Perturbation Theory of Nuclear Matter with a Microscopic Effective Interaction

Abstract

An updated and improved version of the effective interaction based on the Argonne Urbana nuclear Hamiltonian derived using the formalism of Correlated Basis Functions (CBF) and the cluster expansion technique is employed to obtain a number of properties of cold nuclear matter at arbitrary neutron excess within the formalism of many-body perturbation theory. The numerical results including the ground-state energy per nucleon, the symmetry energy, the pressure, the compressibility, and the single-particle spectrum are discussed in the context of the available empirical information, obtained from measured nuclear properties and heavy-ion collisions.