f and p mode oscillation of proto-neutron stars with systematic variation of the nucleon effective mass

Abstract

We develop equation of state (EoS) of proto-neutron stars (PNSs) at various stages of evolution by varying entropy per baryon S, using the Korea-IBS-Daegu-SKKU density functional model. With finite values for both temperature and density, we systematically investigate the influence of nucleon effective mass on EoS of PNSs, for different values of isoscalar effective mass μS*. For high entropy values, we aim to replicate conditions of failed core-collapse supernovae forming black holes. At each stage of evolution, structural and non-radial oscillation (fundamental f-mode and first pressure p1-mode) properties are computed under isentropic conditions by varying μS*. We focus on the effects of S and μS* on oscillation frequencies ff and fp1 adopting complete general relativistic formalism and Cowling approximation. Thermal effects reduce the values of ff and fp1 of PNSs compared to those of cold NSs, consequently detection of the former gets facilitated. For high-mass PNSs, this reduction is more pronounced for fp1 than ff. Moreover, lower values of μS* reduce ff and fp1 further. Universality of mass-scaled angular frequency (ωfM) with compactness (C) and tidal deformability () are obtained as non-linear fits that shift upwards (downwards) in ωfM-C (ωfM-) plane for increasing values of S. For fixed S, the universality is also retained for variation of μS*. S shows stronger correlation than μS* with structural and oscillation properties of (P)NSs. Strength of correlation of S is more prominent with fp1 than ff while the trend is opposite for μS*. These findings suggest that detection of oscillation frequencies by upcoming GW detectors, could potentially indicate the evolutionary stage of a star during its transition from supernova to cold NS.