A unified study of nuclear physics and dark matter constraints through gravitational-wave observations of binary neutron star mergers
A unified study of nuclear physics and dark matter constraints through gravitational-wave observations of binary neutron star mergers
Understanding the properties of strongly interacting matter at extreme densities is a central problem in fundamental physics, but neutron star mergers provide a natural laboratory for probing this regime. However, the complexity of the merger process complicates the interpretation of the associated gravitational-wave and electromagnetic signals. This picture becomes even more complex in the potential scenario in which dark matter accumulates around and in neutron stars, altering their structure and the associated observables. In this work, we study synthetic gravitational-wave observations of binary neutron star mergers with next-generation detectors, investigating their potential to extract both nuclear physics and dark-matter constraints. We also examine how the potential presence of fermionic, non-interacting dark matter inside neutron stars affects the inference of nuclear empirical parameters. We find that combining observations can tighten constraints on nuclear empirical parameters. However, the inferred values remain sensitive to systematic modeling biases and intrinsic degeneracies among the parameters. Conversely, our analysis reveals that even in the presence of dark matter, it will be unlikely to find decisive evidence for dark matter when analyzing gravitational-wave signals. Consequently, systematic biases in nuclear empirical parameter inference potentially resulting from the presence of dark matter are expected to be negligible even for observations with next-generation gravitational-wave detectors.
astro-ph.HE, gr-qc
Kunert, Nina
f9d4fdbd-e867-4ef3-ae45-ba70f107f53f
Grams, Guilherme
580a7213-5670-4c18-87c8-b5ef7b652c0f
Newton, William
0d06cc27-4419-4157-ad59-5c008c1d9075
Giangrandi, Edoardo
c3fe36c1-e97c-45c7-974a-0fc3cb0b525f
Puecher, Anna
4d72776c-b895-41ea-8f1b-1980eb18dbb1
Koehn, Hauke
84bdf687-998d-4c59-8e22-6366fa6e123c
Sagun, Violetta
a3bf27d9-2d6f-41e6-85b2-8f69cd24c3a2
Dietrich, Tim
08a88c32-5baa-475f-bb18-f50f48fbe8f6
23 February 2026
Kunert, Nina
f9d4fdbd-e867-4ef3-ae45-ba70f107f53f
Grams, Guilherme
580a7213-5670-4c18-87c8-b5ef7b652c0f
Newton, William
0d06cc27-4419-4157-ad59-5c008c1d9075
Giangrandi, Edoardo
c3fe36c1-e97c-45c7-974a-0fc3cb0b525f
Puecher, Anna
4d72776c-b895-41ea-8f1b-1980eb18dbb1
Koehn, Hauke
84bdf687-998d-4c59-8e22-6366fa6e123c
Sagun, Violetta
a3bf27d9-2d6f-41e6-85b2-8f69cd24c3a2
Dietrich, Tim
08a88c32-5baa-475f-bb18-f50f48fbe8f6
[Unknown type: UNSPECIFIED]
Abstract
Understanding the properties of strongly interacting matter at extreme densities is a central problem in fundamental physics, but neutron star mergers provide a natural laboratory for probing this regime. However, the complexity of the merger process complicates the interpretation of the associated gravitational-wave and electromagnetic signals. This picture becomes even more complex in the potential scenario in which dark matter accumulates around and in neutron stars, altering their structure and the associated observables. In this work, we study synthetic gravitational-wave observations of binary neutron star mergers with next-generation detectors, investigating their potential to extract both nuclear physics and dark-matter constraints. We also examine how the potential presence of fermionic, non-interacting dark matter inside neutron stars affects the inference of nuclear empirical parameters. We find that combining observations can tighten constraints on nuclear empirical parameters. However, the inferred values remain sensitive to systematic modeling biases and intrinsic degeneracies among the parameters. Conversely, our analysis reveals that even in the presence of dark matter, it will be unlikely to find decisive evidence for dark matter when analyzing gravitational-wave signals. Consequently, systematic biases in nuclear empirical parameter inference potentially resulting from the presence of dark matter are expected to be negligible even for observations with next-generation gravitational-wave detectors.
Text
2602.19627v1
- Author's Original
More information
Published date: 23 February 2026
Keywords:
astro-ph.HE, gr-qc
Identifiers
Local EPrints ID: 510946
URI: http://eprints.soton.ac.uk/id/eprint/510946
PURE UUID: ba2c9ad1-287d-44aa-9639-90727cbbc7d1
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Date deposited: 27 Apr 2026 16:48
Last modified: 28 Apr 2026 02:23
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Contributors
Author:
Nina Kunert
Author:
Guilherme Grams
Author:
William Newton
Author:
Edoardo Giangrandi
Author:
Anna Puecher
Author:
Hauke Koehn
Author:
Violetta Sagun
Author:
Tim Dietrich
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