Performance of photosensors in high rate environment for gas Cherenkov

The upcoming SoLID experiment at Jefferson Lab will push the envelope on luminosity for a large-acceptance detector, requiring the use of a light-gas Cherenkov detector for trigger-level event selection. Due to the high luminosity environment, the single-photon background rate in this Cherenkov is expected to be extremely high at the photon sensor. Thus, it is essential to validate the planned photosensors and readout electronics to determine the limits of these sensors and mitigate the risk of failure of the trigger-level event selection. We report the design of a small prototype telescopic Cherenkov device and a set of early studies in a high-rate environment in Hall C at Jefferson Lab. Commercially available multi-anode photomultipliers (MaPMT) and low-cost large-area picosecond photodetectors (LAPPD) were tested with the JLab FADC250 modules for the data acquisition to assess their performance in such an environment. The experiment results show that both a MaPMT array and an internal stripline LAPPD could detect the Cherenkov signals and separate single-electron events and pair production events. A GEANT4 simulation confirms the experimental performance of the prototype results through direct comparison. With higher quantum efficiency, the MaPMT array provided a better separation of the single-electron events and pair production events than the internal stripline LAPPD. The experiment also demonstrated that the MaPMT array with a summed readout of 16 pixels per MaPMT, the LAPPD with internal stripline readout, and the FADC250 modules performed successfully at a single-photon rate up to 60 $kHz/cm^{2}$.