Strongly self-interacting vector dark matter via freeze-in

We study a vector dark matter (VDM) model in which the dark sector couples to the Standard Model sector via a Higgs portal. If the portal coupling is small enough the VDM can be produced via the freeze-in mechanism. It turns out that the electroweak phase transition have a substantial impact on the...

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Bibliographic Details
Published in:arXiv.org 2017-11
Main Authors: Duch, Mateusz, Grzadkowski, Bohdan, Huang, Da
Format: Article
Language:English
Subjects:
Coupling
Dark matter
Higgs bosons
Phase transitions
Quarks
Universe
Online Access:Get full text
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Summary:We study a vector dark matter (VDM) model in which the dark sector couples to the Standard Model sector via a Higgs portal. If the portal coupling is small enough the VDM can be produced via the freeze-in mechanism. It turns out that the electroweak phase transition have a substantial impact on the prediction of the VDM relic density. We further assume that the dark Higgs boson which gives the VDM mass is so light that it can induce strong VDM self-interactions and solve the small-scale structure problems of the Universe. As illustrated by the latest LUX data, the extreme smallness of the Higgs portal coupling required by the freeze-in mechanism implies that the dark matter direct detection bounds are easily satisfied. However, the model is well constrained by the indirect detections of VDM from BBN, CMB, AMS-02, and diffuse \(\gamma\)/X-rays. Consequently, only when the dark Higgs boson mass is at most of \({\cal O}({\rm keV})\) does there exist a parameter region which leads to a right amount of VDM relic abundance and an appropriate VDM self-scattering while satisfying all other constraints simultaneously.
ISSN:2331-8422
DOI:10.48550/arxiv.1710.00320