Asteroids for ultralight dark-photon dark-matter detection

Abstract

Gravitational-wave (GW) detectors that monitor fluctuations in the separation between inertial test masses (TMs) are sensitive to new forces acting on those TMs. Ultralight dark-photon dark matter (DPDM) coupled to U(1)B or U(1)B-L charges supplies one such force that oscillates with a frequency set by the DPDM mass. GW detectors operating in different frequency bands are thus sensitive to different DPDM mass ranges. A recent GW detection proposal based on monitoring the separation of certain asteroids in the inner Solar System would have sensitivity to μHz frequencies [arXiv:2112.11431]. In this paper, we show how that proposal would also enable access to new parameter space for DPDM coupled to B [respectively, B-L] charges in the mass range 5\ [9] × 10-21 eV mDM 2 × 10-19 eV, with peak sensitivities about a factor of 500 [50] beyond current best limits on B [B-L] at mDM 2 × 10-19 eV. Sensitivity could be extended up to mDM 2 × 10-18 eV only if noise issues associated with asteroid rotational motion could be overcome.