Litcius/Paper detail

Rapidly Spinning Compact Stars with Deconfinement Phase Transition

Tuna Demircik, Christian Ecker, Matti Järvinen

2021The Astrophysical Journal Letters45 citationsDOIOpen Access PDF

Abstract

Abstract We study rapidly spinning compact stars with equations of state featuring a first-order phase transition between strongly coupled nuclear matter and deconfined quark matter by employing the gauge/gravity duality. We consider a family of models that allow purely hadronic uniformly rotating stars with masses up to approximately 2.9 M ⊙ , and are therefore compatible with the interpretation that the secondary component ( ) in GW190814 is a neutron star. These stars have central densities that are several times the nuclear saturation density, so that strong coupling and non-perturbative effects become crucial. We construct models where the maximal mass of static (rotating) stars M TOV ( M max ) is either determined by the secular instability or a phase-transition induced collapse. We find the largest values for M max / M TOV in cases where the phase transition determines M max , which shifts our fit result to , a value slightly above the Breu–Rezzolla bound inferred from models without phase transition.

Topics & Concepts

PhysicsStarsNeutron starDeconfinementStrange matterNuclear matterPhase transitionAstrophysicsCompact starEquation of statePhase (matter)InstabilityHadronQuark starSolar massCoupling (piping)Particle physicsQuarkInterpretation (philosophy)SpinningSaturation (graph theory)Nuclear physicsQuantum chromodynamicsComponent (thermodynamics)Pulsars and Gravitational Waves ResearchHigh-Energy Particle Collisions ResearchQuantum Chromodynamics and Particle Interactions