Axion Dark Matter Detection with Cold Molecules

TL;DR

This paper proposes a novel experimental approach using cold molecules to detect QCD axion dark matter in high decay constant regions, leveraging time-varying nuclear moments and energy shifts in molecular systems.

Contribution

It introduces a new method to search for axion dark matter via molecular energy shifts caused by oscillating nuclear moments, extending detection capabilities to higher axion decay constants.

Findings

Potential detection of energy shifts ~10^-24 eV in molecules.

Method sensitive to axion decay constants >10^15 GeV.

Feasible with current or near-future molecular clock technology.

Abstract

Current techniques cannot detect axion dark matter over much of its parameter space, particularly in the theoretically well-motivated region where the axion decay constant f_a lies near the GUT and Planck scales. We suggest a novel experimental method to search for QCD axion dark matter in this region. The axion field oscillates at a frequency equal to its mass when it is a component of dark matter. These oscillations induce time varying CP-odd nuclear moments, such as electric dipole and Schiff moments. The coupling between internal atomic fields and these nuclear moments gives rise to time varying shifts to atomic energy levels. These effects can be enhanced by using elements with large Schiff moments such as the light Actinides, and states with large spontaneous parity violation, such as molecules in a background electric field. The energy level shift in such a molecule can be ~ 10^-24 eV or larger. While challenging, this energy shift may be observable in a molecular clock configuration with technology presently under development. The detectability of this energy shift is enhanced by the fact that it is a time varying shift whose oscillation frequency is set by fundamental physics and is therefore independent of the details of the experiment. This signal is most easily observed in the sub-MHz range, allowing detection when f_a is > 10^16 GeV, and possibly as low as 10^15 GeV. A discovery in such an experiment would not only reveal the nature of dark matter and confirm the axion as the solution to the strong CP problem, it would also provide a glimpse of physics at the highest energy scales, far beyond what can be directly probed in the laboratory.