Success of the small mass-ratio approximation during the final orbits of binary black hole simulations
Abstract
Recent studies have shown the surprising effectiveness of the small mass-ratio approximation (SMR) in modeling the relativistic two-body problem even at comparable masses. Up to now this effectiveness has been demonstrated only during inspiral, before the binary transitions into plunge and merger. Here we examine the binding energy of nonspinning binary black hole simulations with mass ratios from 20 ∶ 1 to equal mass. We show for the first time that the binaries undergo a transition to plunge as predicted by analytic theory, and estimate the size of the transition region, which is ∼ 10 gravitational wave cycles for equal mass binaries. By including transition, the SMR expansion of the binding energy is accurate until the last cycle of gravitational wave emission. This is true even for comparable mass binaries such as those observed by current gravitational wave detectors, where the transition often makes up much of the observed signal. Our work provides further evidence that the SMR approximation can be directly applied to current gravitational wave observations.
Additional Information
© 2023 American Physical Society. We would like to thank the authors of the SpEC simulations used in this analysis: Serguei Ossokine, Joohean Yoo, Vijay Varma and Jonathan Blackman. We also thank Adam Pound, Niels Warburton, Barry Wardell and Leanne Durkan for discussions about the transition expansion and filtering method and for generously sharing the 2GSF flux data from [45]. For the simulations used in this work, computations were performed on the Wheeler cluster at Caltech, which is supported by the Sherman Fairchild Foundation and by Caltech; and on Frontera at the Texas Advanced Computing Center [93]. We also thank the developers of scri [85,86], which was used to calculate the energy and angular momentum fluxes. This work makes use of the Black Hole Perturbation Toolkit [92]. S. N. A. and A. Z. are supported by National Science Foundation (NSF) Grants No. PHY-1912578 and No. PHY-2207594. M. G. is supported by NSF Grant No. PHY-1912081 at Cornell. M. A. S. is supported in part by the Sherman Fairchild Foundation and by NSF Grants No. PHY-2011961, No. PHY-2011968, and No. OAC-1931266 at Caltech.Attached Files
Published - PhysRevD.107.084021.pdf
Supplemental Material - supplementary.pdf
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Additional details
- Eprint ID
- 121604
- Resolver ID
- CaltechAUTHORS:20230530-441187700.21
- Sherman Fairchild Foundation
- Caltech
- NSF
- PHY-1912578
- NSF
- PHY-2207594
- NSF
- PHY-1912081
- NSF
- PHY-2011961
- NSF
- PHY-2011968
- NSF
- OAC-1931266
- Created
-
2023-06-28Created from EPrint's datestamp field
- Updated
-
2023-06-28Created from EPrint's last_modified field
- Caltech groups
- TAPIR, Walter Burke Institute for Theoretical Physics