Contact-less phonon detection with massive cryogenic absorbers

We have developed a contact-less technique for the real time measurement of a-thermal phonons in an absorber held at sub-Kelvin temperatures. In particular, a thin-film aluminium superconducting resonator was realized on a $30$~g high-resistivity silicon crystal. The lumped-element resonator is inductively excited/read-out by a radio-frequency micro-strip feed-line deposited on another wafer; the sensor is read-out without any physical contact or wiring to the absorber. To our knowledge, this is the first time a Kinetic Inductance Detector (KID), with the read-out/excitation line on a separate substrate, has been used to measure a-thermal phonons. The resonator demonstrates excellent electrical properties, particularly in terms of its internal quality factor. The detection of alphas, gammas and cosmic muons in the massive absorber is achieved, with an energy resolution of about 1.4keV, which is already interesting for particle physics applications. The resolution of this prototype detector is mainly limited by the low (around 0.3%) conversion efficiency of deposited energy to superconducting excitations (quasi-particles). The demonstrated technique can be further optimized, and used to produce large arrays of a-thermal phonon detectors, for use in rare events searches such as: dark matter direct detection, neutrino-less double beta decay, or coherent elastic neutrino-nucleus scattering.