Impact of embedded 163 Ho on the performance of the transition-edge sensor microcalorimeters of the HOLMES experiment.
Douglas Bennett, Matteo Borghesi, Pietro Campana, Rodolfo Carobene, Giancarlo Ceruti, Matteo De Gerone, Marco Faverzani, Lorenzo Ferrari Barusso, Elena Ferri, Joseph Fowler, Sara Gamba, Flavio Gatti, Andrea Giachero, Marco Gobbo, Danilo Labranca
Abstract
Open AccessWe present a detailed investigation of the performance of transition-edge sensor (TES) microcalorimeters with 163 Ho atoms embedded by ion implantation, as part of the HOLMES experiment aimed at neutrino mass determination. The inclusion of 163 Ho atoms introduces an excess heat capacity due to a pronounced Schottky anomaly, which can affect the detector's energy resolution, signal height, and response time. We fabricated TES arrays with varying levels of 163 Ho activity and characterized their performance in terms of energy resolution, decay time constants, and heat capacity. The intrinsic energy resolution was found to degrade with increasing 163 Ho activity, consistent with the expected scaling of heat capacity. From the analysis, we determined the specific heat capacity of 163 Ho to be ( 2.9 ± 0.4 ( stat ) ± 0.7 ( sys ) ) J/K/mol at ( 94 ± 1 ) mK, close to the literature values for metallic holmium. No additional long decay time constants correlated with 163 Ho activity were observed, indicating that the excess heat capacity does not introduce weakly coupled thermodynamic systems. These results suggest that our present TES microcalorimeters can tolerate 163 Ho activities up to approximately 5 Bq, with only about a factor of three degradation in performance compared to detectors without 163 Ho. For higher activities, reducing the TES transition temperature is necessary to maintain or improve the energy resolution. These findings provide critical insights for optimizing TES microcalorimeters for future neutrino mass experiments and other applications requiring embedded radioactive sources. The study also highlights the robustness of TES technology in handling limited amounts of implanted radionuclides while maintaining high-resolution performance.