Merger of black hole-neutron star binaries in full general relativity

Abstract

We present our latest results for simulation for merger of black hole (BH)-neutron star (NS) binaries in full general relativity which is performed preparing a quasicircular state as initial condition. The BH is modeled by a moving puncture with no spin and the NS by the -law equation of state with =2 and corotating velocity field as a first step. The mass of the BH is chosen to be ≈ 3.2 M or 4.0M, and the rest-mass of the NS ≈ 1.4 M with relatively large radius of the NS ≈ 13--14 km. The NS is tidally disrupted near the innermost stable orbit but 80--90% of the material is swallowed into the BH and resulting disk mass is not very large as 0.3M even for small BH mass 3.2M. The result indicates that the system of a BH and a massive disk of M is not formed from nonspinning BH-NS binaries irrespective of BH mass, although a disk of mass 0.1M is a possible outcome for this relatively small BH mass range as 3--4M. Our results indicate that the merger of low-mass BH and NS may form a central engine of short-gamma-ray bursts.

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