Charged Compact Binary Coalescence Signal and Electromagnetic Counterpart of Plunging Black Hole–Neutron Star Mergers
Document Type
Article
Publication Date
3-8-2019
Publication Title
The Astrophysical Journal Letters
Edition
2
Issue
873
First page number:
1
Last page number:
6
Abstract
If at least one of the members of a compact binary coalescence is charged, the inspiral of the two members would generate a Poynting flux with an increasing power, giving rise to a brief electromagnetic counterpart temporally associated with the chirp signal of the merger (with possibly a small temporal offset), which we term as the charged compact binary coalescence (cCBC) signal. We develop a general theory of cCBC for any mass and amount of charge for each member. Neutron stars (NSs), as spinning magnets, are guaranteed to be charged, so the cCBC signal should accompany all NS mergers. The cCBC signal is clean in a black hole (BH)–NS merger with a small mass ratio (q mm º < 2 1 0.2), in which the NS plunges into the BH as a whole, and its luminosity/energy can reach that of a fast radio burst if the NS is Crab-like. The strength of the cCBC signal in Extreme Mass Ratio Inspiral Systems is also estimated.
Keywords
Gravitational Waves; Radiation Mechanisms; Stars; Black Holes; Neutron
Disciplines
Astrophysics and Astronomy | Physical Sciences and Mathematics
Language
English
Repository Citation
Zhang, B.
(2019).
Charged Compact Binary Coalescence Signal and Electromagnetic Counterpart of Plunging Black Hole–Neutron Star Mergers.
The Astrophysical Journal Letters(873),
1-6.