Litcius/Paper detail

Detecting axion dark matter with Rydberg atoms via induced electric dipole transitions

Georg Engelhardt, Amit Bhoonah, W. Vincent Liu

2024Physical Review Research14 citationsDOIOpen Access PDF

Abstract

Long-standing efforts to detect axions are driven by two compelling prospects, naturally accounting for the absence of charge-conjugation and parity symmetry breaking in quantum chromodynamics, and for the elusive dark matter at ultralight mass scale. Many experiments use advanced cavity resonator setups to probe the magnetic-field-mediated conversion of axions to photons. Here, we show how to search for axion matter without relying on such a cavity setup, which opens a new path for the detection of ultralight axions, where cavity-based setups are infeasible. When applied to Rydberg atoms, which feature particularly large transition dipole elements, this effect promises an outstanding sensitivity for detecting ultralight dark matter. Our estimates show that it can provide laboratory constraints in parameter space that so far have only been probed astrophysically, and cover new unprobed regions of the parameter space. The Rydberg atomic gases offer a flexible and inexpensive experimental platform that can operate at room temperature. We project the sensitivity by quantizing the axion-modified Maxwell equations to accurately describe atoms and molecules as quantum sensors wherever axion dark matter is present. Published by the American Physical Society 2024

Topics & Concepts

Rydberg atomAxionDark matterPhysicsDipoleElectric dipole transitionAtomic physicsRydberg formulaMagnetic dipoleAstrophysicsIonQuantum mechanicsIonizationDark Matter and Cosmic PhenomenaAtomic and Subatomic Physics ResearchCold Atom Physics and Bose-Einstein Condensates