An unconventional deformation of the nonrelativistic spin-1/2 Fermi gas
Abstract
We explore a generalization of nonrelativistic fermionic statistics that interpolates between bosons and fermions, in which up to K particles may occupy a single-particle state. We show that it can be mapped exactly to K flavors of fermions with imaginary polarization. In particular, for K\!=\!2, we use such a mapping to derive the virial coefficients and relate them to those of conventional spin-1/2 fermions in an exact fashion. We also use the mapping to derive next-to-leading-order perturbative results for the pressure equation of state. Our results indicate that the K\!=\!2 particles are more strongly coupled than conventional spin-1/2 fermions, as measured by the interaction effects on the virial expansion and on the pressure equation of state. In the regime set by the unitary limit, the proposed K\!=\!2 deformation represents a universal many-body system whose properties remain largely unknown. In particular, the system can be expected to become superfluid at a critical temperature Tc higher than that of the unitary limit. We suggest it may be possible to realize this system experimentally by engineering a polarized coupling to an electrostatic potential. Finally, we show that the K\!=\!2 system does not display a sign problem for determinantal Monte Carlo calculations, which indicates that Tc can at least in principle be calculated with conventional methods.
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