Sensitivity of Neutron Star Observables to Transition Density in Hybrid Equation-of-State Models

Abstract

We investigate how the transition density \(tr\) affects hybrid constructions of the neutron-star equation of state (EoS) in which a nucleonic description at low densities is matched to a model-agnostic high-density extension based on a speed-of-sound parametrization. Using four representative nucleonic models--Taylor expansion, \(n3\) expansion, Skyrme, and relativistic mean-field--built from identical nuclear matter parameters, we isolate the impact of the low-density EoS and the transition density on neutron star observables. We find that, within the present smooth-matching prescription, neutron star properties such as radii and tidal deformabilities retain significant sensitivity to the choice of low-density EoS for commonly adopted transition densities around \(tr ≈ 20\), even when the same high-density parametrization is employed. This residual dependence arises from differences in the matching conditions at \(tr\), which propagate into the high-density extension, so different low-density inputs lead to different effective high-density EoSs. These findings are robust across two distinct speed-of-sound parametrizations. Quantitatively, the model spread in radius and tidal deformability at 1.4\,M exceeds the current observational uncertainty by factors of 1.8 and 1.4 at tr ≈ 20, whereas these factors reduce to 1.05 and 0.4 at tr = 0. Lowering the transition density, therefore, systematically diminishes the spread among models and leads to more consistent predictions. Our results demonstrate that the widely used choice \(tr ≈ 20\) does not guarantee model independence in hybrid EoS constructions, and should be treated as an explicit source of systematic uncertainty when inferring dense matter properties from neutron star observations.