Orbital and asymptotic stability for standing waves of a NLS equation with concentrated nonlinearity in dimension three

Abstract

We begin to study in this paper orbital and asymptotic stability of standing waves for a model of Schr\"odinger equation with concentrated nonlinearity in dimension three. The nonlinearity is obtained considering a point (or contact) interaction with strength α, which consists of a singular perturbation of the laplacian described by a selfadjoint operator Hα, where the strength α depends on the wavefunction: i u= Hα u, α=α(u). If q is the so-called charge of the domain element u, i.e. the coefficient of its singular part, we let the strength α depend on u according to the law α=-|q|σ, with > 0. This characterizes the model as a focusing NLS with concentrated nonlinearity of power type. For such a model we prove the existence of standing waves of the form u (t)=eiω tω, which are orbitally stable in the range σ ∈ (0,1), and orbitally unstable for σ ≥ 1. Moreover, we show that for σ ∈ (0,1 2) every standing wave is asymptotically stable in the following sense. Choosing initial data close to the stationary state in the energy norm, and belonging to a natural weighted Lp space which allows dispersive estimates, the following resolution holds: u(t) = eiω∞ t ω∞ +Ut*∞ +r∞, as \;\; t → +∞, where U is the free Schr\"odinger propagator, ω∞ > 0 and ∞, r∞ ∈ L2(3) with \| r∞ \|L2 = O(t-5/4) as \;\; t → +∞. Notice that in the present model the admitted nonlinearity for which asymptotic stability of solitons is proved is subcritical.