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Spin Precession Experiments for Light Axionic Dark Matter

High Energy Physics - Phenomenology 2018-04-30 v2 Cosmology and Nongalactic Astrophysics High Energy Physics - Experiment Atomic Physics

Abstract

Axion-like particles are promising candidates to make up the dark matter of the universe, but it is challenging to design experiments that can detect them over their entire allowed mass range. Dark matter in general, and in particular axion-like particles and hidden photons, can be as light as roughly 1022  eV10^{-22} \;\rm{eV} (108  Hz\sim 10^{-8} \;\rm{Hz}), with astrophysical anomalies providing motivation for the lightest masses ("fuzzy dark matter"). We propose experimental techniques for direct detection of axion-like dark matter in the mass range from roughly 1013  eV10^{-13} \;\rm{eV} (102  Hz\sim 10^2 \;\rm{Hz}) down to the lowest possible masses. In this range, these axion-like particles act as a time-oscillating magnetic field coupling only to spin, inducing effects such as a time-oscillating torque and periodic variations in the spin-precession frequency with the frequency and direction set by fundamental physics. We show how these signals can be measured using existing experimental technology, including torsion pendulums, atomic magnetometers, and atom interferometry. These experiments demonstrate a strong discovery capability, with future iterations of these experiments capable of pushing several orders of magnitude past current astrophysical bounds.

Keywords

Cite

@article{arxiv.1709.07852,
  title  = {Spin Precession Experiments for Light Axionic Dark Matter},
  author = {Peter W. Graham and David E. Kaplan and Jeremy Mardon and Surjeet Rajendran and William A. Terrano and Lutz Trahms and Thomas Wilkason},
  journal= {arXiv preprint arXiv:1709.07852},
  year   = {2018}
}

Comments

19 pages, 4 figures

R2 v1 2026-06-22T21:52:10.597Z