Late-time accretion in neutron star mergers: implications for short gamma-ray bursts and kilonovae

TL;DR

This paper investigates the long-term evolution of accretion disks after neutron star mergers, linking radioactive heating to jet shutdown and kilonova emission, and predicts observable electromagnetic signatures.

Contribution

It introduces a model connecting radioactive heating to disk evaporation, explaining gamma-ray burst features and predicting orphan extended emissions and late-time spectral lines.

Findings

Radioactive heating causes disk evaporation at ~100 s post-merger.

Jet power correlates with disk mass, explaining flux evolution.

Late-time kilonova emission includes narrow spectral lines from atomic species.

Abstract

We study the long-term (t >> 10 s) evolution of the accretion disk after a neutron star(NS)-NS or NS-black hole merger, taking into account the radioactive heating by r-process nuclei formed in the first few seconds. We find that the cumulative heating eventually exceeds the disk's binding energy at t ~ 10^2 s (\alpha/0.1)^{-1.8} (M/2.6 Msun)^{1.8} after the merger, where \alpha is the Shakura-Sunyaev viscosity parameter and M is the mass of the remnant object. This causes the disk to evaporate rapidly and the jet power to shut off. We propose that this is the cause of the steep flux decline at the end of the extended emission (EE) or X-ray plateau seen in many short gamma-ray bursts (GRBs). The shallow flux evolution before the steep decline is consistent with a plausible scenario where the jet power scales linearly with the disk mass. We suggest that the jets from NS mergers have two components -- a short-duration narrow one corresponding to the prompt gamma-ray emission and a long-lasting wide component producing the EE. This leads to a prediction that "orphan EE" (without the prompt gamma-rays) may be a promising electromagnetic counterpart for NS mergers observable by future wide-field X-ray surveys. The long-lived disk produces a slow ejecta component that can efficiently thermalize the energy carried by beta-decay electrons up to t ~ 100 d and contributes 10% of the kilonova's bolometric luminosity at these late epochs. We predict that future ground-based and JWST near-IR spectroscopy of nearby (< 100 Mpc) NS mergers will detect narrow (~0.01c) line features a few weeks after the merger, which provides a powerful probe of the atomic species formed in these events.