General relativistic simulations of collapsing binary neutron star mergers with Monte-Carlo neutrino transport

TL;DR

This paper presents advanced general relativistic simulations of binary neutron star mergers incorporating Monte-Carlo neutrino transport, revealing insights into outflow properties, remnant composition, and the effects of viscosity and r-process heating.

Contribution

It introduces a novel simulation approach with Monte-Carlo neutrino transport for massive neutron star mergers, comparing results with existing codes and analyzing outflow and remnant characteristics.

Findings

Agreement with previous simulations on black hole and disk properties

Viscosity has a minor impact on outflow electron fraction

R-process heating significantly influences outflow properties

Abstract

Recent gravitational wave observations of neutron star-neutron star and neutron star-black hole binaries appear to indicate that massive neutron stars may not be too uncommon in merging systems. In this manuscript, we present a first set of evolution of massive neutron star binaries using Monte-Carlo radiation transport for the evolution of neutrinos. We study a range of systems, from nearly symmetric binaries that collapse to a black hole before forming a disk or ejecting material, to more asymmetric binaries in which tidal disruption of the lower mass star leads to the production of more interesting post-merger remnants. For the latter type of systems, we additionally study the impact of viscosity on the properties of the outflows, and compare our results to two recent simulations of identical binaries performed with the WhiskyTHC code. We find agreement on the black hole properties, disk mass, and mass and velocity of the outflows within expected numerical uncertainties, and some minor but noticeable differences in the evolution of the electron fraction when using a subgrid viscosity model, with viscosity playing a more minor role in our simulations. The method used to account for r-process heating in the determination of the outflow properties appears to have a larger impact on our result than those differences between numerical codes. We also use the simulation with the most ejected material to verify that our newly implemented Lagrangian tracers provide a reasonable sampling of the matter outflows as they leave the computational grid. We note that, given the lack of production of hot outflows in these mergers, the main role of neutrinos in these systems is to set the composition of the post-merger remnant. One of the main potential use of our simulations is thus as improved initial conditions for longer evolutions of such remnants.