Precision Cosmological Constraints on Atomic Dark Matter
Abstract
Atomic dark matter is a simple but highly theoretically motivated possibility for an interacting dark sector that could constitute some or all of dark matter. We perform a comprehensive study of precision cosmological observables on minimal atomic dark matter, exploring for the first time the full parameter space of dark QED coupling and dark electron and proton masses as well as the two cosmological parameters of aDM mass fraction and temperature ratio at time of SM recombination. We also show how aDM can accommodate the tension from late-time measurements, leading to a better fit than CDM or CDM + dark radiation. Furthermore, including late-time measurements leads to closed contours of preferred and dark hydrogen binding energy. The dark proton mass is seemingly unconstrained. Our results serve as an important new jumping-off point for future precision studies of atomic dark matter at non-linear and smaller scales.
Cite
@article{arxiv.2212.02487,
title = {Precision Cosmological Constraints on Atomic Dark Matter},
author = {Saurabh Bansal and Jared Barron and David Curtin and Yuhsin Tsai},
journal= {arXiv preprint arXiv:2212.02487},
year = {2023}
}
Comments
29 pages + references, 2 tables, 13 figures v2: Significant improvements and further performed checks for public CLASS-aDM code to increase reliability across aDM parameter space. Reran all scans, used newer KiDS-1000 measurement of S_8, no significant change to main results or conclusions, but added plot showing preferred DeltaNeff and dark binding energy