http://arxiv.org/abs/2212.02487
Atomic dark matter (aDM) 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 $(\alpha_{D}, m_{e_{D}}, m_{p_{D}})$ as well as the two cosmological parameters of aDM mass fraction $f_D$ and temperature ratio $\xi$ at time of SM recombination. We find that significant aDM mass fractions require the dark electron mass to obey an $\alpha_{D}$-dependent lower bound. We also show how aDM can accommodate the $(H_0, S_8)$ tension from late-time measurements, leading to a significantly better fit than $\Lambda$CDM or $\Lambda$CDM + dark radiation. Furthermore, including late-time measurements leads to strikingly tight constraints on the parameters of atomic dark matter. The dark QED coupling must obey an upper bound of $\alpha_{D} < 0.025$, the dark electron cannot be lighter than the SM electron, and $\Delta N_D, f_{D} \gtrsim 0.1$ are preferred. 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.
S. Bansal, J. Barron, D. Curtin, et. al.
Tue, 6 Dec 22
35/87
Comments: 27 pages + references, 2 tables, 11 figures
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