R-process beta-decay neutrino flux from binary neutron star mergers and collapsars

Abstract

This study investigates the antineutrinos production by β-decay of r-process nuclei in two astrophysical sites that are capable of producing gamma-ray bursts (GRBs): binary neutron star mergers (BNSMs) and collapsars, which are promising sites for heavy element nucleosynthesis. We employ a simplified method to compute the β-decay e energy spectrum and consider a number of different representative thermodynamic trajectories for r-process simulations, each with four sets of Ye distribution. The time evolution of the e spectrum is derived for both the dynamical ejecta and the disk wind for BNSMs and collapsar outflow, based on approximated mass outflow rates. Our results show that the e has an average energy of approximately 3 to 9~MeV, with a high energy tail of up to 20 MeV. The e flux evolution is primarily determined by the outflow duration, and can thus remain large for O(10)~s and O(100)~s for BNSMs and collapsars, respectively. For a single merger or collapsar at 40~Mpc, the e flux is O(10-100)~cm-2~s-1, indicating a possible detection horizon up to 0.1-1~Mpc for Hyper-Kamiokande. We also estimate their contributions to the diffuse e background, and find that both sources should only contribute subdominantly to the diffuse background when compared to that expected from core-collapse supernovae.