Testing the post-Newtonian expansion with GW170817

Observations of gravitational waves from compact binary mergers have enabled unique tests of general relativity in the dynamical and non-linear regimes. One of the most important such tests is constraints on the post-Newtonian (PN) corrections to the phase of the gravitational wave signal. The value...

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Veröffentlicht in:	General relativity and gravitation 2023-04, Vol.55 (4), Article 55
Hauptverfasser:	Shoom, Andrey A., Gupta, Pawan K., Krishnan, Badri, Nielsen, Alex B., Capano, Collin D.
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Schlagworte:	Astronomy Astrophysics and Cosmology Binary stars Classical and Quantum Gravitation Coalescence Coefficients Covariance matrix Deviation Differential Geometry Gravitational waves Gravity Mathematical analysis Mathematical and Computational Physics Neutron stars Parameters Physics Physics and Astronomy Quantum Physics Relativity Relativity Theory Research Article Theoretical Theory of relativity
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description	Observations of gravitational waves from compact binary mergers have enabled unique tests of general relativity in the dynamical and non-linear regimes. One of the most important such tests is constraints on the post-Newtonian (PN) corrections to the phase of the gravitational wave signal. The values of the PN coefficients can be calculated within standard general relativity, and these values are different in many alternate theories of gravity. It is clearly of great interest to constrain the deviations based on gravitational wave observations. In the majority of such tests which have been carried out, and which yield by far the most stringent constraints, it is common to vary these PN coefficients individually. While this might in principle be useful for detecting certain deviations from standard general relativity, it is a serious limitation. For example, we would expect alternate theories of gravity to generically have additional parameters. The corrections to the PN coefficients would be expected to depend on these additional non-GR parameters, whence, we expect that the various PN coefficients to be highly correlated. We present an alternate analysis here using data from the binary neutron star coalescence GW170817. Our analysis uses an appropriate linear combination of non-GR parameters that represent absolute deviations from the corresponding post-Newtonian inspiral coefficients in the TaylorF2 approximant phase. These combinations represent uncorrelated non-GR parameters which correspond to principal directions of their covariance matrix in the parameter subspace. Our results illustrate good agreement with GR. In particular, the integral non-GR phase is Ψ i n t - n o n - G R = 0.0447 ± 25.3000 and the deviation from GR percentile is p n D e v - G R = 25.85 % .
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One of the most important such tests is constraints on the post-Newtonian (PN) corrections to the phase of the gravitational wave signal. The values of the PN coefficients can be calculated within standard general relativity, and these values are different in many alternate theories of gravity. It is clearly of great interest to constrain the deviations based on gravitational wave observations. In the majority of such tests which have been carried out, and which yield by far the most stringent constraints, it is common to vary these PN coefficients individually. While this might in principle be useful for detecting certain deviations from standard general relativity, it is a serious limitation. For example, we would expect alternate theories of gravity to generically have additional parameters. The corrections to the PN coefficients would be expected to depend on these additional non-GR parameters, whence, we expect that the various PN coefficients to be highly correlated. We present an alternate analysis here using data from the binary neutron star coalescence GW170817. Our analysis uses an appropriate linear combination of non-GR parameters that represent absolute deviations from the corresponding post-Newtonian inspiral coefficients in the TaylorF2 approximant phase. These combinations represent uncorrelated non-GR parameters which correspond to principal directions of their covariance matrix in the parameter subspace. Our results illustrate good agreement with GR. 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We present an alternate analysis here using data from the binary neutron star coalescence GW170817. Our analysis uses an appropriate linear combination of non-GR parameters that represent absolute deviations from the corresponding post-Newtonian inspiral coefficients in the TaylorF2 approximant phase. These combinations represent uncorrelated non-GR parameters which correspond to principal directions of their covariance matrix in the parameter subspace. Our results illustrate good agreement with GR. 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We present an alternate analysis here using data from the binary neutron star coalescence GW170817. Our analysis uses an appropriate linear combination of non-GR parameters that represent absolute deviations from the corresponding post-Newtonian inspiral coefficients in the TaylorF2 approximant phase. These combinations represent uncorrelated non-GR parameters which correspond to principal directions of their covariance matrix in the parameter subspace. Our results illustrate good agreement with GR. In particular, the integral non-GR phase is Ψ i n t - n o n - G R = 0.0447 ± 25.3000 and the deviation from GR percentile is p n D e v - G R = 25.85 % .</abstract><cop>New York</cop><pub>Springer US</pub><doi>10.1007/s10714-023-03100-z</doi><oa>free_for_read</oa></addata></record>
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subjects	Astronomy Astrophysics and Cosmology Binary stars Classical and Quantum Gravitation Coalescence Coefficients Covariance matrix Deviation Differential Geometry Gravitational waves Gravity Mathematical analysis Mathematical and Computational Physics Neutron stars Parameters Physics Physics and Astronomy Quantum Physics Relativity Relativity Theory Research Article Theoretical Theory of relativity
title	Testing the post-Newtonian expansion with GW170817
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