Dark matter freeze-in from non-equilibrium QFT: towards a consistent treatment of thermal effects

We study thermal corrections to a model of real scalar dark matter interacting feebly with a SM fermion and a gauge-charged vector-like fermion. We employ the Closed-Time-Path (CTP) formalism for our calculation and go beyond previous works by including the full dependence on the relevant mass scales as opposed to using (non)relativistic approximations. In particular, we use 1PI-resummed propagators without relying on the Hard-Thermal-Loop approximation. We conduct our analysis at leading order in the loop expansion of the 2PI effective action and compare our findings to commonly used approximation schemes, including the aforementioned Hard-Thermal-Loop approximation and results obtained from solving Boltzmann equations using thermal masses as a regulator for $t$-channel divergences. We find that the Boltzmann approach deviates between $-10\%$ and $+30\%$ from our calculation, where the size and sign strongly depends on the mass splitting between the DM candidate and the gauge-charged parent. The HTL-approximated result is more precise for small gauge couplings and is percent level accurate for large mass splittings, whereas it overestimates the relic density up to $25 \%$ for small mass splittings. Tree-level propagators lead to underabundant DM as they do not account for scattering contributions and can deviate up to $-100\%$ from the 1PI-resummed result.