Bose-Einstein condensates and quantum degenerate Ferni gases in optical lattices

Author

Inguscio, M. ; de Mirandes, E. ; Fallani, L. ; Ferlaino, F. ; Fort, C. ; Lye, J. ; Modugno, G. ; Modugno, M. ; Roati, G.

Author_Institution

Dipt. di Fisica, Firenze Univ., Fiorentino

fYear

2005

fDate

17-17 June 2005

Firstpage

704

Lastpage

704

Abstract

The physics of quantum particles in periodic potentials can be described in terms of Bloch waves and indeed many effects originally predicted for electrons moving in a lattice of ions have been observed for ultracold atoms in optical lattices. Interactions among the atoms forming the BEC are responsible for the nonlinear character of the Bloch waves, resulting in the onset of different kinds of instabilities, we have performed a detailed investigation of the stability regimes of a condensate in a moving optical lattice, separately addressing the effects and the timescales of energetic and dynamic instabilities. Spin-polarized Fermi gases are free from these effects and fundamental conduction phenomena, such as the crossover from a conducting to an insulating behaviour, the latter due to a localization of the particles in the lattice, can be observed

Keywords

Bose-Einstein condensation; fermion systems; laser cooling; quantum optics; radiation pressure; Bloch waves; Bose-Einstein condensates; dynamic instabilities; optical lattices; periodic potentials; quantum degenerate Fermi gases; quantum particles; spin-polarized Fermi gases; ultracold atoms; Atom optics; Atomic beams; Gas lasers; Gases; Laboratories; Lattices; Lenses; Optical arrays; Quantum computing; Quantum well lasers;

fLanguage

English

Publisher

ieee

Conference_Titel

Lasers and Electro-Optics Europe, 2005. CLEO/Europe. 2005 Conference on

Conference_Location

Munich

Print_ISBN

0-7803-8974-3

Type

conf

DOI

10.1109/CLEOE.2005.1568480

Filename

1568480