Multi-Messenger Constraints on Magnetic Fields in Merging Black Hole-Neutron Star Binaries

TL;DR

This paper uses gravitational wave and electromagnetic data from BHNS mergers to set upper limits on neutron star magnetic fields, constraining models of magnetospheric emission and neutron star evolution.

Contribution

It introduces a novel multi-messenger approach to constrain neutron star magnetic fields in black-hole-neutron-star mergers using GW and EM observations.

Findings

NS magnetic fields are constrained to be less than 10^{15} G.

Strongly magnetized magnetars are ruled out in these mergers.

The BH-battery fireball mechanism is inconsistent with observations.

Abstract

The LIGO-Virgo-KAGRA Collaboration recently detected gravitational waves (GWs) from the merger of black-hole-neutron-star (BHNS) binary systems GW200105 and GW200115. No coincident electromagnetic (EM) counterparts were detected. While the mass ratio and BH spin in both systems were not sufficient to tidally disrupt the NS outside of the BH event horizon, other, magnetospheric mechanisms for EM emission exist in this regime and depend sensitively on the NS magnetic field strength. Combining GW measurements with EM flux upper limits, we place upper limits on the NS surface magnetic field strength above which magnetospheric emission models would have generated an observable EM counterpart. We consider fireball models powered by the black-hole battery mechanism, where energy is output in gamma-rays over $\lesssim1$~second. Consistency with no detection by Fermi-GBM or INTEGRAL SPI-ACS constrains the NS surface magnetic field to $\lesssim10^{15}$~G. Hence, joint GW detection and EM upper limits rule out the theoretical possibility that the NSs in GW200105 and GW200115, and the putative NS in GW190814, retain $\gtrsim10^{15}$~G dipolar magnetic fields until merger. They also rule out formation scenarios where strongly magnetized magnetars quickly merge with BHs. We alternatively rule out operation of the BH-battery powered fireball mechanism in these systems. This is the first multi-messenger constraint on NS magnetic fields in BHNS systems and a novel approach to probe fields at this point in NS evolution. This demonstrates the constraining power that multi-messenger analyses of BHNS mergers have on BHNS formation scenarios, the magnetic-field evolution in NSs, and the physics of BHNS magnetospheric interactions.