Perturbative approach to an orbital evolution around a supermassive black hole
Top Cited Papers
- 24 April 2003
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review D
- Vol. 67 (8) , 084027
- https://doi.org/10.1103/physrevd.67.084027
Abstract
A charge-free, point particle of infinitesimal mass orbiting a Kerr black hole is known to move along a geodesic. When the particle has a finite mass or charge, it emits radiation which carries away orbital energy and angular momentum, and the orbit deviates from a geodesic. In this paper we assume that the deviation is small and show that the half-advanced minus half-retarded field surprisingly provides the correct radiation reaction force, in a time-averaged sense, and determines the orbit of the particle.Keywords
All Related Versions
This publication has 14 references indexed in Scilit:
- Radiation damping in a gravitational fieldPublished by Elsevier ,2004
- Self-force via a Green’s function decompositionPhysical Review D, 2003
- Approximating the inspiral of test bodies into Kerr black holesPhysical Review D, 2002
- Zoom and whirl: Eccentric equatorial orbits around spinning black holes and their evolution under gravitational radiation reactionPhysical Review D, 2002
- Evolution of circular, nonequatorial orbits of Kerr black holes due to gravitational-wave emission. II. Inspiral trajectories and gravitational waveformsPhysical Review D, 2001
- Axiomatic approach to electromagnetic and gravitational radiation reaction of particles in curved spacetimePhysical Review D, 1997
- Gravitational radiation reaction to a particle motionPhysical Review D, 1997
- Chapter 1. Black Hole PerturbationProgress of Theoretical Physics Supplement, 1997
- Chapter 7. Gravitational Radiation ReactionProgress of Theoretical Physics Supplement, 1997
- Radiation reaction in the Kerr gravitational fieldJournal of Physics A: General Physics, 1982