Superfluid Gap in Neutron Matter from a Microscopic Effective Interaction

Abstract

Correlated Basis Function (CBF) perturbation theory and the formalism of cluster expansions have been recently employed to obtain an effective interaction from a nuclear Hamiltonian strongly constrained by phenomenology. We report the results of a study of the superfluid gap in pure neutron matter, associated with the formation of Cooper pairs in the 1S0 channel. The calculations have been carried out using an improved version of the CBF effective interaction, in which three-nucleon forces are taken into account using a microscopic model. Our results show that a non-vanishing superfluid gap develops at densities in the range 2 × 10-4 /0 0.1 , where 0 = 2.8 × 1014 g cm-3 is the equilibrium density of isospin-symmetric nuclear matter, corresponding mainly to the neutron star inner crust.