First measurements of remoTES cryogenic calorimeters: easy-to-fabricate particle detectors for a wide choice of target materials

Low-temperature calorimeters based on a readout via transition edge sensors (TESs) and operated below 100 mK are well suited for rare event searches. We present first experimental results from two detector prototypes using a novel thermometer design denoted remoTES. This design facilitates the use of TESs in combination with absorber materials which, due to their physical and chemical properties, as e.g. hygroscopicity, low hardness and low melting point, prevent the direct deposition of the TES onto their surface. In a remoTES detector, the TES is fabricated onto a separate wafer. The absorber crystal is then equipped with a gold pad that transmits the phonon signal created from an interaction in the absorber to the thermometer via a gold bonding wire. With recent prototype detectors operated in an above-ground R&D facility, we achieve energy resolutions of sigma=87.8 eV for a silicon absorber and $\sigma=193.5$ eV for an alpha-TeO$_{2}$ absorber, respectively. RemoTES calorimeters offer - besides the wider choice of absorber materials - a simpler production process combined with a higher reproducibility for large detector arrays and an enhanced radiopurity standard, which is of particular interest for rare event searches.