Accurate one-dimensional effective description of realistic matter-wave gap solitons

TL;DR

This paper demonstrates that an effective 1D equation accurately models the behavior and stability of matter-wave gap solitons in Bose-Einstein condensates within optical lattices, outperforming the standard 1D GPE.

Contribution

The study validates an effective 1D model as a reliable and computationally efficient alternative to 3D GPE for describing matter-wave gap solitons in optical lattices.

Findings

Effective 1D model predicts soliton trajectories and wavefunctions accurately.

Model correctly determines stability properties via linear and numerical analysis.

Spectrum of eigenfrequencies matches full 3D stability analysis.

Abstract

We consider stationary matter-wave gap solitons realized in Bose--Einstein condensates loaded in one-dimensional (1D) optical lattices and investigate whether the effective 1D equation proposed in [Phys. Rev. A \textbf{77}, 013617 (2008)] can be a reliable alternative to the three-dimensional treatment of this kind of system in terms of the Gross--Pitaevskii equation (GPE). Our results demonstrate that, unlike the standard 1D GPE (which is not applicable in most realistic situations), the above effective model is able to correctly predict the distinctive trajectories characterizing the different gap soliton families as well as the corresponding axial wavefunctions along the entire band gaps. It can also predict the stability properties of the different gap soliton families as follows from both a linear stability analysis and a representative set of numerical computations. In particular, by numerically solving the corresponding Bogoliubov--de Gennes equations we show that the effective 1D model gives the correct spectrum of complex eigenfrequencies responsible for the dynamical stability of the system, thus providing us with a useful tool for the physical description of stationary matter-wave gap solitons in 1D optical lattices.