English

Atom Interferometer Tests of Dark Matter

High Energy Physics - Phenomenology 2024-09-09 v4 Cosmology and Nongalactic Astrophysics Quantum Physics

Abstract

Direct detection experiments for dark matter are increasingly ruling out large parameter spaces. However, light dark matter models with particle masses << GeV are still largely unconstrained. Here we examine a proposal to use atom interferometers to detect a light dark matter subcomponent at sub-GeV masses. We describe the decoherence and phase shifts caused by dark matter scattering off of one "arm" of an atom interferometer using a generalized dark matter direct detection framework. This allows us to consider multiple channels: nuclear recoils, hidden photon processes, and axion interactions. We apply this framework to several proposed atom interferometer experiments. Because atom interferometers are sensitive to extremely low momentum deposition and their coherent atoms may give them a boost in sensitivity, these experiments will be highly competitive and complementary to other direct detection methods. In particular, atom interferometers are uniquely able to probe a dark matter sub-component with mχ10 keVm_\chi \lesssim 10~\rm{keV}. We find that, for a mediator mass mϕ=105mχm_\phi=10^{-5}m_\chi, future atom interferometers could close a gap in the existing constraints on nuclear recoils down to σˉn1042 cm2\bar{\sigma}_n \sim 10^{-42}~\rm{cm}^2 for mχ105101 MeVm_\chi \sim 10^{-5} - 10^{-1}~\rm{MeV} dark matter masses.

Keywords

Cite

@article{arxiv.2205.13546,
  title  = {Atom Interferometer Tests of Dark Matter},
  author = {Yufeng Du and Clara Murgui and Kris Pardo and Yikun Wang and Kathryn M. Zurek},
  journal= {arXiv preprint arXiv:2205.13546},
  year   = {2024}
}

Comments

26 pages, 5 figures; v4: changes to decoherence observable

R2 v1 2026-06-24T11:30:00.568Z