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Dark matter as a heavy thermal hot relic

Thomas Hambye, Matteo Lucca, Laurent Vanderheyden

2020Physics Letters B20 citationsDOIOpen Access PDF

Abstract

If, during the early Universe epoch, the dark matter particle thermalizes in a hidden sector which does not thermalize with the Standard Model thermal bath, its relativistic thermal decoupling can easily lead to the observed relic density, even if the dark matter particle mass is many orders of magnitude heavier than the usual ∼ eV hot relic mass scale. This straightforward scenario simply requires that the temperature of the hidden sector thermal bath is one to five orders of magnitude cooler than the temperature of the Standard Model thermal bath. In this way the resulting relic density turns out to be determined only by the dark matter mass scale and the ratio of the temperatures of both sectors. In a model independent way we determine that this can work for a dark matter mass all the way from ∼1 keV to ∼30 PeV. We also show how this scenario works explicitly in the framework of two illustrative models. One of them can lead to a PeV neutrino flux from dark matter decay of the order of the one needed to account for the high energy neutrinos observed by IceCube.

Topics & Concepts

PhysicsDark matterThermalisationNeutrinoHidden sectorThermalDecoupling (probability)Standard Model (mathematical formulation)Particle physicsHot dark matterLight dark matterWarm dark matterAstrophysicsDark energyScalar field dark matterCosmologyThermodynamicsControl engineeringArchaeologyEngineeringHistoryGauge (firearms)Dark Matter and Cosmic PhenomenaParticle physics theoretical and experimental studiesCosmology and Gravitation Theories
Dark matter as a heavy thermal hot relic | Litcius