Strong-field tidal distortions of rotating black holes: Formalism and results for circular, equatorial orbits

Author(s)

O'Sullivan, Stephen Gerard; Hughes, Scott A

Abstract

Tidal coupling between members of a compact binary system can have an interesting and important influence on that binary’s dynamical inspiral. Tidal coupling also distorts the binary’s members, changing them (at lowest order) from spheres to ellipsoids. At least in the limit of fluid bodies and Newtonian gravity, there are simple connections between the geometry of the distorted ellipsoid and the impact of tides on the orbit’s evolution. In this paper, we develop tools for investigating tidal distortions of rapidly rotating black holes using techniques that are good for strong-field, fast-motion binary orbits. We use black hole perturbation theory, so our results assume extreme mass ratios. We develop tools to compute the distortion to a black hole’s curvature for any spin parameter, and for tidal fields arising from any bound orbit, in the frequency domain. We also develop tools to visualize the horizon’s distortion for black hole spin a/M ≤ √3/2 (leaving the more complicated a/M > √3/2 case to a future analysis). We then study how a Kerr black hole’s event horizon is distorted by a small body in a circular, equatorial orbit. We find that the connection between the geometry of tidal distortion and the orbit’s evolution is not as simple as in the Newtonian limit.

Date issued

2014-12

URI

http://hdl.handle.net/1721.1/92426

Department

Massachusetts Institute of Technology. Department of Physics
MIT Kavli Institute for Astrophysics and Space Research

Journal

Physical Review D

Publisher

American Physical Society

Citation

O'Sullivan, Stephen, and Scott A. Hughes. "Strong-field tidal distortions of rotating black holes: Formalism and results for circular, equatorial orbits." Phys. Rev. D 90, 124039 (December 2014). © 2014 American Physical Society

Version: Final published version

ISSN

1550-7998

1550-2368