UV complete framework of freeze-in massive particle dark matter

Abstract

We propose a way to generate tiny couplings of freeze-in massive particle dark matter with the standard model particles dynamically by considering an extension of the electroweak gauge symmetry. The dark matter is considered to be a singlet under this extended gauge symmetry which we have assumed to be the one in a very widely studied scenario called left-right symmetric model. Several heavy particles, that can be thermally inaccessible in the early Universe due to their masses being greater than the reheat temperature after inflation, can play the role of portals between dark matter and standard model particles through one loop couplings. Due to the loop suppression, one can generate the required nonthermal dark matter couplings without any need of highly fine tuned Yukawa couplings beyond that of electron Yukawa with the standard model like Higgs boson. We show that generic values of Yukawa couplings as large as O(0.01) to O(1) can keep the dark matter out of thermal equilibrium in the early Universe and produce the correct relic abundance later through the freeze-in mechanism. Though the radiative couplings of dark matter are tiny as required by the freeze-in scenario, the associated rich particle sector of the model can be probed at ongoing and near future experiments. The allowed values of dark matter mass can remain in a wide range from keV to TeV order keeping the possibilities of warm and cold dark matter equally possible.