High-Density behavior of symmetry energy and speed of sound in the dense matter within an effective chiral model

Abstract

With an effective chiral model, we investigate how the mesonic cross couplings σ- and ω- affect the density content of the symmetry energy and its higher-order slope parameters. Earlier mentioned cross-couplings are crucial to controlling the density content of symmetry energy. For this purpose, we did a case study for different values of the symmetry energy J1, defined at density 0.1 fm-3 in the range (23.4 - 25.2) for a fixed value of the slope of the symmetry energy L0 = 60 MeV at saturation density and investigate its effect on the higher-order coefficients and their influence on the underlying equation of state. We found that the model with J1= 24.6 MeV is more favorable with the pure neutron matter (PNM) constraints obtained from calculations. In addition, we show that all of our models predict a monotonically increasing speed of sound up to four times the saturation density. The speed of sound decreases/saturates above that point and approaches the conformal limit approximately 1/3~c at the center of the maximum mass star.