Ground states for a linearly coupled system of Schrödinger equations on $\mathbb{R}^{N}$ (1807.03436v1)

Abstract: We study the following class of linearly coupled Schr\"{o}dinger elliptic systems $$\left{ \begin{array}{lr} -\Delta u+V_{1}(x)u=\mu|u|^{p-2}u+\lambda(x)v, & \quad x\in\mathbb{R}^{N}, \ -\Delta v+V_{2}(x)v=|v|^{q-2}v+\lambda(x)u, & x\in\mathbb{R}^{N}, \end{array} \right. $$ where $N\geq3$, $2<p\leq q\leq 2^{*}=2N/(N-2)$ and $\mu\geq0$. We consider nonnegative potentials periodic or asymptotically periodic which are related with the coupling term $\lambda(x)$ by the assumption $|\lambda(x)|\leq\delta\sqrt{V_{1}(x)V_{2}(x)}$, for some $0<\delta\<1$. We deal with three cases: Firstly, we study the subcritical case, $2<p\leq q\<2^{*}$, and we prove the existence of positive ground state for all parameter $\mu\geq0$. Secondly, we consider the critical case, $2<p<q=2^{*}$, and we prove that there exists $\mu_{0}\>0$ such that the coupled system possesses positive ground state solution for all $\mu\geq\mu_{0}$. In these cases, we use a minimization method based on Nehari manifold. Finally, we consider the case $p=q=2^{*}$, and we prove that the coupled system has no positive solutions. For that matter, we use a Pohozaev identity type.