Gravitational self-force on eccentric equatorial orbits around a Kerr black hole
Gravitational self-force on eccentric equatorial orbits around a Kerr black hole
This paper presents the first calculation of the gravitational self-force on a small compact object on an eccentric equatorial orbit around a Kerr black hole to first order in the mass ratio. That is the pointwise correction to the object’s equations of motion (both conservative and dissipative) due to its own gravitational field, which is treated as a linear perturbation to the background Kerr spacetime generated by the much larger spinning black hole. The calculation builds on recent advances on constructing the local metric and self-force from solutions of the Teukolsky equation, which led to the calculation of the Detweiler-Barack-Sago redshift invariant on eccentric equatorial orbits around a Kerr black hole in a previous paper. After deriving the necessary expression to obtain the self-force from the Weyl scalar ?4, we perform several consistency checks of the method and numerical implementation, including a check of the balance law relating the orbital average of the self-force to the average flux of energy and angular momentum out of the system. Particular attention is paid to the pointwise convergence properties of the sum over frequency modes in our method, identifying a systematic inherent loss of precision that any frequency domain calculation of the self-force on eccentric orbits must overcome.
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Van De Meent, Maarten
c06e1d53-18af-4ef1-8671-ff99b1a1df22
19 August 2016
Van De Meent, Maarten
c06e1d53-18af-4ef1-8671-ff99b1a1df22
Van De Meent, Maarten
(2016)
Gravitational self-force on eccentric equatorial orbits around a Kerr black hole.
Physical Review D, 94 (4), .
(doi:10.1103/PhysRevD.94.044034).
Abstract
This paper presents the first calculation of the gravitational self-force on a small compact object on an eccentric equatorial orbit around a Kerr black hole to first order in the mass ratio. That is the pointwise correction to the object’s equations of motion (both conservative and dissipative) due to its own gravitational field, which is treated as a linear perturbation to the background Kerr spacetime generated by the much larger spinning black hole. The calculation builds on recent advances on constructing the local metric and self-force from solutions of the Teukolsky equation, which led to the calculation of the Detweiler-Barack-Sago redshift invariant on eccentric equatorial orbits around a Kerr black hole in a previous paper. After deriving the necessary expression to obtain the self-force from the Weyl scalar ?4, we perform several consistency checks of the method and numerical implementation, including a check of the balance law relating the orbital average of the self-force to the average flux of energy and angular momentum out of the system. Particular attention is paid to the pointwise convergence properties of the sum over frequency modes in our method, identifying a systematic inherent loss of precision that any frequency domain calculation of the self-force on eccentric orbits must overcome.
Text
gsfkerr.pdf
- Accepted Manuscript
More information
Accepted/In Press date: 15 August 2016
e-pub ahead of print date: 19 August 2016
Published date: 19 August 2016
Organisations:
Applied Mathematics
Identifiers
Local EPrints ID: 403473
URI: http://eprints.soton.ac.uk/id/eprint/403473
ISSN: 1550-7998
PURE UUID: 61acd6ad-ea23-4f20-aebe-d57dee98c9d5
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Date deposited: 02 Dec 2016 10:04
Last modified: 15 Mar 2024 03:43
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Author:
Maarten Van De Meent
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