Worldtube excision method for intermediate-mass-ratio inspirals: self-consistent evolution in a scalar-charge model
Worldtube excision method for intermediate-mass-ratio inspirals: self-consistent evolution in a scalar-charge model
This is a third installment in a program to develop a method for alleviating the scale disparity in binary black hole simulations with mass ratios in the intermediate astrophysical range, where simulation cost is prohibitive while purely perturbative methods may not be adequate. The method is based on excising a “worldtube” around the smaller object, much larger than the object itself, replacing it with an analytical model that approximates a tidally deformed black hole. Previously [Phys. Rev. D 108, 024041 (2023)] we have tested the idea in a toy model of a scalar charge in a fixed circular geodesic orbit around a Schwarzschild black hole, solving for the massless Klein-Gordon field in 3+1 dimensions on the SpECTRE platform. Here we take the significant further step of allowing the orbit to evolve radiatively, in a self-consistent manner, under the effect of back reaction from the scalar field. We compute the inspiral orbit and the emitted scalar-field waveform, showing a good agreement with perturbative calculations in the adiabatic approximation. We also demonstrate how our simulations accurately resolve post-adiabatic effects (for which we do not have perturbative results). In this work we focus on quasi-circular inspirals. Our implementation will shortly be publicly accessible in the SpECTRE numerical relativity code.
Wittek, Nikolas A.
d5b843ac-a29b-444e-ae39-53f49712d570
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Pfeiffer, Harald P.
8fc76bb1-dc2f-46b1-9ef5-f004ee7abe79
Barack, Leor
f08e66d4-c2f7-4f2f-91b8-f2c4230d0298
Wittek, Nikolas A.
d5b843ac-a29b-444e-ae39-53f49712d570
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Pfeiffer, Harald P.
8fc76bb1-dc2f-46b1-9ef5-f004ee7abe79
Barack, Leor
f08e66d4-c2f7-4f2f-91b8-f2c4230d0298
Wittek, Nikolas A., Pound, Adam, Pfeiffer, Harald P. and Barack, Leor
(2024)
Worldtube excision method for intermediate-mass-ratio inspirals: self-consistent evolution in a scalar-charge model.
Physical Review D.
(In Press)
Abstract
This is a third installment in a program to develop a method for alleviating the scale disparity in binary black hole simulations with mass ratios in the intermediate astrophysical range, where simulation cost is prohibitive while purely perturbative methods may not be adequate. The method is based on excising a “worldtube” around the smaller object, much larger than the object itself, replacing it with an analytical model that approximates a tidally deformed black hole. Previously [Phys. Rev. D 108, 024041 (2023)] we have tested the idea in a toy model of a scalar charge in a fixed circular geodesic orbit around a Schwarzschild black hole, solving for the massless Klein-Gordon field in 3+1 dimensions on the SpECTRE platform. Here we take the significant further step of allowing the orbit to evolve radiatively, in a self-consistent manner, under the effect of back reaction from the scalar field. We compute the inspiral orbit and the emitted scalar-field waveform, showing a good agreement with perturbative calculations in the adiabatic approximation. We also demonstrate how our simulations accurately resolve post-adiabatic effects (for which we do not have perturbative results). In this work we focus on quasi-circular inspirals. Our implementation will shortly be publicly accessible in the SpECTRE numerical relativity code.
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Accepted/In Press date: 13 August 2024
Identifiers
Local EPrints ID: 494312
URI: http://eprints.soton.ac.uk/id/eprint/494312
ISSN: 2470-0010
PURE UUID: 3fdf38eb-19c2-4c71-a395-6f283d04f0b6
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Date deposited: 03 Oct 2024 16:43
Last modified: 21 Nov 2024 02:44
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Author:
Nikolas A. Wittek
Author:
Harald P. Pfeiffer
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