First Results for the pLGAD Sensor for Low-Penetrating Particles Article Swipe

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Waleed Khalid , M. Valentan , Albert Doblas , D. Flores , S. Hidalgo , Gertrud Konrad , Johann Marton , Neil Moffat , Daniel Moser , Sebastian Onder , G. Pellegrini , Jairo Villegas ·

YOU? · · 2022 · Open Access · · DOI: https://doi.org/10.48550/arxiv.2207.06047 · OA: W4285483563

Silicon sensors are the go-to technology for high-precision sensors in particle physics. But only recently low-noise silicon sensors with internal amplification became available. The so-called Low Gain Avalanche Detector (LGAD) sensors have been developed for applications in High Energy Physics, but lack two characteristics needed for the measurement of low-energy protons (<60 keV): a thin entrance window (in the order of tens of nm) and the efficient amplification of signals created near the sensor's surface (in a depth below 1 um). In this paper we present the so-called proton Low Gain Avalanche Detector (pLGAD) sensor concept and some results from characterization of the first prototypes of the sensor. The pLGAD is specifically designed to detect low-energy protons, and other low-penetrating particles. It will have a higher detection efficiency than non-silicon technologies, and promises to be a lot cheaper and easier to operate than competing silicon technologies.