Mass Ejection from the Remnant of a Binary Neutron Star Merger: Viscous-Radiation Hydrodynamics Study

Abstract

We perform long-term general relativistic neutrino radiation hydrodynamics simulations (in axisymmetry) for a massive neutron star (MNS) surrounded by a torus, which is a canonical remnant formed after the binary neutron star merger. We take into account the effects of viscosity, which is likely to arise in the merger remnant due to magnetohydrodynamical turbulence. As the initial condition, we employ the azimuthally averaged data of the MNS-torus system derived in a three-dimensional, numerical-relativity simulation for the binary neutron star merger. The viscous effect plays key roles for the remnant evolution and mass ejection from it in two phases of the evolution. In the first t10 ms, a differential rotation state of the MNS is changed to a rigidly rotating state, and as a result, a sound wave, which subsequently becomes a shock wave, is formed in the vicinity of the MNS due to the variation of the quasi-equilibrium state of the MNS. The shock wave induces significant mass ejection of mass (0.5-2.0)× 10-2M for the alpha viscosity parameter of 0.01-0.04. For the longer-term evolution with 0.1-10 s, a significant fraction of the torus material is ejected. The ejecta mass is likely to be of order 10-2M, so that the total mass of the viscosity-driven ejecta could dominate that of the dynamical ejecta of mass 10-2M. The electron fraction, Ye, of the ejecta is always high enough (Ye0.25) that this post-merger ejecta is lanthanide-poor; hence, the opacity of the ejecta is likely to be 10-100 times lower than that of the dynamical ejecta. This indicates that the electromagnetic signal from the ejecta would be rapidly evolving, bright, and blue if it is observed from a small viewing angle ( 45) for which the effect of the dynamical ejecta is minor.