Temperature evolution in the Early Universe and freeze-in at stronger coupling

Catarina Cosme; Francesco Costa; Oleg Lebedev

doi:10.1088/1475-7516/2024/06/031

Temperature evolution in the Early Universe and freeze-in at stronger coupling

Catarina Cosme, Francesco Costa, Oleg Lebedev

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

Abstract

Dark matter freeze-in at stronger coupling is operative when the Standard Model (SM) bath temperature never exceeds the dark matter mass. An attractive feature of this scenario is that it can be probed by direct detection experiments as well as at the LHC. In this work, we show how the mechanism can be realized in a simple UV complete framework, emphasizing the role of the maximal temperature of the SM thermal bath. We demonstrate that the maximal temperature can coincide with the reheating temperature or be close to it such that dark matter production is always Boltzmann-suppressed. This possibility is realized, for example, if the inflaton decays primarily into feebly interacting right-handed neutrinos, which subsequently generate the SM thermal bath. In this case, the SM sector temperature remains constant over cosmological times prior to reheating.

Original language	English
Article number	031
Journal	Journal of Cosmology and Astroparticle Physics
Volume	2024
Issue number	6
Number of pages	16
ISSN	1475-7516
DOIs	https://doi.org/10.1088/1475-7516/2024/06/031
Publication status	Published - 13 Jun 2024
MoE publication type	A1 Journal article-refereed

Fields of Science

dark matter theory
particle physics - cosmology connection
physics of the early universe
114 Physical sciences

Access to Document

10.1088/1475-7516/2024/06/031Licence: CC BY

Cosme_2024_J._Cosmol._Astropart._Phys._2024_031Final published version, 868 KBLicence: CC BY

Cite this

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AU - Costa, Francesco

AU - Lebedev, Oleg

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AB - Dark matter freeze-in at stronger coupling is operative when the Standard Model (SM) bath temperature never exceeds the dark matter mass. An attractive feature of this scenario is that it can be probed by direct detection experiments as well as at the LHC. In this work, we show how the mechanism can be realized in a simple UV complete framework, emphasizing the role of the maximal temperature of the SM thermal bath. We demonstrate that the maximal temperature can coincide with the reheating temperature or be close to it such that dark matter production is always Boltzmann-suppressed. This possibility is realized, for example, if the inflaton decays primarily into feebly interacting right-handed neutrinos, which subsequently generate the SM thermal bath. In this case, the SM sector temperature remains constant over cosmological times prior to reheating.

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KW - particle physics - cosmology connection

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