Standard-siren cosmology using gravitational waves from binary black holes
Standard-siren cosmology using gravitational waves from binary black holes
Gravitational-wave astronomy provides a unique new way to study the expansion history of the universe. In this work, we investigate the impact future gravitational-wave observatories will have on cosmology. Third-generation observatories like the Einstein Telescope and Cosmic Explorer will be sensitive to essentially all of the binary black hole coalescence events in the universe. Recent work by Farr et al. points out that features in the stellar-mass black hole population break the mass-redshift degeneracy, facilitating precise determination of the Hubble parameter without electromagnetic counterparts or host galaxy catalogs. Using a hierarchical Bayesian inference model, we show that with one year of observations by the Einstein Telescope, the Hubble constant will be measured to ≲1%. We also show that this method can be used to perform Bayesian model selection between cosmological models. As an illustrative example, we find that a decisive statement can be made comparing the ΛCDM and RHCT cosmological models using two weeks of data from the Einstein Telescope.
You, Zhi Qiang
af0e4679-4f82-4164-9fb2-dc390cdd1fc8
Zhu, Xing Jiang
e3acbe8f-e553-4118-b4f8-a49ef2808d40
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Thrane, Eric
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Zhu, Zong Hong
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25 February 2021
You, Zhi Qiang
af0e4679-4f82-4164-9fb2-dc390cdd1fc8
Zhu, Xing Jiang
e3acbe8f-e553-4118-b4f8-a49ef2808d40
Ashton, Gregory
a8cec4b1-3c98-4b28-af2a-1e37cb3b9f2a
Thrane, Eric
2bafe758-0f64-458f-9f9a-fede9abc343c
Zhu, Zong Hong
a856211a-7ee2-463e-910e-761702235def
You, Zhi Qiang, Zhu, Xing Jiang, Ashton, Gregory, Thrane, Eric and Zhu, Zong Hong
(2021)
Standard-siren cosmology using gravitational waves from binary black holes.
Astrophysical Journal, 908 (2), [215].
(doi:10.3847/1538-4357/abd4d4).
Abstract
Gravitational-wave astronomy provides a unique new way to study the expansion history of the universe. In this work, we investigate the impact future gravitational-wave observatories will have on cosmology. Third-generation observatories like the Einstein Telescope and Cosmic Explorer will be sensitive to essentially all of the binary black hole coalescence events in the universe. Recent work by Farr et al. points out that features in the stellar-mass black hole population break the mass-redshift degeneracy, facilitating precise determination of the Hubble parameter without electromagnetic counterparts or host galaxy catalogs. Using a hierarchical Bayesian inference model, we show that with one year of observations by the Einstein Telescope, the Hubble constant will be measured to ≲1%. We also show that this method can be used to perform Bayesian model selection between cosmological models. As an illustrative example, we find that a decisive statement can be made comparing the ΛCDM and RHCT cosmological models using two weeks of data from the Einstein Telescope.
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Accepted/In Press date: 14 December 2020
Published date: 25 February 2021
Identifiers
Local EPrints ID: 508309
URI: http://eprints.soton.ac.uk/id/eprint/508309
ISSN: 0004-637X
PURE UUID: d3a86df0-a7ba-49e5-9097-824d8ad10ac6
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Date deposited: 16 Jan 2026 17:42
Last modified: 17 Jan 2026 03:47
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Author:
Zhi Qiang You
Author:
Xing Jiang Zhu
Author:
Gregory Ashton
Author:
Eric Thrane
Author:
Zong Hong Zhu
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