A hybrid post-Newtonian -- effective-one-body scheme for spin-precessing compact-binary waveforms
Abstract
We introduce \texttt{TEOBResumSP}: an efficient, accurate hybrid scheme for generating gravitational waveforms from spin-precessing compact binaries. The precessing waveforms are generated via the established technique of Euler rotating the non-precessing \texttt{TEOBResumS} waveforms from a precessing frame to an inertial frame. We obtain the Euler angles by solving the post-Newtonian precession equations expanded to second post-Newtonian order. Current version of \texttt{TEOBResumSP} produces precessing waveforms through the inspiral phase up to the onset of the merger. We compare \texttt{TEOBResumSP} to current state-of-the-art precessing approximants \texttt{NRSur7dq4}, \texttt{SEOBNRv4PHM}, and \texttt{IMRPhenomPv3HM} for 200 cases of precessing compact binary inspirals with orbital inclinations up to 90 degrees, mass ratios up to four, and the effective precession parameter up to 0.75. We further provide an extended comparison with \texttt{SEOBNRv4PHM} involving 1030 more inspirals with and mass ratios up to 10. We find that 91\% of the \texttt{TEOBResumSP}-\texttt{NRSur7dq4} matches, 85\% of the \texttt{TEOBResumSP}-\texttt{SEOBNRv4PHM} matches, and 77\% of the \texttt{TEOBResumSP}-\texttt{IMRPhenomPv3HM} matches are greater than . Most disagreements occur for large mass ratios and . We identify the mismatch of the \emph{non}-precessing mode as one of the leading causes of disagreements. We also introduce a new parameter, , to measure the strength of precession and hint that the mismatch between the above approximants shows an exponential dependence on though this requires further study. Our results indicate that \texttt{TEOBResumSP} is on its way to becoming a robust precessing approximant to be employed in the parameter estimation of generic-spin compact binaries.
Cite
@article{arxiv.2005.05338,
title = {A hybrid post-Newtonian -- effective-one-body scheme for spin-precessing compact-binary waveforms},
author = {Sarp Akcay and Rossella Gamba and Sebastiano Bernuzzi},
journal= {arXiv preprint arXiv:2005.05338},
year = {2021}
}
Comments
23 pages, 14 figures. Matches the accepted Phys. Rev. D version modulo abridged abstract, American vs. British English, and some figure placements