Aspects of Gravitational Portals and Freeze-in during Reheating

TL;DR

This paper systematically studies freeze-in dark matter production during reheating, considering both gravitational and inflaton decay contributions, and identifies conditions where gravitational production dominates and matches observed relic density.

Contribution

It provides a comprehensive analysis of freeze-in during reheating, including gravitational portals and inflaton decay, with new constraints on parameters for various potentials and interactions.

Findings

Gravitationally-produced radiation bath can dominate freeze-in production.

Relic density matches observations if DM mass exceeds reheating temperature.

Constraints on BSM scale depend on DM mass, reheating temperature, and potential parameters.

Abstract

We conduct a systematic investigation of freeze-in during reheating while taking care to include both direct and indirect production of dark matter (DM) via gravitational portals and inflaton decay. Direct production of DM can occur via gravitational scattering of the inflaton, while indirect production occurs through scattering in the Standard Model radiation bath. We consider two main contributions to the radiation bath during reheating. The first, which may dominate at the onset of the reheating process, is produced via gravitational scattering of the inflaton. The second (and more standard contribution) comes from inflaton decay. We consider a broad class of DM production rates parameterized as $R_{\chi} \propto T^{n+6}/\Lambda^{n+2}$, and inflaton potentials with a power-law form $V(\phi) \propto \phi^{k}$ about the minimum. We find the relic density produced by freeze-in for each contribution to the Standard Model bath for arbitrary $k$ and $n$, and compare these with the DM density produced gravitationally by inflaton scattering. We find that freeze-in production from the gravitationally-produced radiation bath can exceed that of the conventional decay bath and account for the observed relic density provided that $m_{\chi} > T_{\rm RH}$, with additional $k$- and $n$-dependent constraints. For each freeze-in interaction considered, we also find $m_{\chi}$- and $T_{\rm RH}$-dependent limits on the BSM scale, $\Lambda$, for which gravitational production will exceed ordinary freeze-in production.