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000602205 1112_ $$a13th International "Hiroshima" Symposium on the Development and Application of Semiconductor Tracking Detectors$$cVancouver$$d2023-12-03 - 2023-12-08$$gHSTD13$$wCanada
000602205 245__ $$aThe DESY digital silicon photomultiplier: Device characteristics and first test-beam results
000602205 260__ $$aAmsterdam$$bNorth-Holland Publ. Co.$$c2024
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000602205 500__ $$aCC BY 4.0 Deed, Received 13 February 2024, Revised 27 March 2024, Accepted 3 April 2024, Available online 5 April 2024, Version of Record 13 April 2024.
000602205 520__ $$aSilicon Photomultipliers (SiPMs) are state-of-the-art photon detectors used in particle physics, medical imaging, and beyond. They are sensitive to individual photons in the optical wavelength regime and achieve time resolutions of a few tens of picoseconds, which makes them interesting candidates for timing detectors in tracking systems for particle physics experiments. The Geiger discharges triggered in the sensitive elements of a SiPM, Single-Photon Avalanche Diodes (SPADs), yield signal amplitudes independent of the energy deposited by a photon or ionizing particle. This intrinsically digital nature of the signal motivates its digitization already on SPAD level. A digital SiPM (dSiPM) was designed at Deutsches Elektronen Synchrotron (DESY), combining a SPAD array with embedded CMOS circuitry for on-chip signal processing. A key feature of the DESY dSiPM is its capability to provide hit-position information on pixel level, and one hit time stamp per quadrant at a 3 MHz readout-frame rate. The pixels comprise four SPADs and have a pitch of about 70 μm. The four time stamps are provided by 12 bit Time-to-Digital Converters (TDCs) with a resolution better than 100 ps. The chip was characterized in the laboratory to determine dark count rate, breakdown voltage, and TDC characteristics. Test-beam measurements are analyzed to assess the DESY dSiPMs performance in the context of a 4D-tracking applications. The results demonstrate a spatial hit resolution on a pixel level, a minimum-ionizing particle detection efficiency of about 30 % and a time resolution in the order of 50 ps.
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