Nonlinear transport of Bose-Einstein condensates through mesoscopic waveguides
- 5 December 2007
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 76 (6) , 063605
- https://doi.org/10.1103/physreva.76.063605
Abstract
We study the coherent flow of interacting Bose-condensed atoms in mesoscopic waveguide geometries. Analytical and numerical methods, based on the mean-field description of the condensate, are developed to study both stationary as well as time-dependent propagation processes. We apply these methods to the propagation of a condensate through an atomic quantum dot in a waveguide, discuss the nonlinear transmission spectrum and show that resonant transport is generally suppressed due to an interaction-induced bistability phenomenon. Finally, we establish a link between the nonlinear features of the transmission spectrum and the self-consistent quasibound states of the quantum dot.Keywords
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This publication has 59 references indexed in Scilit:
- Diffraction of a Bose-Einstein Condensate from a Magnetic Lattice on a MicrochipPhysical Review Letters, 2005
- Matter-wave interferometry in a double well on an atom chipNature Physics, 2005
- Interference of Bose-Einstein condensates split with an atom chipPhysical Review A, 2005
- Nonlinear Self-Trapping of Matter Waves in Periodic PotentialsPhysical Review Letters, 2005
- Nonlinear Dynamics of a Bose-Einstein Condensate in a Magnetic WaveguidePhysical Review Letters, 2003
- Bose–Einstein condensation on a microelectronic chipNature, 2001
- Nonlinear atomic Fabry-Perot interferometer: From the mean-field theory to theatom blockadeeffectPhysical Review A, 2001
- Controlling Cold Atoms using Nanofabricated Surfaces: Atom ChipsPhysical Review Letters, 2000
- Modulated Optical Lattice as an Atomic Fabry-Perot InterferometerPhysical Review Letters, 2000
- Quantum Point Contacts for Neutral AtomsPhysical Review Letters, 1999