Equation of state of neutron star matter and its warm extension with an interacting hadron resonance gas

Abstract

We propose an interpolating equation of state that satisfies phenomenologically established boundary conditions in two extreme regimes at high temperature and low baryon density and at low temperature and high baryon density. We confirm that the hadron resonance gas model with the Carnahan-Starling excluded volume effect can reasonably fit the empirical equation of state at high density up to several times the normal nuclear density. We identify the onsets of strange particles and quantify the strangeness contents in dense matter. We finally discuss the finite temperature effects and estimate the thermal index th as a function of the baryon density, which should be a crucial input for the core-collapse supernova and the binary neutron star merger simulations.