Nonlinear curvature effects in gravitational waves from inspiralling black hole binaries

Banafsheh Shiralilou; Tanja Hinderer; Samaya M. Nissanke; Néstor Ortiz; Helvi Witek

doi:10.1103/PhysRevD.103.L121503

Nonlinear curvature effects in gravitational waves from inspiralling black hole binaries

Banafsheh Shiralilou, Tanja Hinderer, Samaya M. Nissanke, Néstor Ortiz, Helvi Witek

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Gravitational waves (GWs) from merging black holes allow for unprecedented probes of strong-field gravity. Testing gravity in this regime requires accurate predictions of gravitational waveform templates in viable extensions of general relativity. We concentrate on scalar Gauss-Bonnet gravity, one of the most compelling classes of theories appearing as the low-energy limit of quantum gravity paradigms, which introduces quadratic curvature corrections to gravity coupled to a scalar field and allows for black hole solutions with scalar charge. Focusing on inspiraling black hole binaries, we compute the leading-order corrections due to curvature nonlinearities in the GW and scalar waveforms, showing that the new contributions, beyond merely the effect of scalar field, appear at first post-Newtonian order in GWs. We provide ready-to-implement GW polarizations and phasing. Computing the GW phasing in the Fourier domain, we perform a parameter-space study to quantify the detectability of deviations from general relativity. Our results lay important foundations for future precision tests of gravity with both parametrized and theory-specific searches.

Original language	English
Article number	L121503
Journal	Physical Review D
Volume	103
Issue number	12
DOIs	https://doi.org/10.1103/PhysRevD.103.L121503
Publication status	Published - 15 Jun 2021

Bibliographical note

Funding Information:
We thank L. Gualtieri, H. O. Silva, H. S. Chia, and S. Mukherjee for useful discussions. B. S., T. H., and S. M. N. are grateful for financial support from the Nederlandse Organisatie voor Wetenschappelijk Onderzoek (NWO) through the Projectruimte and VIDI grants (Nissanke). T. H. also acknowledges financial support from the NWO sector plan. N. O. acknowledges financial support by the CONACyT Grants “Ciencia de frontera” No. 140630 and No. 376127, and by the UNAM-PAPIIT Grant No. IA100721. H. W. acknowledges financial support provided by NSF Grant No. OAC-2004879 and the Royal Society Research Grant No. RGF\R1\180073.

Publisher Copyright:
© 2021 American Physical Society.

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abstract = "Gravitational waves (GWs) from merging black holes allow for unprecedented probes of strong-field gravity. Testing gravity in this regime requires accurate predictions of gravitational waveform templates in viable extensions of general relativity. We concentrate on scalar Gauss-Bonnet gravity, one of the most compelling classes of theories appearing as the low-energy limit of quantum gravity paradigms, which introduces quadratic curvature corrections to gravity coupled to a scalar field and allows for black hole solutions with scalar charge. Focusing on inspiraling black hole binaries, we compute the leading-order corrections due to curvature nonlinearities in the GW and scalar waveforms, showing that the new contributions, beyond merely the effect of scalar field, appear at first post-Newtonian order in GWs. We provide ready-to-implement GW polarizations and phasing. Computing the GW phasing in the Fourier domain, we perform a parameter-space study to quantify the detectability of deviations from general relativity. Our results lay important foundations for future precision tests of gravity with both parametrized and theory-specific searches.",

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note = "Funding Information: We thank L. Gualtieri, H. O. Silva, H. S. Chia, and S. Mukherjee for useful discussions. B. S., T. H., and S. M. N. are grateful for financial support from the Nederlandse Organisatie voor Wetenschappelijk Onderzoek (NWO) through the Projectruimte and VIDI grants (Nissanke). T. H. also acknowledges financial support from the NWO sector plan. N. O. acknowledges financial support by the CONACyT Grants “Ciencia de frontera” No. 140630 and No. 376127, and by the UNAM-PAPIIT Grant No. IA100721. H. W. acknowledges financial support provided by NSF Grant No. OAC-2004879 and the Royal Society Research Grant No. RGF\R1\180073. Publisher Copyright: {\textcopyright} 2021 American Physical Society.",

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Nonlinear curvature effects in gravitational waves from inspiralling black hole binaries

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