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Main Authors: Blas, Diego, Gasparotto, Silvia, Vicente, Rodrigo
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2410.07330
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author Blas, Diego
Gasparotto, Silvia
Vicente, Rodrigo
author_facet Blas, Diego
Gasparotto, Silvia
Vicente, Rodrigo
contents Ultra-light bosons, naturally appearing in well-motivated extensions to the Standard Model, can constitute all the dark matter. Models with particle mass close to the smallest phenomenologically allowed exhibit coherent field configurations at (sub)galactic scales, oscillating at a frequency corresponding to the fundamental mass of the dark matter particle. The gravitational field of these structures inherits the dark matter field's coherent oscillations, leaving an imprint on gravitational (and electromagnetic) waves sourced close to (or in) such overdensities. This happens via a heterodyning frequency modulation, which can later be decoded in a gravitational-wave detector. An analogous effect occurs in models with universal (conformal) couplings of ultra-light bosons with ordinary matter, generated by the direct interaction with the oscillating field. In this work, we explore this phenomenon in detail and assess the capability of near-future interferometers to probe ultra-light dark matter and its potential conformal couplings to matter. Using astrophysical population models, together with results from cosmological simulations, we find that the observation of gravitational waves from spinning neutron stars at the Galactic Centre with the Einstein Telescope/Cosmic Explorer would be particularly effective in constraining ultra-light dark matter.
format Preprint
id arxiv_https___arxiv_org_abs_2410_07330
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Searching for ultra-light dark matter through frequency modulation of gravitational waves
Blas, Diego
Gasparotto, Silvia
Vicente, Rodrigo
High Energy Physics - Phenomenology
General Relativity and Quantum Cosmology
Ultra-light bosons, naturally appearing in well-motivated extensions to the Standard Model, can constitute all the dark matter. Models with particle mass close to the smallest phenomenologically allowed exhibit coherent field configurations at (sub)galactic scales, oscillating at a frequency corresponding to the fundamental mass of the dark matter particle. The gravitational field of these structures inherits the dark matter field's coherent oscillations, leaving an imprint on gravitational (and electromagnetic) waves sourced close to (or in) such overdensities. This happens via a heterodyning frequency modulation, which can later be decoded in a gravitational-wave detector. An analogous effect occurs in models with universal (conformal) couplings of ultra-light bosons with ordinary matter, generated by the direct interaction with the oscillating field. In this work, we explore this phenomenon in detail and assess the capability of near-future interferometers to probe ultra-light dark matter and its potential conformal couplings to matter. Using astrophysical population models, together with results from cosmological simulations, we find that the observation of gravitational waves from spinning neutron stars at the Galactic Centre with the Einstein Telescope/Cosmic Explorer would be particularly effective in constraining ultra-light dark matter.
title Searching for ultra-light dark matter through frequency modulation of gravitational waves
topic High Energy Physics - Phenomenology
General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2410.07330