Trapped Atomic Fermi Gases
Abstract
A many-body system of fermion atoms with a model interaction characterized by the scattering length is considered. We treat both and the density as parameters assuming that the system can be created artificially in a trap. If is negative the system becomes strongly correlated at densities , provided the scattering length is the dominant parameter of the problem. It means that we consider to be much bigger than the radius of the interaction or any other relevant parameter of the system. The density at which the compressibility vanishes is defined by . Thus, a system composed of fermion atoms with the scattering length is completely unstable at low densities, inevitably collapsing until the repulsive core stops the density growth. As a result, any Fermi system possesses the equilibrium density and energy if the bare particle-particle interaction is sufficiently strong to make negative and to be the dominant parameter. This behavior can be realized in a trap. Our results show that a low density neutron matter can have the equilibrium density.
Cite
@article{arxiv.cond-mat/0112373,
title = {Trapped Atomic Fermi Gases},
author = {M. Ya. Amusia and A. Z. Msezane and V. R. Shaginyan},
journal= {arXiv preprint arXiv:cond-mat/0112373},
year = {2009}
}
Comments
6 pages, to be published in Physics Letters A