Fortifying gravitational-wave tests of general relativity against astrophysical assumptions
Abstract
Most tests of general relativity with gravitational-wave observations rely on inferring the degree to which a signal deviates from general relativity in conjunction with the astrophysical parameters of its source, such as the component masses and spins of a compact binary. Due to features of the signal, measurements of these deviations are often highly correlated with the properties of astrophysical sources. As a consequence, prior assumptions about astrophysical parameters will generally affect the inferred magnitude of the deviations. Incorporating information about the underlying astrophysical population is necessary to avoid biases in the inference of deviations from general relativity. Current tests assume that the astrophysical population follows an unrealistic fiducial prior chosen to ease sampling of the posterior—for example, a prior flat in component masses—which is inconsistent with both astrophysical expectations and the distribution inferred from observations. We propose a framework for fortifying tests of general relativity by simultaneously inferring the astrophysical population using a catalog of detections. Although this method applies broadly, we demonstrate it concretely on massive graviton constraints and parametrized tests of deviations to the post-Newtonian phase coefficients. Using observations from LIGO-Virgo-KAGRA's third observing run, we show that concurrent inference of the astrophysical distribution strengthens constraints and improves overall consistency with general relativity. We provide updated constraints on deviations from the theory, finding that, upon modeling the astrophysical population, the 90%-credible upper limit on the mass of the graviton improves by 25% to 𝓂₉ ≤ 9.6 × 10⁻²⁴ eV/c² and the inferred population-level post-Newtonian deviations move ∼0.4σ closer to zero.
Copyright and License
© 2023 American Physical Society.
Acknowledgement
We thank Jacob Golomb and Alan Weinstein for insightful discussions, and Carl-Johan Haster for useful comments on the manuscript. Computing resources were provided by the Flatiron Institute. The Flatiron Institute is funded by the Simons Foundation. E. P. was supported by NSF Grant No. PHY-1764464. K. C. was supported by NSF Grant No. PHY-2110111. This material is based upon work supported by NSF's LIGO Laboratory which is a major facility fully funded by the National Science Foundation. This research has made use of data, software and/or web tools obtained from the Gravitational Wave Open Science Center ([110]) a service of LIGO Laboratory, the LIGO Scientific Collaboration and the Virgo Collaboration. Virgo is funded by the French Centre National de Recherche Scientifique (CNRS), the Italian Istituto Nazionale della Fisica Nucleare (INFN) and the Dutch Nikhef, with contributions by Polish and Hungarian institutes. The authors are grateful for computational resources provided by the LIGO Laboratory and supported by National Science Foundation Grants No. PHY-0757058 and No. PHY-0823459. This manuscript carries LIGO Document No. #P2300292.
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Additional details
- ISSN
- 2470-0029
- Flatiron Institute
- Simons Foundation
- National Science Foundation
- PHY-1764464
- National Science Foundation
- PHY-2110111
- Centre National de la Recherche Scientifique
- Istituto Nazionale di Fisica Nucleare
- Dutch Nikhef
- National Science Foundation
- PHY-0757058
- National Science Foundation
- PHY-0823459
- Caltech groups
- LIGO, TAPIR, Astronomy Department, Walter Burke Institute for Theoretical Physics
- Other Numbering System Name
- LIGO Document No.
- Other Numbering System Identifier
- P2300292