Publication Date
2008
Journal or Book Title
NONLINEARITY
Abstract
The aim of this review is to introduce the reader to some of the physical notions and the mathematical methods that are relevant to the study of nonlinear waves in Bose–Einstein condensates (BECs). Upon introducing the general framework, we discuss the prototypical models that are relevant to this setting for different dimensions and different potentials confining the atoms. We analyse some of the model properties and explore their typical wave solutions (plane wave solutions, bright, dark, gap solitons as well as vortices). We then offer a collection of mathematical methods that can be used to understand the existence, stability and dynamics of nonlinear waves in such BECs, either directly or starting from different types of limits (e.g. the linear or the nonlinear limit or the discrete limit of the corresponding equation). Finally, we consider some special topics involving more recent developments, and experimental setups in which there is still considerable need for developing mathematical as well as computational tools.
Pages
R139-R202
Volume
21
Issue
7
Recommended Citation
Carretero-Gonzalez, R; Frantzeskakis, DJ; and Kevrekidis, PG, "Nonlinear waves in Bose-Einstein condensates: physical relevance and mathematical techniques" (2008). NONLINEARITY. 84.
Retrieved from https://scholarworks.umass.edu/math_faculty_pubs/84
Comments
This is the prepublished version harvested from ArXiv. The published version is located at http://iopscience.iop.org/0951-7715/21/7/R01/