Possible Superfluidity of a System of Strongly Interacting Fermions

Abstract

The possible superfluidity of a system interacting fermions in investigated on the assumption that an adequate description of the system in its normal'' state is griven by independent fermions in a momentum-dependent potential. On the basis of this assumption we have investigated whether a correlated wave function of the form used by Bardeen, Cooper, and Schrieffer minimizes the ground-state energy. The nonzero terms in the expectation value of the Hamiltonian contain the modified kinetic energy and the full two-body potential between the fermion pairs. An integral equation is obtained in configuration space for the correlation function between pairs. This integral equation is meaningful even for potentials with hard cores and a nonzero solution implies the existence of a superfluid state. A variational method is devised which provides a criterion for superfluidity and a lower bound for the transition temperature into the superfluid state. It is found that a repulsive hard core does not in principle forbid the existence of a superfiuid state, but whereas in the absence of a hard core an attractive two-body potential always leads to a superfiuid state at sufficiently low temperatures, in the presence of a repulsive core there appears to be a critical strength ofmore » attraction needed to form a superfluid state. When the variational principle is applied to liquid He/sup 3/ or to nuclear matter, it ia found for a wide class of trial functions that the system does not become a superfluid. (auth)« less