Effective repulsion in dense quark matter from non-perturbative gluon exchange

Abstract

A moderately strong vector repulsion between quarks in dense quark matter is needed to explain how a quark core can support neutron stars heavier than two solar masses. We study this repulsion, parametrized by a four-fermion interaction with coupling gV, in terms of non-perturbative gluon exchange in QCD in the Landau gauge. Matching the energy of quark matter, gV nq2 (where nq is the number density of quarks) with the quark exchange energy calculated in QCD with a gluon propagator parametrized by a finite gluon mass mg and a frozen coupling alphas, at moderate quark densities, we find that gluon masses mg in the range 200 - 600 MeV and alphas = 2 - 4 lead to a gV consistent with neutron star phenomenology. Estimating the effects of quark masses and a color-flavor-locked (CFL) pairing gap, we find that gV can be well approximated by a flavor-symmetric, decreasing function of density. We briefly discuss similar matchings for the isovector repulsion and for the pairing attraction.