Strongly interacting singlet scalar dark matter during reheating

TL;DR

This paper explores how non-standard cosmological histories can enable strongly interacting singlet scalar dark matter to achieve the observed relic abundance via 4-to-2 self-annihilations, overcoming previous constraints.

Contribution

It demonstrates that non-standard cosmologies can make the SIMP mechanism viable for scalar dark matter with perturbative couplings, unlike in standard radiation-dominated scenarios.

Findings

Non-standard cosmology alters freeze-out dynamics.

Viable parameter space with perturbative couplings identified.

Compatibility with current and future experimental bounds.

Abstract

We revisit the singlet scalar dark matter model in the presence of a non-standard cosmological history prior to radiation domination. We focus on the regime in which the relic abundance is set by 4-to-2 self-annihilations while the dark and visible sectors remain in kinetic equilibrium, i.e. the standard strongly interacting massive particle (SIMP) framework. In the conventional radiation-dominated cosmology, this realization is not viable, as it requires sub-MeV masses and large quartic couplings in tension with bounds on dark matter self-interactions. We show that this conclusion is significantly modified if freeze-out occurs during non-standard cosmological eras. The altered Hubble expansion rate and the possible non-conservation of the standard model entropy change the freeze-out dynamics, allowing the observed relic density to be achieved with perturbative couplings and consistent with astrophysical constraints. We determine the region where SIMP production dominates over the WIMP mechanism and confront the viable parameter space with current and future direct detection and collider bounds.