Hybrid waveform model for asymmetric spinning binaries: self-force meets post-Newtonian theory
Hybrid waveform model for asymmetric spinning binaries: self-force meets post-Newtonian theory
We develop and implement a new hybrid waveform model for quasicircular inspirals with a spinning primary and nonspinning secondary, excluding the merger and ringdown. This model, which is a core component of the more extensive WaSABI-C model, consistently assembles all available first-order self-force and post-Newtonian results through a hybridization procedure without any tuning to numerical relativity, making it particularly suited for intermediate to extreme mass ratios. For almost all masses and primary spins, the resulting hybrid model significantly improves the faithfulness of both post-Newtonian and adiabatic self-force waveforms considered separately. We provide detailed comparisons with 50 simulations from the SXS catalog with mass ratios ranging from 1 to 15 and primary spins ranging from −0.8 to 0.8. The hybrid model improves the median mismatch against numerical relativity waveforms by a factor of 2000 with respect to adiabatic waveforms and 40 with respect to post-Newtonian waveforms. The mismatches are comparable to those obtained from the SEOBNRv5EHM model in the quasicircular limit over most of the parameter space covered by numerical relativity simulations.
Honet, Loic
fcdf0b39-dc9e-4976-ac6d-dbaa9b25e910
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Compere, Geoffrey
2d021c5a-9aec-437f-8c94-dfb518f44d25
Honet, Loic
fcdf0b39-dc9e-4976-ac6d-dbaa9b25e910
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Compere, Geoffrey
2d021c5a-9aec-437f-8c94-dfb518f44d25
Honet, Loic, Pound, Adam and Compere, Geoffrey
(2026)
Hybrid waveform model for asymmetric spinning binaries: self-force meets post-Newtonian theory.
Physical Review D, 113, [064035].
(doi:10.1103/rhwy-59y2).
Abstract
We develop and implement a new hybrid waveform model for quasicircular inspirals with a spinning primary and nonspinning secondary, excluding the merger and ringdown. This model, which is a core component of the more extensive WaSABI-C model, consistently assembles all available first-order self-force and post-Newtonian results through a hybridization procedure without any tuning to numerical relativity, making it particularly suited for intermediate to extreme mass ratios. For almost all masses and primary spins, the resulting hybrid model significantly improves the faithfulness of both post-Newtonian and adiabatic self-force waveforms considered separately. We provide detailed comparisons with 50 simulations from the SXS catalog with mass ratios ranging from 1 to 15 and primary spins ranging from −0.8 to 0.8. The hybrid model improves the median mismatch against numerical relativity waveforms by a factor of 2000 with respect to adiabatic waveforms and 40 with respect to post-Newtonian waveforms. The mismatches are comparable to those obtained from the SEOBNRv5EHM model in the quasicircular limit over most of the parameter space covered by numerical relativity simulations.
Text
Hybrid_inspiral_model_with_spin
- Accepted Manuscript
More information
Accepted/In Press date: 18 February 2026
e-pub ahead of print date: 19 March 2026
Identifiers
Local EPrints ID: 510994
URI: http://eprints.soton.ac.uk/id/eprint/510994
ISSN: 2470-0010
PURE UUID: 34b98a67-624a-4db0-9182-da9fdf36dde7
Catalogue record
Date deposited: 28 Apr 2026 17:00
Last modified: 29 Apr 2026 01:46
Export record
Altmetrics
Contributors
Author:
Loic Honet
Author:
Geoffrey Compere
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
