Physics – Condensed Matter – Soft Condensed Matter
Scientific paper
2004-03-30
Physics
Condensed Matter
Soft Condensed Matter
16 pages, 3 figures. Submitted to Optics Communications for special issue "Degenerate Quantum Gases"
Scientific paper
10.1016/j.optcom.2004.09.079
Derivation of effective zero-range one-dimensional (1D) interactions between atoms in tight waveguides is reviewed, as is the Fermi-Bose mapping method for determination of exact and strongly-correlated states of ultracold bosonic and fermionic atomic vapors in such waveguides, including spin degrees of freedom. Odd-wave 1D interactions derived from 3D p-wave scattering are included as well as the usual even-wave interactions derived from 3D s-wave scattering, with emphasis on the role of 3D Feshbach resonances for selectively enhancing s-wave or p-wave interactions. A duality between 1D fermions and bosons with zero-range interactions suggested by Cheon and Shigehara is shown to hold for the effective 1D dynamics of a spinor Fermi gas with both even and odd-wave interactions and that of a spinor Bose gas with even and odd-wave interactions, with even(odd)-wave Bose coupling constants inversely related to odd(even)-wave Fermi coupling constants. Some recent applications of Fermi-Bose mapping to determination of many-body ground states of Bose gases and of both magnetically trapped, spin-aligned and optically trapped, spin-free Fermi gases are described, and a new generalized Fermi-Bose mapping is used to determine the phase diagram of ground-state total spin of the spinor Fermi gas as a function of the even and odd-wave coupling constants.
Girardeau Marvin D.
Nguyen Hoi H.
Olshanii Maxim
No associations
LandOfFree
Effective interactions, Fermi-Bose duality, and ground states of ultracold atomic vapors in tight de Broglie waveguides does not yet have a rating. At this time, there are no reviews or comments for this scientific paper.
If you have personal experience with Effective interactions, Fermi-Bose duality, and ground states of ultracold atomic vapors in tight de Broglie waveguides, we encourage you to share that experience with our LandOfFree.com community. Your opinion is very important and Effective interactions, Fermi-Bose duality, and ground states of ultracold atomic vapors in tight de Broglie waveguides will most certainly appreciate the feedback.
Profile ID: LFWR-SCP-O-78518