Radial oscillations of pulsating neutron stars: The UCIa equation-of-state case

Abstract

Radial oscillations provide a clean dynamical test of the high-density stiffness of neutron-star equations of state. We study spherically symmetric pulsations of nonrotating relativistic stars built from cold, charge-neutral, β-equilibrated pure nucleonic matter described within relativistic mean-field theory. As a baseline we adopt the UCIa parameter set [Astron. Astro-phys. 689, A242 (2024)], and we implement high-density stiffening via the σ-cut scheme by adding a regulator potential U cut(σ) [Phys. Rev. C 92, no.5, 052801 (2015), Phys. Rev. C 106, no.5, 055806 (2022)]. For representative choices fs=0 (no cutoff) and fs=0.58 (stiffened), we solve the Tolman-Oppenheimer-Volkoff and tidal perturbation equations to obtain equilibrium sequences, mass-radius relations, and tidal deformabilities. We then derive and solve the linear general-relativistic radial pulsation equations to compute the eigenfrequencies and eigenfunctions of the fundamental and overtone modes. The σ-cutoff suppresses the growth of the scalar field at supranuclear density, increases the pressure, and shifts the maximum mass, radii, and 1.4 accordingly, while systematically raising the radial-mode frequencies at fixed mass. Using the sign change of ω02 as a stability criterion, we identify stiffened models that remain radially stable up to the observed 2M mass scale and are consistent with current multimessenger constraints, demonstrating how radial spectra complement static EoS tests.