What if the neutron star maximum mass is beyond $\sim2.3 M_{\odot}$?

TL;DR

This paper explores the possibility that neutron stars can have maximum masses exceeding 2.3 solar masses by analyzing the stiffness and transition density of their equations of state using a polytropic model, considering both normal and strange stars.

Contribution

It introduces a parametric polytropic model to investigate conditions allowing neutron stars to surpass 2.3 solar masses, providing constraints on EOS parameters for different star types.

Findings

Minimum transition density for normal stars: ~0.50 times nuclear saturation density.

Polytropic exponent range for strange stars: >1.40 if surface density > nuclear saturation density.

Estimated neutron star radius range: 9.8-13.8 km for normal stars, 10.5-12.5 km for strange stars.

Abstract

By assuming the formation of a black hole soon after the merger event of GW170817, Shibata et al. updated the constraints on the maximum mass ($M_\textrm{max}$) of a stable neutron star within $\lesssim$ 2.3 $M_{\odot}$, but there is no solid evidence to rule out $M_\textrm{max}>2.3~M_{\odot}$ from the point of both microphysical and astrophysical views. In order to explain massive pulsars, it is naturally expected that the equation of state (EOS) would become stiffer beyond a specific density. In this paper, we consider the possibility of EOSs with $M_\textrm{max}>2.3~M_{\odot}$, investigating the stiffness and the transition density in a polytropic model. Two kinds of neutron stars are considered, i.e., normal neutron stars (the density vanishes on gravity-bound surface) and strange stars (a sharp density discontinuity on self-bound surface). The polytropic model has only two parameter inputs in both cases: ($\rho_{\rm t}$, $\gamma$) for gravity-bound objects, while ($\rho_{\rm s}$, $\gamma$) for self-bound ones, with $\rho_{\rm t}$ the transition density, $\rho_{\rm s}$ the surface density and $\gamma$ the polytropic exponent. In the matter of $M_\textrm{max}>2.3~M_{\odot}$, it is found that the smallest $\rho_{\rm t}$ and $\gamma$ should be $\sim 0.50~\rho_0$ and $\sim 2.65$ for normal neutron stars, respectively, whereas for strange star, we have $\gamma > 1.40$ if $\rho_{\rm s} > 1.0~\rho_0$ and $\rho_{\rm s} < 1.58~\rho_0$ if $\gamma <2.0$ ($\rho_0$ is the nuclear saturation density). These parametric results could guide further research of the real EOS with any foundation of microphysics if a pulsar mass higher than $2.3~M_{\odot}$ is measured in the future. We also derive rough results of common neutron star radius range, which is $9.8~\rm{km} < R_{1.4} < 13.8~\rm{km}$ for normal neutron stars and $10.5~\rm{km} < R_{1.4} < 12.5~\rm{km}$ for strange stars.