Prompt Black Hole Formation in Binary Neutron Star Mergers

TL;DR

This study analyzes the prompt-collapse behavior in binary neutron star mergers through extensive simulations, revealing a universal relation for critical mass and implications for electromagnetic signals.

Contribution

It introduces a quasi-universal relation for the critical mass and a gauge-independent diagnostic for collapse thresholds in BNS mergers.

Findings

Critical mass increases with EOS stiffness.

Universal relation: M_crit / M_TOV ≈ 1.41 ± 0.06.

Collapse threshold impacts electromagnetic counterpart emission.

Abstract

We carry out an in-depth analysis of the prompt-collapse behaviour of binary neutron star (BNS) mergers. To this end, we perform more than $80$ general relativistic BNS merger simulations using a family of realistic Equations of State (EOS) with different stiffness, which feature a first order deconfinement phase transition between hadronic and quark matter. From these simulations we infer the critical binary mass $M_{\rm crit}$ that separates the prompt from the non-prompt collapse regime. We show that the critical mass increases with the stiffness of the EOS and obeys a tight quasi-universal relation, $M_{\rm crit}/M_{\rm TOV}\approx 1.41\pm 0.06$, which links it to the maximum mass $M_{\rm TOV}$ of static neutron stars, and therefore provides a straightforward estimate for the total binary mass beyond which prompt collapse becomes inevitable. In addition, we introduce a novel gauge independent definition for a one-parameter family of threshold masses in terms of curvature invariants of the Riemann tensor which characterizes the development toward a more rapid collapse with increasing binary mass. Using these diagnostics, we find that the amount of matter remaining outside the black hole sharply drops in supercritical mass mergers compared to subcritical ones and is further reduced in mergers where the black hole collapse is induced by the formation of a quark matter core. This implies that $M_{\rm crit}$, particularly for merger remnants featuring quark matter cores, imposes a strict upper limit on the emission of any detectable electromagnetic counterpart in BNS mergers.