Nuclear matter properties and neutron star structures from an extended linear sigma model
Abstract
The properties of nuclear matter and the structures of neutron stars are analyzed with a baryonic extended linear sigma model in mean-field approximation, where the masses of baryons and mesons are generated via the spontaneous chiral symmetry breaking. The couplings between the iso-scalar scalar meson and nucleons, gσ NN, the iso-vector scalar meson and nucleons, ga0 NN, and the four-vector meson couplings play an important role in the properties of nuclear matter and neutron stars. The introduction of the δ meson leads to a plateau structure of the symmetry energy, E sym(n), at intermediate densities, which is crucial to the consistency of neutron skin thickness of 208Pb and the tidal deformability of a canonical neutron star. The explicit chiral symmetry breaking term is then introduced with a constant background field, , which can be related to the current quark mass and thus the pion-nucleon sigma term, σπ N. A negative σπ N leads to a stiffer EOS of neutron star matter and thus a larger maximum mass of neutron stars, but the value of σπ N needed to satisfy the astrophysical constraints is negative, not positive as the vacuum value. The study may provide insights into the running behaviors of the parameters in the low-energy effective model to give the density-dependent description for the EOS of neutron star matter.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.