Self-bound quark stars with a first-order two-to-three flavor phase transition

TL;DR

This paper models self-bound quark stars with a focus on a first-order phase transition from two-flavor to three-flavor quark matter, analyzing their properties and potential observational signatures.

Contribution

It introduces a flavor-dependent quark-mass density-dependent model with an excluded-volume correction to study self-bound quark stars and their phase transition characteristics.

Findings

Self-bound hybrid stars can develop a characteristic kink at the phase transition point.

The equation of state stiffness, controlled by the excluded-volume parameter, influences maximum mass and radius.

Model-insensitive trends in moment of inertia versus compactness are identified.

Abstract

We investigate self-bound quark stars in a flavor-dependent quark-mass density-dependent model with an excluded-volume correction. We chart the parameter space at zero pressure to identify self-bound regimes, including parametrizations in which self-bound two-flavor matter undergoes a genuine first-order $ud \to uds$ transition at finite pressure. We construct cold, $\beta$-equilibrated stellar sequences and compute the corresponding global properties (mass-radius relation, tidal deformability, and moment of inertia). For a wide region of the model parameter space, we find that the onset of a $uds$ core occurs before the maximum-mass configuration is reached, yielding self-bound hybrid stars that follow the typical strange-quark-star sequence morphology but develop a characteristic kink at $p_c=p_{\rm tr}$ along the stellar curves. The excluded-volume parameter $\kappa$ controls the stiffness of the equation of state and thus masses, radii, tidal deformabilities, and moments of inertia; intermediate repulsion typically reconciles $M_{\max}\!\gtrsim\!2\,M_\odot$ with current astrophysical constraints. We further identify two equation-of-state-insensitive trends: dimensionless moment of inertia versus compactness and gravitational versus baryonic compactness. These results provide model-guided priors and tools for discriminating between hadronic and self-bound equations of state with multimessenger data.