# Electromagnetic signals following stellar-mass black hole mergers

**Authors:** S. E. de Mink (1), A. King (2) ((1) U. of Amsterdam, (2) U. of, Leicester)

arXiv: 1703.07794 · 2017-04-19

## TL;DR

This paper suggests that electromagnetic signals could follow stellar-mass black hole mergers if residual gas is present, offering a new way to observe and understand these cosmic events.

## Contribution

It introduces the possibility of detectable EM counterparts from black hole mergers due to residual gas, challenging previous assumptions of no EM emission.

## Key findings

- EM signals may be detectable hours after GW events for certain disk masses
- Optical depth effects influence the observable EM emission
- Existing unidentified sources might be black hole merger counterparts

## Abstract

It is often assumed that gravitational wave (GW) events resulting from the merger of stellar-mass black holes are unlikely to produce electromagnetic (EM) counterparts. We point out that the progenitor binary has probably shed a mass $\gtrsim 10\,{\rm M}_{\odot}$ during its prior evolution. If a tiny fraction of this gas is retained until the merger, the recoil and sudden mass loss of the merged black hole shocks and heats it within hours of the GW event. Whether resulting EM emission is detectable is uncertain. The optical depth through the disk is likely to be high enough that the prompt emission consists only of photons from its optically thin skin, while the majority may take years to emerge. However, if some mechanism can release more photons in a time comparable to the few-hour energy production time, the peak luminosity of the EM signal could be detectable. For a disk retaining only $\sim 10^{-3}$ of the mass shed in the earlier binary evolution, medium-energy X-rays to infrared emission would be observable hours after the GW event for source distances $\sim 500\,\rm{Mpc}$. Events like this may already have been observed, but ascribed to unidentified active galactic nuclei. Improved sky-localization should eventually allow identification based on spatial coincidence. A detection would provide unique constraints on formation scenarios and potentially offer tests of strong-field general relativity. Accordingly we argue that the high scientific payoff of an EM detection fully justifies search campaigns.

## Full text

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## Figures

1 figure with captions in the complete paper: https://tomesphere.com/paper/1703.07794/full.md

## References

80 references — full list in the complete paper: https://tomesphere.com/paper/1703.07794/full.md

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Source: https://tomesphere.com/paper/1703.07794