Two approaches for the gravitational self force in black hole spacetime: comparison of numerical results
Two approaches for the gravitational self force in black hole spacetime: comparison of numerical results
Recently, two independent calculations have been presented of finite-mass (“self-force”) effects on the orbit of a point mass around a Schwarzschild black hole. While both computations are based on the standard mode-sum method, they differ in several technical aspects, which makes comparison between their results difficult—but also interesting. Barack and Sago [Phys. Rev. D 75, 064021 (2007)] invoke the notion of a self-accelerated motion in a background spacetime, and perform a direct calculation of the local self-force in the Lorenz gauge (using numerical evolution of the perturbation equations in the time domain); Detweiler [Phys. Rev. D 77, 124026 (2008)] describes the motion in terms a geodesic orbit of a (smooth) perturbed spacetime, and calculates the metric perturbation in the Regge-Wheeler gauge (using frequency-domain numerical analysis). Here we establish a formal correspondence between the two analyses, and demonstrate the consistency of their numerical results. Specifically, we compare the value of the conservative O(?) shift in ut (where ? is the particle’s mass and ut is the Schwarzschild t component of the particle’s four-velocity), suitably mapped between the two orbital descriptions and adjusted for gauge. We find that the two analyses yield the same value for this shift within mere fractional differences of ?10-5–10-7 (depending on the orbital radius)—comparable with the estimated numerical error.
124024-[9pp]
Sago, Norichika
50641559-f289-4ffa-810b-fe4ec8c26e26
Barack, Leor
f08e66d4-c2f7-4f2f-91b8-f2c4230d0298
Detweiler, Steven
95b5d66c-a475-4615-a92f-a42389b23268
30 December 2008
Sago, Norichika
50641559-f289-4ffa-810b-fe4ec8c26e26
Barack, Leor
f08e66d4-c2f7-4f2f-91b8-f2c4230d0298
Detweiler, Steven
95b5d66c-a475-4615-a92f-a42389b23268
Sago, Norichika, Barack, Leor and Detweiler, Steven
(2008)
Two approaches for the gravitational self force in black hole spacetime: comparison of numerical results.
Physical Review D, 78 (12), .
(doi:10.1103/PhysRevD.78.124024).
Abstract
Recently, two independent calculations have been presented of finite-mass (“self-force”) effects on the orbit of a point mass around a Schwarzschild black hole. While both computations are based on the standard mode-sum method, they differ in several technical aspects, which makes comparison between their results difficult—but also interesting. Barack and Sago [Phys. Rev. D 75, 064021 (2007)] invoke the notion of a self-accelerated motion in a background spacetime, and perform a direct calculation of the local self-force in the Lorenz gauge (using numerical evolution of the perturbation equations in the time domain); Detweiler [Phys. Rev. D 77, 124026 (2008)] describes the motion in terms a geodesic orbit of a (smooth) perturbed spacetime, and calculates the metric perturbation in the Regge-Wheeler gauge (using frequency-domain numerical analysis). Here we establish a formal correspondence between the two analyses, and demonstrate the consistency of their numerical results. Specifically, we compare the value of the conservative O(?) shift in ut (where ? is the particle’s mass and ut is the Schwarzschild t component of the particle’s four-velocity), suitably mapped between the two orbital descriptions and adjusted for gauge. We find that the two analyses yield the same value for this shift within mere fractional differences of ?10-5–10-7 (depending on the orbital radius)—comparable with the estimated numerical error.
This record has no associated files available for download.
More information
Published date: 30 December 2008
Organisations:
Applied Mathematics
Identifiers
Local EPrints ID: 63997
URI: http://eprints.soton.ac.uk/id/eprint/63997
ISSN: 1550-7998
PURE UUID: e178dfc4-857f-4b62-96a3-5d15ca41c501
Catalogue record
Date deposited: 24 Nov 2008
Last modified: 16 Mar 2024 03:41
Export record
Altmetrics
Contributors
Author:
Norichika Sago
Author:
Steven Detweiler
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics
