Probing Cosmic Axions through Resonant Emission and Absorption in Atomic Systems with Superradiance

Abstract

The μeV-mass axion is one of the most promising candidates for cold dark matter, and remains to be a well-motivated solution to the CP problem of Quantum Chromodynamics (QCD) via the Peccei-Quinn mechanism. In this paper, we propose a novel method to detect the dark-matter axions in our galaxy via the resonant emission | e | g + γ + γ + a (or absorption a + | e | g + γ + γ) in an atomic system with superradiance, where | e and | g stand for the excited and ground energy levels of atoms, respectively. A similar process via | e | g + γ + a (or a + | e | g + γ) is also put forward to probe the axion-electron coupling. For the nominal experimental setup assuming a background-free environment, most of the parameter space for typical QCD axion models can be covered with parahydrogen molecules or ytterbium atoms. However, the background in a realistic experimental setup remains to be a major issue that needs to be solved in future studies. Searching for better atomic or molecular candidates may be required for a bigger signal-to-noise ratio.