Postadiabatic dynamics and waveform generation in self-force theory: An invariant pseudo-Hamiltonian framework
Postadiabatic dynamics and waveform generation in self-force theory: An invariant pseudo-Hamiltonian framework
Gravitational waveform modeling in self-force theory has reached a mature stage in recent years, with fast and accurate models emerging at both adiabatic (0PA) and first post-adiabatic (1PA) orders in a multiscale expansion. Here, we provide a gauge-invariant 1PA waveform-generation framework that involves no direct calculation of the (gauge-dependent) self-force. To achieve this, we recast the multiscale framework in a pseudo-Hamiltonian form, working on the six-dimensional phase space intrinsic to the multiscale expansion. We characterize the gauge freedom on phase space and show how a localization procedure avoids nonlocal-in-time effects in the 1PA dynamics. We find a conservative Hamiltonian structure can be naturally embedded into the complete, dissipative~1PA pseudo-Hamiltonian dynamics, giving rise to natural definitions of the conserved energy, angular momentum, and radial and polar actions. As a byproduct, we clarify that the on-shell value of the conservative Hamiltonian is equal to the mechanical energy historically predicted by the first law of binary black hole mechanics.
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Lewis, Jack Edward
ac314faa-6b25-400a-9fba-b39f1d617680
Tanaka, Takahiro
13fcab0c-a5cd-41af-9164-065d839dec5f
Kakehi, Takafumi
eaf0231e-b051-44ae-b556-9d1dead224bd
Pound, Adam
5aac971a-0e07-4383-aff0-a21d43103a70
Lewis, Jack Edward
ac314faa-6b25-400a-9fba-b39f1d617680
Tanaka, Takahiro
13fcab0c-a5cd-41af-9164-065d839dec5f
Kakehi, Takafumi
eaf0231e-b051-44ae-b556-9d1dead224bd
Pound, Adam, Lewis, Jack Edward, Tanaka, Takahiro and Kakehi, Takafumi
(2025)
Postadiabatic dynamics and waveform generation in self-force theory: An invariant pseudo-Hamiltonian framework.
Physical Review D.
(doi:10.1103/jllr-kl86).
(In Press)
Abstract
Gravitational waveform modeling in self-force theory has reached a mature stage in recent years, with fast and accurate models emerging at both adiabatic (0PA) and first post-adiabatic (1PA) orders in a multiscale expansion. Here, we provide a gauge-invariant 1PA waveform-generation framework that involves no direct calculation of the (gauge-dependent) self-force. To achieve this, we recast the multiscale framework in a pseudo-Hamiltonian form, working on the six-dimensional phase space intrinsic to the multiscale expansion. We characterize the gauge freedom on phase space and show how a localization procedure avoids nonlocal-in-time effects in the 1PA dynamics. We find a conservative Hamiltonian structure can be naturally embedded into the complete, dissipative~1PA pseudo-Hamiltonian dynamics, giving rise to natural definitions of the conserved energy, angular momentum, and radial and polar actions. As a byproduct, we clarify that the on-shell value of the conservative Hamiltonian is equal to the mechanical energy historically predicted by the first law of binary black hole mechanics.
Text
Second_order_bypath_project
- Accepted Manuscript
More information
Accepted/In Press date: 17 December 2025
Identifiers
Local EPrints ID: 508703
URI: http://eprints.soton.ac.uk/id/eprint/508703
ISSN: 2470-0010
PURE UUID: c3231a29-319e-460c-8d72-4f828ca06001
Catalogue record
Date deposited: 30 Jan 2026 17:46
Last modified: 31 Jan 2026 04:49
Export record
Altmetrics
Contributors
Author:
Jack Edward Lewis
Author:
Takahiro Tanaka
Author:
Takafumi Kakehi
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
