Probing low-mass dark matter from sub-MeV to sub-GeV with germanium-based quantum phononic spectroscopy

Abstract

We present a germanium phonon-to-charge transducer that integrates a slow-phonon phononic-crystal (PnC) region with radio-frequency quantum point-contact (RF-QPC) readout at 4 K, and we evaluate its dark-sector reach. A calibrated signal-collection model, which combines geometric guiding, propagation survival, and multiplicity-assisted primary-phonon detection, provides selection-corrected thresholds in the 10-3-10-2~eV range and a background model informed by nanosecond timing gates and GHz-band power-spectral-density windows. Under standard halo assumptions, a 100 g module achieves projected sensitivity to DM-electron and DM-nucleon scattering at recoil energies below 10-2~eV, probing cross sections below 10-43\,cm2 for m ∈ [0.01,100]~MeV/c2 (with efficiencies and thresholds folded in). We present sensitivities for both heavy-mediator (F DM=1) and light-mediator (F DM 1/q2) benchmarks, quantify dominant systematics (threshold, phonon quality factor Q, and bulk defect densities), and outline a staged program toward kg·yr exposures that begins to test models approaching the solar CE background.

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