When Freeze-out occurs due to a non-Boltzmann suppression: A study of degenerate dark sector

TL;DR

This paper explores a non-standard freeze-out mechanism for dark matter in a degenerate dark sector, analyzing how co-decaying dynamics and interactions influence relic density and observable signals, while evading current experimental bounds.

Contribution

It introduces a detailed study of co-decaying dark matter in a degenerate dark sector, solving coupled Boltzmann equations and analyzing observational signals.

Findings

Co-decaying dark matter can evade current neutrino and gamma-ray bounds.

Interactions in the dark sector influence temperature and relic density.

Degenerate scenarios are less constrained by existing observations.

Abstract

Exponential suppression or commonly known as the Boltzmann suppression in the number density of dark matter is the key ingredient for creating chemical imbalance prior to the usual thermal freeze-out. A degenerate/quasi-degenerate dark sector can experience a different exponential suppression in the number density analogous to the radioactive decay law leading to a delayed freeze-out mechanism of dark matter known as the co-decaying dark matter. In this work, we study the dynamics of a multicomponent dark matter from thermally decoupled degenerate dark sector in a hidden U$(1)_{X}$ extension of the Standard Model. We compute the relic density of dark matter frozen-out through the co-decaying mechanism by solving four coupled Boltzmann equations. We demonstrate how temperature $T^\prime $ of the dark sector changes due to all types of $3\rightarrow 2$ and $2\rightarrow 2$ interactions along with the eternal expansion of the Universe. We find that $3\rightarrow 2$ interactions enhance $T^\prime$ by producing energetic particles in the dark sector while the excess heat is transferred by $2\rightarrow 2$ interactions to the entire dark sector. As the direct detection is possible only through the feeble portal couplings, we investigate the neutrino and $\gamma$-ray signals from dark matter annihilation via one step cascade processes and compare our results with the measured fluxes of atmospheric neutrinos by Super-Kamiokande and diffuse $\gamma$-rays by Fermi-LAT, EGRET, INTEGRAL collaborations. We find that the present scenario easily evades all the existing bounds from atmospheric neutrino and diffuse $\gamma$-ray observations for degenerate dark sector. However, the constraints are significant for quasi degenerate scenario.