Transverse stability of line soliton and characterization of ground state for wave guide Schrödinger equations

Abstract: In this paper, we study the transverse stability of the line Schr\"{o}dinger soliton under a full wave guide Schr\"{o}dinger flow on a cylindrical domain $\mathbb R\times\mathbb T$. When the nonlinearity is of power type $|\psi|^{p-1}\psi$ with $p>1$, we show that there exists a critical frequency $\omega_{p} >0$ such that the line standing wave is stable for $0<\omega < \omega_{p}$ and unstable for $\omega > \omega_{p}$. Furthermore, we characterize the ground state of the wave guide Schr\"{o}dinger equation. More precisely, we prove that there exists $\omega_{} \in (0, \omega_{p}]$ such that the ground states coincide with the line standing waves for $\omega \in (0, \omega_{}]$ and are different from the line standing waves for $\omega \in (\omega_{*}, \infty)$.