Asymmetric Reheating of Dark QED

TL;DR

This paper explores asymmetric reheating in a dark QED model, analyzing how inflaton decay into visible and hidden sectors affects dark matter production, thermalization, and relic abundance.

Contribution

It introduces a new DM production mechanism, studies temperature ratios and initial asymmetries, and reassesses viable DM candidates considering thermalization constraints.

Findings

Discovered a new DM production mechanism involving annihilation during inflaton decay.

Analyzed the temperature ratio $ = T'/T$ and its relation to initial energy asymmetry.

Reevaluated the parameter space for viable DM candidates considering unitarity and thermalization constraints.

Abstract

We study in detail a scenario in which the inflaton scalar field couples to both a visible sector (VS) and a hidden sector (HS). The VS is assumed to contain the Standard Model (SM), while the HS contains a dark matter (DM) candidate. We are in particular interested in a scenario in which the inflaton decays dominantly into the HS degrees of freedom. The DM candidate is taken to be a dark Dirac fermion $\chi$, coupled to a massive dark photon $\gamma'$, a popular model for a HS also known as Dark QED. The inflaton decays into particles of both sectors generate an initial asymmetry between the SM and HS fermion abundances, which we model as being proportional to the ratio of effective Yukawa couplings, $y$ and $y'$. We pay particular attention to the process of thermalisation of the HS, with temperature $T'$, as a function of $y'$ and $\alpha'$, the HS fine structure constant. We investigate the several possible ways of producing the observed DM relic abundance, and their interplay with the reheating of the HS and the transfer of energy between the HS and the VS. Key results, beyond the systematic character of our analysis, include: a new mechanism for DM production, which occurs when DM particles annihilate while still being produced by the inflaton decay; a study of the temperature ratio $\xi = T'/T$ and its relation with the initial energy asymmetry between the HS and VS, as parameterized by $\xi_i = \sqrt{y'/y}$; a reassessment of the domain of viable DM candidates, taking into account the constraints set by unitarity and the thermalisation of the HS, accounting for the LPM effect; and, in cases where the HS does not reach thermal equilibrium, an analysis of how non-thermal DM production fits within the domain of thermal DM candidates.