Bose-Einstein condensation in variable dimensionality

A. A. Svidzinky; A. Chatterjee; A. Chatterjee; A. Gonzalez; A. L. Fetter; A. L. Fetter; A. L. Fetter; A. Sinha; B. A. McKinney; B. Jackson; C. J. Myatt; D. K. Watson; D. K. Watson; E. Fermi; E. Lundh; F. Dalfovo; G. Baym; H. T. C. Stoof; J. L. Bohn; L. H. Thomas; M. Crescimanno; M. Dunn; M. Edwards; M.-O. Mewes; P. Schuck; V. M. Pérez-García

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Bose-Einstein condensation in variable dimensionality

Authors: A. A. Svidzinky
A. Chatterjee
A. Chatterjee
A. Gonzalez
A. L. Fetter
A. L. Fetter
A. L. Fetter
A. Sinha
B. A. McKinney
B. Jackson
C. J. Myatt
D. K. Watson
D. K. Watson
E. Fermi
E. Lundh
F. Dalfovo
G. Baym
H. T. C. Stoof
J. L. Bohn
L. H. Thomas
M. Crescimanno
M. Dunn
M. Edwards
M.-O. Mewes
P. Schuck
V. M. Pérez-García
Publication date: 2 October 2001
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We introduce dimensional perturbation techniques to Bose-Einstein condensation of inhomogeneous alkali gases (BEC). The perturbation parameter is delta=1/kappa, where kappa depends on the effective dimensionality of the condensate and on the angular momentum quantum number. We derive a simple approximation that is more accurate and flexible than the N -> infinity Thomas-Fermi ground state approximation (TFA) of the Gross-Pitaevskii equation. The approximation presented here is well-suited for calculating properties of states in three dimensions and in low effective dimensionality, such as vortex states in a highly anisotropic trap

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