Characterisation of low radioactivity SiPMs and sensitivity studies for future LAr direct dark matter detection experiments

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Title
Characterisation of low radioactivity SiPMs and sensitivity studies for future LAr direct dark matter detection experiments

CoPED ID
bfe6511f-3b46-4dd8-96b8-4ef5fbfcc41c

Status
Active

Funder

Value
No funds listed.

Start Date
Aug. 31, 2021

End Date
Feb. 28, 2025

Description

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Silicon Photomultiplier (SiPM) technology has advanced in recent years with better photon detection efficiency, low power consumption, single-photon sensitivity, compactness, robustness, high precision position, and time resolution. The recent advancement has shown SIPMs as an alternative to the traditionally used photomultiplier tube in detecting scintillation light in noble gas detectors. To fully benefit from the excellent performance of SiPM technology, it is necessary to understand and simulate the features concerned with their operation.
This project aims to characterise the performance of cutting-edge silicon photosensors produced for the DarkSide-20k direct dark matter detection experiment through study of features such as the dark count rate, cross talk, after pulsing, gain, time resolution, Sound to noise ratio (SNR), and breakdown voltage. The performance characteristics of the sensors measured in Manchester will be used to inform an updated simulation of the response of the DarkSide detector to dark matter interactions and inform data analysis optimisation and estimates of the ultimate dark matter sensitivity of the experiment when data-taking begins.
These studies will also be used to inform R&D toward the design of future quantum sensors for future experiments requiring the use of high efficiency low radioactivity large-area photosensor arrays operating with photon signals in the vacuum ultraviolet range.

Darren Price SUPER_PER
Conner Roberts STUDENT_PER

Subjects by relevance
  1. Silicone
  2. Measurement
  3. Simulation
  4. Detectors
  5. Photons
  6. Optimisation
  7. Dark matter

Extracted key phrases
  1. Future lar direct dark matter detection experiment
  2. DarkSide-20k direct dark matter detection experiment
  3. Ultimate dark matter sensitivity
  4. High efficiency low radioactivity large
  5. Low radioactivity SiPMs
  6. Dark matter interaction
  7. Well photon detection efficiency
  8. Future experiment
  9. Sensitivity study
  10. Low power consumption
  11. Photon sensitivity
  12. Future quantum sensor
  13. Dark count rate
  14. Characterisation
  15. SiPM technology

Related Pages

UKRI project entry

UK Project Locations