}\lambda_1&=\inf_{0 \neq \eta \in H^1_0(\Omega)} \frac{\int_{\Omega} |\nabla \eta|^2\, dx +2N\int_{\Omega} \frac{| \eta|^2}{|x|^2}\, dx }{\int_\Omega \eta^2 v(x)^{\frac{p-2}{2}}u(x)^{\frac{q-2}{2}}\, dx } \\&\quad\leq \inf_{0 \neq \eta \in H^1_0(\Omega)} \frac{\Big(1+\frac{2N}{\lambda_H}\Big)\int_{\Omega} |\nabla \eta|^2\, dx }{\int_\Omega \eta^2 v(x)^{\frac{p-2}{2}}u(x)^{\frac{q-2}{2}}\, dx }\leq \sqrt{\frac{q}{p}}\left(1+\frac{2N}{\lambda_H}\right), \end{align*} $$

where the last inequality follows from Theorem 4.1. In particular, if

$$ \begin{align*}\frac{q}{p}\left(1+\frac{2N}{\lambda_H}\right)^2<(p-1)(q-1),\end{align*} $$

then $(p'-1)\lambda _1^2-(q-1)<0.$ This implies that $h"(0)<0.$ This in fact shows that

$$ \begin{align*}\max_{\tau\in[0,1]} I(\gamma_\sigma(\tau))=I\big (g(\sigma)({u}+ \sigma v)l\big)<I(u),\end{align*} $$

for small $\sigma>0$ as desired.

Recall from (26) that

$$ \begin{align*} K=K(m,n):=\left\{0\leq u=u(s,t) \in W_{G}^{2,p'}(\Omega)\cap W_0^{1,p'}(\Omega): su_t - tu_s \leq 0 \text{ a.e. in } \widehat \Omega\right\}, \end{align*} $$

which corresponds to the decomposition $\mathbb{R} ^{m}\times \mathbb{R} ^{n}$ of the annulus ${\Omega =\{x:\, R_1< |x|<R_2\}}$ in $ \mathbb{R} ^N$ with $N=m+n.$ We have the following result regarding the distinction of solutions for different decompositions of $ \mathbb{R} ^N$ .

Lemma 4.3 Let $1 < n <n'\leq \lfloor \frac {N}{2}\rfloor $ and set $m=N-n$ , $m'=N-n'.$ Let $u_{m,n} \in K(m,n)$ and $u_{m',n'}\in K(m',n')$ be the solutions obtained in Theorem 1.1 corresponding to the decomposition $\mathbb{R} ^{m}\times \mathbb{R} ^{n}$ and $\mathbb{R} ^{m'}\times \mathbb{R} ^{n'}$ of $\mathbb{R} ^N$ , respectively. Then $u_{m,n} \not = u_{m',n'}$ unless they are both radial functions.

Proof Let $u_{m,n} =u_{m',n'}=u.$ We shall show that u must be radial. It follows that $u(x)=f(s,t)=g(s',t')$ for two functions f and $g,$ where

$$ \begin{align*} s^2:= { x_1^2 + \cdot \cdot \cdot + x_{m}^2}, \qquad t^2:={x_{m+1}^2 + \cdot \cdot \cdot + x_N^2 }, \end{align*} $$

and

$$ \begin{align*} {s'}^2:= { x_1^2 + \cdot \cdot \cdot + x_{m'}^2}, \qquad {t'}^2:={x_{m'+1}^2 + \cdot \cdot \cdot + x_N^2 }. \end{align*} $$

By assuming $x_i=0$ for $i\not = x_1, x_{m}$ , we obtain that

$$ \begin{align*}g\left(|x_1|, |x_{m}|\right)=g\left(\sqrt{x_1^2+x_{m}^2}, 0\right),\end{align*} $$

from which we obtain that g must be a radial function. To show that f is a radial function, we assume that $x_i = 0$ for $i \neq x_{m'+1}, x_N.$ Then

$$ \begin{align*}f\left(|x_{m'+1}|, |x_N|\right)=g\left(0, \sqrt{x_{m'+1}^2 + x_N^2}\right)\end{align*} $$

from which we obtain that f is a radial function.

Proof of Theorem 1.3.

We begin by proving the existence of a positive solution. Afterward, we show that the positive solution is in fact, non-radial.

Part 1. It follows from Theorem 1.1 that for each $n\leq k$ and $q\geq p> 2,$ equation (28) has a solution of the form $(u_{m,n}, v_{m,n}) =\left (u_{m,n}(s,t), v_{m,n}(s,t)\right )$ , where

$$ \begin{align*} s^2:= { x_1^2 + \cdot \cdot \cdot + x_{m}^2}, \qquad t^2:={x_{m+1}^2 + \cdot \cdot \cdot + x_N^2 }, \end{align*} $$

provided

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}>1-\frac{2}{n+1},\quad \text{ for }n>\frac{p+1}{p-1}.\end{align*} $$

Since $n\leq k,$ it follows that

$$ \begin{align*}1-\frac{2}{n+1} \leq 1-\frac{2}{k+1}, \quad \text{ for } k>\frac{p+1}{p-1}.\end{align*} $$

Thus, for each $n\leq k,$ we have a positive solution provided

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}> 1-\frac{2}{k+1}.\end{align*} $$

Part 2. If $k\leq (p+1)/(p-1),$ then $n\leq (p+1)/(p-1).$ So, by Theorem 1.1, there exists a positive solution of (28).

Now, we proceed to prove that the solution in parts 1 and 2 are non-radial. Indeed, by Theorem 1.2, the solution $(u_{m,n},v_{m,n})$ is non-radial provided

$$ \begin{align*}(p-1)(q-1)> \left(1+\frac{2N}{\lambda_H}\right)^2\left(\frac{q}{p}\right).\end{align*} $$

Thus, for each $n \in \{1,\dots ,k\}$ we have a non-radial solution $(u_{m,n},v_{m,n}).$ On the other hand, by Lemma 4.3, we have that $u_{m,n} \not = u_{m',n'}$ for all $n\not =n'.$ Similarly, by Lemma 4.3, we obtain $v_{m,n} \not = v_{m',n'}$ for all $n \not = n'.$ This indeed implies that we have k distinct positive non-radial solutions.

Proof of Corollary 1.4.

1. For each $k\in \mathbb{N} $ with $1\leq k \leq \lfloor \frac {p+1}{p-1}\rfloor ,$ by part 2 of Theorem 1.3, there exists a solution provided

$$ \begin{align*} (p-1)(q-1)> \left(1+\frac{2N}{\lambda_H}\right)^2\left(\frac{q}{p}\right).\end{align*} $$

Thus, if

$$ \begin{align*}(p-1)(q-1)\left(\frac{p}{q}\right)> \left(1+\frac{2N}{\lambda_H}\right)^2,\end{align*} $$

then we must have $\lfloor \frac {p+1}{p-1}\rfloor $ positive non-radial solutions.

2. Assuming $k=\Big \lfloor \frac {N}{2} \Big \rfloor $ in Theorem 1.3, we obtain that there are $\Bigl \lfloor \frac {N}{2} \Bigr \rfloor $ positive non-radial solutions provided that

$$ \begin{align*}(p-1)(q-1)>\Big(1+\frac{2N}{\lambda_H}\Big)^2\left(\frac{q}{p}\right) \end{align*} $$

and

$$ \begin{align*}\frac{1}{p}+\frac{1}{q}>1-\frac{2}{\Big\lfloor\frac{N}{2} \Big\rfloor+1}.\end{align*} $$

Now, to obtain

$$ \begin{align*}(p-1)(q-1)> \frac{q}{p},\end{align*} $$

we want to show that $\lambda _H$ can be sufficiently large under conditions $2(a)$ and $2(b)$ and hence, we conclude that there are $\lfloor \frac {N}{2}\rfloor $ positive non-radial solutions. As for the proof of $2(a)$ and $2(b),$ we refer the interested reader to [Reference Cowan and Moameni11].

Acknowledgments

We would like to thank the referees for carefully reading our manuscript and for giving us valuable comments that substantially improved the clarity of the original manuscript.

Data availability statement

Data sharing is not applicable to this article as no data-sets were generated or analyzed during the current study.

Competing interests

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Footnotes

A.M. is pleased to acknowledge the support of the National Sciences and Engineering Research Council of Canada.

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