Self-Force on a Particle in Orbit around a Black Hole
- 15 May 2000
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 84 (20) , 4529-4532
- https://doi.org/10.1103/physrevlett.84.4529
Abstract
We study the self-force acting on a scalar charge in uniform circular motion around a Schwarzschild black hole. The analysis is based on a direct calculation of the self-force via mode decomposition, and on a regularization procedure based on Ori's mode-sum regularization prescription. We find the four self-forces at arbitrary radii and angular velocities (both geodesic and nongeodesic), in particular near the black hole, where general-relativistic effects are strongest, and for fast motion. We find the radial component of the self-force to be repulsive or attractive, depending on the orbit.Keywords
All Related Versions
This publication has 11 references indexed in Scilit:
- Self-force approach to synchrotron radiationAmerican Journal of Physics, 2000
- Self-force on a static scalar test charge outside a Schwarzschild black holePhysical Review D, 2000
- Evolution of circular, nonequatorial orbits of Kerr black holes due to gravitational-wave emissionPhysical Review D, 2000
- Self-force on static charges in Schwarzschild spacetimeClassical and Quantum Gravity, 1999
- Optimal entropy bound and the self-energy of test objects in the vicinity of a black holePhysical Review D, 1999
- Measuring gravitational waves from binary black hole coalescences. II. The waves’ information and its extraction, with and without templatesPhysical Review D, 1998
- Axiomatic approach to electromagnetic and gravitational radiation reaction of particles in curved spacetimePhysical Review D, 1997
- Radiative evolution of the Carter constant for generic orbits around a Kerr black holePhysical Review D, 1997
- Gravitational radiation reaction to a particle motionPhysical Review D, 1997
- Radiative evolution of orbits around a Kerr black holePhysics Letters A, 1995