Black hole - neutron star binaries with high spins and large mass asymmetries: II. Properties of dynamical simulations

TL;DR

This paper systematically explores black hole-neutron star binary mergers with high spins and large mass asymmetries, linking quasi-equilibrium predictions with detailed simulations to understand tidal disruption and merger outcomes.

Contribution

It introduces a novel method to relate quasi-equilibrium analyses with general-relativistic simulations, improving predictions of tidal disruption in BH-NS mergers.

Findings

Verified the reliability of QE predictions for plunge and disruption.

Identified conditions leading to tidal disruption based on binary parameters.

Developed a new diagnostic using Riemann tensor contraction to characterize disruption.

Abstract

Black hole (BH) - neutron star (NS) binary mergers are not only strong sources of gravitational waves (GWs), but they are also candidates for joint detections in the GW and electromagnetic (EM) spectra. However, the possible emergence of an EM signal from these binaries is determined by a complex combination of the equation of state (EOS), the BH spin, and the mass ratio. In this second paper in a series, we present a systematic exploration of the possible space of binary parameters in terms of the mass ratio and BH spin so as to construct a complete description of the dynamical processes accompanying a BHNS binary merger. This second work relies not only on the initial data presented in the companion paper I, but also on the predictions via quasi-equilibrium (QE) sequences on the outcome of the binary. In this way, and for the first time, we are able to relate the predictions of QE analyses with the results of accurate general-relativistic magnetohydrodynamic simulations. In addition to a careful investigation of the evolution of the BH mass and spin as a result of the merger, the total remnant rest-mass of the resulting accretion disk and its properties, and of the corresponding post-merger GW emission, special attention is paid to the conditions that lead to tidal disruption. Leveraging QE calculations, we are able to verify the reliability of stringent predictions about the occurrence or not of a plunge and to measure the `strength' of the tidal disruption when it takes place. Finally, using a novel contraction of the Riemann tensor in a tetrad comoving with the fluid introduced in paper I, we are able to point out the onset of the instability to tidal disruption. This new diagnostic can be employed not only to determine the occurrence of the disruption, but also to characterize it in terms of the binary parameters.