Gamma-ray burst precursors from tidally resonant neutron star oceans: potential implications for GRB 211211A

TL;DR

This paper proposes a model where neutron star ocean resonances triggered by tidal forces explain short gamma-ray burst precursors, allowing for system parameter constraints and distinguishing merger types without gravitational wave data.

Contribution

The paper introduces a novel model linking neutron star ocean resonances to gamma-ray burst precursors, enabling parameter estimation and merger type identification.

Findings

Precursor energy and oscillation data constrain binary parameters.

Model distinguishes NS-BH mergers from BNS mergers without GW detection.

Application to GRB 211211A supports a high-mass NS and extreme-mass ratio NS-BH merger.

Abstract

Precursor emission has been observed seconds to minutes before some short gamma-ray bursts. While the origins of these precursors remain unknown, one potential explanation relies on the resonance of neutron star pulsational modes with the tidal forces during the inspiral phase of a compact binary merger. In this paper, we present a model for short gamma-ray burst precursors which relies on tidally resonant neutron star oceans. In this scenario, the onset of tidal resonance in the crust-ocean interface mode corresponds to the ignition of the precursor flare, possibly through the interaction between the excited neutron star ocean and the surface magnetic fields. From just the precursor total energy, the time before the main event, and a detected quasi-periodic oscillation frequency, we may constrain the binary parameters and neutron star ocean properties as never before. Our model can immediately distinguish neutron star-black hole mergers from binary neutron star mergers without gravitational wave detection. We apply our model to GRB 211211A, the recently detected long duration short gamma-ray burst with a quasi-periodic precursor, and explore the parameters of this system within its context. The precursor of GRB 211211A is consistent with a tidally resonant neutron star ocean explanation that requires an extreme-mass ratio NSBH merger and a high mass neutron star. While difficult to reconcile with the gamma-ray burst main emission and associated kilonova, our results constrain the possible precursor generating mechanisms in this system. A systematic study of short gamma-ray burst precursors with the model presented here can test precursor origin and could probe the possible connection between gamma-ray bursts and neutron star-black hole mergers.