# Imprints of r-process heating on fall-back accretion: distinguishing   black hole-neutron star from double neutron star mergers

**Authors:** Dhruv Desai, Brian D. Metzger, Francois Foucart

arXiv: 1812.04641 · 2019-03-20

## TL;DR

This paper investigates how r-process nucleosynthesis heating influences fall-back accretion in compact binary mergers, revealing distinct accretion signatures that can differentiate black hole-neutron star from double neutron star mergers, with implications for gravitational wave detection.

## Contribution

It demonstrates that nuclear heating effects can produce unique fall-back accretion patterns, providing a new method to distinguish merger types and interpret extended gamma-ray burst emissions.

## Key findings

- r-process heating causes fall-back rate cut-offs or gaps depending on black hole mass
- Black hole-neutron star mergers can be identified by specific fall-back accretion signatures
- The model suggests comparable or higher detection rates for NS-BH mergers by LIGO

## Abstract

Mergers of compact binaries containing two neutron stars (NS-NS), or a neutron star and a stellar-mass black hole (NS-BH), are likely progenitors of short-duration gamma ray bursts (SGRBs). A fraction >20% of SGRBs are followed by temporally-extended (>~ minute-long), variable X-ray emission, attributed to ongoing activity of the central engine. One source of late-time engine activity is fall-back accretion of bound tidal ejecta; however, observed extended emission light curves do not track the naively-anticipated, uninterrupted ~t^{-5/3} power-law decay, instead showing a lull or gap in emission typically lasting tens of seconds after the burst. Here, we re-examine the impact of heating due to rapid neutron capture (r-process) nucleosynthesis on rate of the fall-back accretion, using ejecta properties obtained from numerical relativity simulations of NS-BH mergers in a toy model for the dynamical influence of nuclear heating. Depending on the mass of the remnant black hole, r-process heating can imprint a variety of fall-back curve shapes, ranging from temporal lulls of up to tens of seconds to complete late-time cut-off in the fall-back rate. This behavior is robust to realistic variations in the nuclear heating experienced by different parts of the ejecta. Central black holes with masses <~ 3 Msun typically experience absolute cut-offs in the fall-back rate, while more massive >6-8 Msun black holes instead show temporal gaps. We thus propose that SGRBs with extended emission arise from NS-BH, rather than NS-NS, mergers. Our model implies a NS-BH merger detection rate by LIGO which, in steady-state, is comparable to or greater than that of NS-NS mergers.

## Full text

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## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1812.04641/full.md

## References

68 references — full list in the complete paper: https://tomesphere.com/paper/1812.04641/full.md

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Source: https://tomesphere.com/paper/1812.04641