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Auteurs principaux: Batell, Brian, Yin, Wen
Format: Preprint
Publié: 2024
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Accès en ligne:https://arxiv.org/abs/2406.17028
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author Batell, Brian
Yin, Wen
author_facet Batell, Brian
Yin, Wen
contents Why does dark matter (DM) live longer than the age of the Universe? Here we study a novel sub-eV scalar DM candidate whose stability is due to the Pauli exclusion of its fermionic decay products. We analyze the stability of the DM condensate against decays, scatterings (i.e., evaporation), and parametric resonance, delineating the viable parameter regions in which DM is cosmologically stable. In a minimal scenario in which the scalar DM decays to a pair of new exotic fermions, we find that scattering can populate an interacting thermal dark sector component to energies far above the DM mass. This self-interacting dark radiation may potentially alleviate the Hubble tensions. Furthermore, our scenario can be probed through precise measurements of the halo mass function or the masses of dwarf spheroidal galaxies since scattering prevents the DM from becoming too dense. On the other hand, if the lightest neutrino stabilizes the DM, the cosmic neutrino background (C$ν$B) can be significantly altered from the $Λ$CDM prediction and thus be probed in the future by C$ν$B detection experiments.
format Preprint
id arxiv_https___arxiv_org_abs_2406_17028
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Cosmic Stability of Dark Matter from Pauli Blocking
Batell, Brian
Yin, Wen
High Energy Physics - Phenomenology
Why does dark matter (DM) live longer than the age of the Universe? Here we study a novel sub-eV scalar DM candidate whose stability is due to the Pauli exclusion of its fermionic decay products. We analyze the stability of the DM condensate against decays, scatterings (i.e., evaporation), and parametric resonance, delineating the viable parameter regions in which DM is cosmologically stable. In a minimal scenario in which the scalar DM decays to a pair of new exotic fermions, we find that scattering can populate an interacting thermal dark sector component to energies far above the DM mass. This self-interacting dark radiation may potentially alleviate the Hubble tensions. Furthermore, our scenario can be probed through precise measurements of the halo mass function or the masses of dwarf spheroidal galaxies since scattering prevents the DM from becoming too dense. On the other hand, if the lightest neutrino stabilizes the DM, the cosmic neutrino background (C$ν$B) can be significantly altered from the $Λ$CDM prediction and thus be probed in the future by C$ν$B detection experiments.
title Cosmic Stability of Dark Matter from Pauli Blocking
topic High Energy Physics - Phenomenology
url https://arxiv.org/abs/2406.17028