Jet launching from binary black hole-neutron star mergers: Dependence on black hole spin, binary mass ratio and magnetic field orientation

University of Illinois at Urbana-Champaign

Abstract

Black hole-neutron star (BHNS) mergers are one of the most promising targets for multimessenger astronomy. Using general relativistic magnetohydrodynamic simulations of BHNS undergoing merger we previously showed that a magnetically-driven jet can be launched by the disk + spinning black hole remnant $if$ the neutron star is endowed with a dipole magnetic field extending from the interior into the exterior as in a radio pulsar. These self-consistent studies considered a BHNS system with mass ratio $q = 3 : 1$, black hole spin $a/M_{\rm BH} = 0.75$ aligned with the total orbital angular momentum, and a neutron star that is irrotational, threaded by an aligned magnetic field, and modeled by an $\Gamma-$law equation of state with $\Gamma = 2$. Here, as a crucial step in establishing BHNS systems as viable progenitors of central engines that power short $\Gamma-$ray bursts (sGRBs) and thereby solidify their role as multimessenger sources, we survey different BHNS configurations that differ in the spin of the BH companion $(a/M_{\rm BH} = -0.5, 0, 0.5, 0.75)$, in the mass ratio $(q = 3 : 1$ and $q = 5 : 1)$, and in the orientation of the magnetic field (aligned and tilted by $90^{\circ}$ with respect to the orbital angular momentum). We find that by $\Delta t \sim 3500M - 4000M \sim 88(M_{\rm NS}/1.4M_{\odot}){\rm ms} - 100(M_{\rm NS}/1.4M_{\odot}){\rm ms}$ after the peak gravitational wave signal a magnetically-driven jet is launched in the cases where the initial spin of the BH companion is $a/M_{\rm BH} = 0.5$ or $0.75$. The lifetime of the jets $[\Delta t \sim 0.5(M_{\rm NS}/1.4M_{\odot}){\rm s} - 0.7(M_{\rm NS}/1.4M_{\odot}){\rm s}]$ and their outgoing Poynting luminosities $[L_{jet} \sim 10^{51 \pm 1}{\rm erg/s}]$ are consistent with typical sGRBs, as well as with the Blandford-Znajek mechanism for launching jets and their associated Poynting luminosities. By the time we terminate our simulations, we do not observe either an outflow or a large-scale magnetic field collimation in the other configurations we simulate. These results suggest that future multimessenger detections from BHNSs are more likely produced by binaries with highly spinning BH companions and small tilt-angle magnetic fields.

arXiv:1810.08618

Rendering

These visualizations were created using VisIt software on the Blue Waters supercomputer at NCSA.


University of Illinois at Urbana-Champaign

Introduction
Initial Configuration
Case A: Mass Ratio 3:1, Spin 0.75
Case B: Mass Ratio 3:1, Spin 0.5
Case C: Mass Ratio 3:1, Spin 0
Case D: Mass Ratio 3:1, Spin 0.75, Tilted Magnetic Fields
Gravitational Waveforms: Case A