1,957 research outputs found
Cold atoms at unitarity and inverse square interaction
Consider two identical atoms in a spherical harmonic oscillator interacting
with a zero-range interaction which is tuned to produce an s-wave zero-energy
bound state. The quantum spectrum of the system is known to be exactly
solvable. We note that the same partial wave quantum spectrum is obtained by
the one-dimensional scale-invariant inverse square potential. Long known as the
Calogero-Sutherland-Moser (CSM) model, it leads to Fractional Exclusion
Statistics (FES) of Haldane and Wu. The statistical parameter is deduced from
the analytically calculated second virial coefficient. When FES is applied to a
Fermi gas at unitarity, it gives good agreement with experimental data without
the use of any free parameter.Comment: 11 pages, 3 figures, To appear in J. Phys. B. Atomic, Molecular and
Optical Physic
Atomic Ground-State Energies
It is demonstrated that atomic Hartree–Fock binding energies may be reproduced with great accuracy (within about four parts in a thousand) by a scaled model system in which the electrons are noninteracting, and are bound in a bare Coulomb potential. </jats:p
A Fermion-like description of condensed Bosons in a trap
A Bose-Einstein condensate of atoms, trapped in an axially symmetric harmonic
potential, is considered. By averaging the spatial density along the symmetry
direction over a length that preserves the aspect ratio, the system may be
mapped on to a zero temperature noninteracting Fermi-like gas. The ``mock
fermions'' have a state occupancy factor proportional to the ratio of
the coherance length to the ``hard-core'' radius of the atom. The mapping
reproduces the ground state properties of the condensate, and is used to
estimate the vortex excitation energy analytically. The ``mock-fermion''
description predicts some novel collective excitation in the condensed phase.Comment: 11 pages, REVTE
The virial expansion of a classical interacting system
We consider N particles interacting pair-wise by an inverse square potential
in one dimension (Calogero-Sutherland-Moser model). When trapped harmonically,
its classical canonical partition function for the repulsive regime is known in
the literature. We start by presenting a concise re-derivation of this result.
The equation of state is then calculated both for the trapped and the
homogeneous gas. Finally, the classical limit of Wu's distribution function for
fractional exclusion statistics is obtained and we re-derive the classical
virial expansion of the homogeneous gas using this distribution function.Comment: 9 pages; added references to some earlier work on this problem; this
has led to a significant shortening of the paper and a changed titl
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