Extended Skyrme interactions for nuclear matter, finite nuclei and neutron stars

TL;DR

This paper develops extended Skyrme interactions fitted to nuclear data, which accurately describe nuclear properties, eliminate instabilities, and support massive neutron stars, offering improved models for nuclear matter and astrophysics.

Contribution

It introduces three new extended Skyrme parameter sets that incorporate additional momentum and density dependencies, enhancing the modeling of nuclear matter and neutron stars.

Findings

Successfully fit finite nuclei properties and nuclear matter constraints

Eliminate unphysical instabilities up to high densities

Support neutron stars with masses over two solar masses

Abstract

Recent progress in theory, experiment and observation challenges the mean field models using the conventional Skyrme interaction, suggesting that the extension of the conventional Skyrme interaction is necessary. In this work, by fitting the experimental data of a number of finite nuclei together with a few additional constraints on nuclear matter using the simulated annealing method, we construct three Skyrme interaction parameter sets, namely, eMSL07, eMSL08 and eMSL09, based on an extended Skyrme interaction which includes additional momentum and density dependent two-body forces to effectively simulate the momentum dependence of the three-body force. The three new interactions can reasonably describe the ground-state properties and the isoscalar giant monopole resonance energies of various spherical nuclei used in the fit as well as the ground-state properties of many other spherical nuclei, nicely conform to the current knowledge on the equation of state of asymmetric nuclear matter, eliminate the notorious unphysical instabilities of symmetric nuclear matter and pure neutron matter up to a very high density of $1.2$ fm$^{-3}$, and simultaneously support heavier neutron stars with mass larger than two times solar mass. One important difference of the three new interactions is about the prediction of the symmetry energy at supra-saturation densities, and these new interactions are thus potentially useful for the determination of the largely uncertain high-density symmetry energy in future. In addition, a comparison is made for the predictions of nuclear matter, finite nuclei and neutron stars with the three new interactions versus those with three typical interactions BSk22, BSk24 and BSk26 from Brussels group.