QCD Axion Dark Matter in the Dark Dimension
Abstract
The recently proposed dark dimension scenario reveals that axions can be localized on the Standard Model brane, thereby predicting the quantum chromodynamics (QCD) axion decay constant from the Weak Gravity Conjecture: fa M5 109-1010\, GeV, where M5 is the five-dimensional Planck mass. When combined with observational lower bounds, this implies that fa falls within a narrow range fa 109-1010\, GeV, corresponding to the axion mass ma 10-3-10-2\, eV. At this scale, the QCD axion constitutes a minor fraction of the total cold dark matter (DM) density 10-3-10-2. In this work, we investigate the issue of QCD axion DM within the context of the dark dimension and demonstrate that the QCD axion in this scenario can account for the entire DM abundance through a simple two-axion mixing mechanism. Specifically, we consider the resonant conversion of an axion-like particle (ALP) into the QCD axion. We find that, in a scenario where the ALP possesses a mass of approximately mA 10-5 \, eV and a decay constant of fA 1011 \, GeV, the QCD axion in the dark dimension can account for the overall DM. The ALP required within this specific range may originate from the grand unification of gauge forces in the dark dimension.
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