Effects of Symmetry Energy on the Equation of State for Hybrid Neutron Stars

Abstract

In this paper, the implications of the symmetry energy on the hadron and quark phase transitions in the compact star, including the properties of the possible configurations of the quark-hadron hybrid stars, are investigated in the frameworks of the energy-density functional (EDF) models and the flavor SU(2) Nambu--Jona-Lasinio (NJL) model with the help of the Schwinger's covariant proper-time regularization (PTR) scheme. In this theoretical setup, the equations of states (EoSs) of hadronic matter for various values of symmetry energies obtained from the EDF models are employed to describe the hadronic matter, and the flavor SU(2) NJL model with various repulsive-vector interaction strengths are used to describe the quark matter. We then observe the obtained EoS in the mass-radius properties of the hybrid star configurations for various vector interactions and nuclear symmetry energies by solving the Tolman-Oppenheimer-Volkoff equation. We obtain that the critical density at which the phase transition occurs varies over the density (3.6--6.7)0 depending on the symmetry energy and the strength of the vector coupling Gv. The maximum mass of the neutron star (NS) is susceptible to Gv. When there is no repulsive force, the NS maximum mass is only about 1.5M, but it becomes larger than 2.0M when the vector coupling constant is about half of the attractive scalar coupling constant. Surprisingly, the presence of the quark matter does not affect the canonical mass of NS (1.4M), so observing the canonical mass of NSs can provide unique constraints to the EoS of hadronic matter at high densities.