Constraints on the Maximum Densities of Neutron Stars from Postmerger Gravitational Waves with Third-Generation Observations

Matteo Breschi; Sebastiano Bernuzzi; Daniel Godzieba; Albino Perego; David Radice

doi:10.1103/PhysRevLett.128.161102

Constraints on the Maximum Densities of Neutron Stars from Postmerger Gravitational Waves with Third-Generation Observations

Matteo Breschi, Sebastiano Bernuzzi, Daniel Godzieba, Albino Perego, David Radice

Physics

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

4 Scopus citations

Abstract

Using data from 289 numerical relativity simulations of binary neutron star mergers, we identify, for the first time, a robust quasiuniversal relation connecting the postmerger peak gravitational-wave frequency and the value of the density at the center of the maximum mass nonrotating neutron star. This relation offers a new possibility for precision equation-of-state constraints with next-generation ground-based gravitational-wave interferometers. Mock Einstein Telescope observations of fiducial events indicate that Bayesian inferences can constrain the maximum density to ∼15% (90% credibility level) for a single signal at the minimum sensitivity threshold for a detection. If the postmerger signal is included in a full-spectrum (inspiral-merger-postmerger) analysis of such a signal, the pressure-density function can be tightly constrained up to the maximum density, and the maximum neutron star mass can be measured with an accuracy better than 12% (90% credibility level).

Original language	English (US)
Article number	161102
Journal	Physical review letters
Volume	128
Issue number	16
DOIs	https://doi.org/10.1103/PhysRevLett.128.161102
State	Published - Apr 22 2022

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)

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10.1103/PhysRevLett.128.161102

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@article{033b42aef6404a54a8210a006cd8e4a9,

title = "Constraints on the Maximum Densities of Neutron Stars from Postmerger Gravitational Waves with Third-Generation Observations",

abstract = "Using data from 289 numerical relativity simulations of binary neutron star mergers, we identify, for the first time, a robust quasiuniversal relation connecting the postmerger peak gravitational-wave frequency and the value of the density at the center of the maximum mass nonrotating neutron star. This relation offers a new possibility for precision equation-of-state constraints with next-generation ground-based gravitational-wave interferometers. Mock Einstein Telescope observations of fiducial events indicate that Bayesian inferences can constrain the maximum density to ∼15% (90% credibility level) for a single signal at the minimum sensitivity threshold for a detection. If the postmerger signal is included in a full-spectrum (inspiral-merger-postmerger) analysis of such a signal, the pressure-density function can be tightly constrained up to the maximum density, and the maximum neutron star mass can be measured with an accuracy better than 12% (90% credibility level).",

author = "Matteo Breschi and Sebastiano Bernuzzi and Daniel Godzieba and Albino Perego and David Radice",

note = "Funding Information: The authors thank Francesco Zappa, Aviral Prakash, and Andrea Camilletti for providing unreleased NR data and Ssohrab Borhanian for providing additional documentation for gwbench . Moreover, we acknowledge important discussions in the LIGO-Virgo Extreme matter group and within the Virgo-EGO Collaboration; in particular, we thank Nikolaos Stergioulas, Katerina Chatziioannou, and Jocelyn Read. M. B. and S. B. acknowledge support by the EU H2020 under ERC Starting Grant No. BinGraSp-714626. M. B. acknowledges support from the Deutsche Forschungsgemeinschaft (DFG) under Grant No. 406116891 within the Research Training Group RTG 2522/1. D. R. acknowledges funding from the U.S. Department of Energy, Office of Science, Division of Nuclear Physics under Grant No. DE-SC0021177 and from the National Science Foundation under Grants No. PHY-2011725, No. PHY-2020275, No. PHY-2116686, and No. AST-2108467. 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. Simulations were performed on ARA, a resource of Friedrich-Schiller-Universt{\"a}t Jena supported in part by DFG Grants No. INST 275/334-1 FUGG, No. INST 275/363-1 FUGG, and No. EU H2020 BinGraSp-714626. The bajes software together with the nrpm model are publicly available . The NR simulations employed in this work are publicly available . Publisher Copyright: {\textcopyright} 2022 American Physical Society.",

year = "2022",

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doi = "10.1103/PhysRevLett.128.161102",

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T1 - Constraints on the Maximum Densities of Neutron Stars from Postmerger Gravitational Waves with Third-Generation Observations

AU - Breschi, Matteo

AU - Bernuzzi, Sebastiano

AU - Godzieba, Daniel

AU - Perego, Albino

AU - Radice, David

N1 - Funding Information: The authors thank Francesco Zappa, Aviral Prakash, and Andrea Camilletti for providing unreleased NR data and Ssohrab Borhanian for providing additional documentation for gwbench . Moreover, we acknowledge important discussions in the LIGO-Virgo Extreme matter group and within the Virgo-EGO Collaboration; in particular, we thank Nikolaos Stergioulas, Katerina Chatziioannou, and Jocelyn Read. M. B. and S. B. acknowledge support by the EU H2020 under ERC Starting Grant No. BinGraSp-714626. M. B. acknowledges support from the Deutsche Forschungsgemeinschaft (DFG) under Grant No. 406116891 within the Research Training Group RTG 2522/1. D. R. acknowledges funding from the U.S. Department of Energy, Office of Science, Division of Nuclear Physics under Grant No. DE-SC0021177 and from the National Science Foundation under Grants No. PHY-2011725, No. PHY-2020275, No. PHY-2116686, and No. AST-2108467. 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. Simulations were performed on ARA, a resource of Friedrich-Schiller-Universtät Jena supported in part by DFG Grants No. INST 275/334-1 FUGG, No. INST 275/363-1 FUGG, and No. EU H2020 BinGraSp-714626. The bajes software together with the nrpm model are publicly available . The NR simulations employed in this work are publicly available . Publisher Copyright: © 2022 American Physical Society.

PY - 2022/4/22

Y1 - 2022/4/22

N2 - Using data from 289 numerical relativity simulations of binary neutron star mergers, we identify, for the first time, a robust quasiuniversal relation connecting the postmerger peak gravitational-wave frequency and the value of the density at the center of the maximum mass nonrotating neutron star. This relation offers a new possibility for precision equation-of-state constraints with next-generation ground-based gravitational-wave interferometers. Mock Einstein Telescope observations of fiducial events indicate that Bayesian inferences can constrain the maximum density to ∼15% (90% credibility level) for a single signal at the minimum sensitivity threshold for a detection. If the postmerger signal is included in a full-spectrum (inspiral-merger-postmerger) analysis of such a signal, the pressure-density function can be tightly constrained up to the maximum density, and the maximum neutron star mass can be measured with an accuracy better than 12% (90% credibility level).

AB - Using data from 289 numerical relativity simulations of binary neutron star mergers, we identify, for the first time, a robust quasiuniversal relation connecting the postmerger peak gravitational-wave frequency and the value of the density at the center of the maximum mass nonrotating neutron star. This relation offers a new possibility for precision equation-of-state constraints with next-generation ground-based gravitational-wave interferometers. Mock Einstein Telescope observations of fiducial events indicate that Bayesian inferences can constrain the maximum density to ∼15% (90% credibility level) for a single signal at the minimum sensitivity threshold for a detection. If the postmerger signal is included in a full-spectrum (inspiral-merger-postmerger) analysis of such a signal, the pressure-density function can be tightly constrained up to the maximum density, and the maximum neutron star mass can be measured with an accuracy better than 12% (90% credibility level).

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Constraints on the Maximum Densities of Neutron Stars from Postmerger Gravitational Waves with Third-Generation Observations

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