Hadron-quark Pasta Phase in Massive Neutron Stars

TL;DR

This paper investigates the hadron-quark pasta phase in massive neutron stars, extending the energy minimization method to include surface and Coulomb effects, and explores its impact on the star's equation of state and maximum mass.

Contribution

It introduces an extended EM method for modeling the hadron-quark pasta phase, incorporating electric charge effects and analyzing its influence on neutron star properties.

Findings

Pasta phases can exist in massive neutron star cores.

Vector interactions stiffen the EOS at high densities.

Results are compatible with current astrophysical observations.

Abstract

The structured hadron-quark mixed phase, known as the pasta phase, is expected to appear in the core of massive neutron stars. Motivated by the recent advances in astrophysical observations, we explore the possibility of the appearance of quarks inside neutron stars and check its compatibility with current constraints. We investigate the properties of the hadron-quark pasta phases and their influences on the equation of state (EOS) for neutron stars. In this work, we extend the energy minimization (EM) method to describe the hadron-quark pasta phase, where the surface and Coulomb contributions are included in the minimization procedure. By allowing different electron densities in the hadronic and quark matter phases, the total electron chemical potential with the electric potential remains constant, and local ? equilibrium is achieved inside the Wigner-Seitz cell. The mixed phase described in the EM method shows the features lying between the Gibbs and Maxwell constructions, which is helpful for understanding the transition from the Gibbs construction (GC) to the Maxwell construction (MC) with increasing surface tension. We employ the relativistic mean-field model to describe the hadronic matter, while the quark matter is described by the MIT bag model with vector interactions. It is found that the vector interactions among quarks can significantly stiffen the EOS at high densities and help enhance the maximum mass of neutron stars. Other parameters like the bag constant can also affect the deconfinement phase transition in neutron stars. Our results show that hadron-quark pasta phases may appear in the core of massive neutron stars that can be compatible with current observational constraints.