Correlations between nuclear incompressibility, liquid-gas critical point, and quarkyonic transition

Abstract

We systematically probe different parametrizations of the attractive nuclear force based on real gas models to construct the nuclear matter equation of state. In each of the cases, the repulsion between nucleons is treated in the framework of excluded volume, and interaction parameters are fitted to the empirical properties of the nuclear ground state. We calculate the critical temperature Tc and critical particle number density nc, and find that they are strongly correlated. Both are also correlated with the incompressibility K0 in the nuclear ground state. We also include a quarkyonic matter phase in the quasiparticle description and investigate the relationships among K0, transition density to the quarkyonic phase, ntr, and corresponding peak in the speed of sound, vs, max2. At each density, the quark fraction is found by minimizing the energy density. We find that both ntr and vs, max2 are negatively correlated with K0, nc, and Tc.