Rapidly Spinning Compact Stars with Deconfinement Phase Transition

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, which 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 (2.59+0.08-0.09\, M) in GW190814 is a neutron star. These stars have central densities 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 MTOV (Mmax) is either determined by the secular instability or a phase transition induced collapse. We find largest values for Mmax/MTOV in cases where the phase transition determines Mmax, which shifts our fit result to Mmax/MTOV = 1.227+0.031-0.016, a value slightly above the Breu-Rezzolla bound 1.203+0.022-0.022 inferred from models without phase transition.