Modification of the universal relation between mass, radius and nonradial f-mode oscillation in proto-neutron stars

Abstract

Neutron stars are usually assumed to be cold; however, in certain dynamical astrophysical scenarios such as newly born neutron stars or binary star mergers, the temperature effects play a non-negligible role. We systematically derive the equation of state at finite-temperature within a relativistic mean-field hadronic model applicable to such proto-neutron stars. The equation of state so derived considerably affects the mass-radius curve, thereby affecting the nonradial quadruple f-mode oscillation frequencies. Temperature effectively makes the equation of state stiffer at relatively low and intermediate densities, thereby making the star less compact and flattening the mass-radius curve. The f-mode frequency for low and intermediate-mass neutron stars decreases with temperature and thus should be easier to detect. The universal relation (connecting f-mode frequency, mass, and radius) changes nonlinearly with temperature. The parameters defining the universal relation [ω M = a(T) (MR) + b(T)] becomes temperature dependent with the coefficients following a parabolic relation with temperature.