Phonon-Mediated KIDs as Light Detectors for Rare-Event Search: The CALDER Project

Cruciani, A.; Bellini, F.; Cardani, L.; Casali, N.; Castellano, M. G.; Colantoni, I.; Coppolecchia, A.; Cosmelli, C.; D’Addabbo, A.; DI DOMIZIO, Sergio; Martinez, M.; Tomei, C.; Vignati, M.

doi:10.1007/s10909-016-1574-0

Background suppression plays a crucial role in experiments searching for rare events, like neutrino-less double beta decay (0νDBD) and dark matter. Large mass bolometers that are among the most competitive devices in this field would largely benefit from the development of ultrasensitive light detectors, as the combined readout of the bolometric and light signals enables the particle identification. The CALDER collaboration is developing cryogenic light detectors that will match the requirements of next generation experiments: noise lower than 20Â eV RMS, large active area (several cm2), wide temperature range of operation, and ease in fabricating and operating a thousand of detectors. For this purpose, we are exploiting the excellent energy resolution and the natural multiplexed read-out provided by kinetic inductance detectors (KIDs). These devices can be operated in a phonon-mediated approach, in which KIDs are coupled to a large insulating substrate in order to increase the active surface from a few mm2 to 25 cm2. Our current best prototype, based on aluminum LEKIDs, reached a baseline sensitivity of 80Â eV with an overall efficiency of about 20Â %.

Phonon-Mediated KIDs as Light Detectors for Rare-Event Search: The CALDER Project

Cruciani, A.;Bellini, F.;Cardani, L.;Casali, N.;Castellano, M. G.;Colantoni, I.;Coppolecchia, A.;Cosmelli, C.;D’Addabbo, A.;DI DOMIZIO, SERGIO;Martinez, M.;Tomei, C.;Vignati, M.

2016-01-01

Abstract

Background suppression plays a crucial role in experiments searching for rare events, like neutrino-less double beta decay (0νDBD) and dark matter. Large mass bolometers that are among the most competitive devices in this field would largely benefit from the development of ultrasensitive light detectors, as the combined readout of the bolometric and light signals enables the particle identification. The CALDER collaboration is developing cryogenic light detectors that will match the requirements of next generation experiments: noise lower than 20Â eV RMS, large active area (several cm2), wide temperature range of operation, and ease in fabricating and operating a thousand of detectors. For this purpose, we are exploiting the excellent energy resolution and the natural multiplexed read-out provided by kinetic inductance detectors (KIDs). These devices can be operated in a phonon-mediated approach, in which KIDs are coupled to a large insulating substrate in order to increase the active surface from a few mm2 to 25 cm2. Our current best prototype, based on aluminum LEKIDs, reached a baseline sensitivity of 80Â eV with an overall efficiency of about 20Â %.