Fast spinning strange stars: possible ways to constrain interacting quark matter parameters

TL;DR

This study constructs general relativistic models of rapidly spinning strange stars using interacting quark matter equations of state, exploring how parameters B_eff and a_4 influence observable properties to help constrain fundamental quark matter parameters.

Contribution

First to model fully relativistic sequences of fast-spinning strange stars with these specific EoS parameters, analyzing their effects on measurable star properties.

Findings

Lower B_eff supports higher stellar mass.

Radius and moment of inertia increase as B_eff decreases.

a_4 significantly impacts stellar mass and binding energy.

Abstract

For a set of equation of state (EoS) models involving interacting strange quark matter, characterized by an effective bag constant (B_eff) and a perturbative QCD corrections term (a_4), we construct fully general relativistic equilibrium sequences of rapidly spinning strange stars for the first time. Computation of such sequences is important to study millisecond pulsars and other fast spinning compact stars. Our EoS models can support a gravitational mass (M_G) and a spin frequency at least up to approximately 3.0 solar mass and approximately 1250 Hz respectively, and hence are fully consistent with measured M_G and spin frequency values. This paper reports the effects of B_eff and a_4 on measurable compact star properties, which could be useful to find possible ways to constrain these fundamental quark matter parameters, within the ambit of our EoS models. We confirm that a lower B_eff allows a higher mass. Besides, for known M_G and spin frequency, measurable parameters, such as stellar radius, radius-to-mass ratio and moment of inertia, increase with the decrease of B_eff. Our calculations also show that a_4 significantly affects the stellar rest mass and the total stellar binding energy. As a result, a_4 can have signatures in evolutions of both accreting and non-accreting compact stars, and the observed distribution of stellar mass and spin and other source parameters. Finally, we compute the parameter values of two important pulsars, PSR J1614-2230 and PSR J1748-2446ad, which may have implications to probe their evolutionary histories, and for constraining EoS models.