Purpose <p>Water Cherenkov detectors play a fundamental role in neutrino physics and cosmic-ray research. The water attenuation length (WAL, also called water transparency) is the parameter serving as an indicator of water quality within the detector. This paper presents the design, implementation, and performance of a dedicated monitoring system developed to measure the WAL <i>in situ</i> in the water Cherenkov (Veto) detector of the Jiangmen Underground Neutrino Observatory (JUNO).</p> Method <p>The system incorporates five 20-inch PMTs with light guides, a stable LED light source and a calibration LED light source with optical fibers, and deployed at the bottom of the JUNO water pool.</p> Result <p>The system provides the capability to continuously monitor water transparency throughout the water filling and commissioning phases in JUNO. Long-term monitoring data demonstrate a systematic improvement in water quality. The measured WAL increased from an initial value of 23&#xa0;m at the beginning of filling operations to a stable value of about 60&#xa0;m during detector commissioning. With the ongoing operation of the water purification and recirculation system, the attenuation length has further improved, currently reaching about 75&#xa0;m.</p> Conclusion <p>The system operates stably, monitor detector performance and validating water circulation in JUNO water Cherenkov detector.</p>

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Water attenuation length measurement in JUNO

  • Chuanshi Dong,
  • Jilei Xu,
  • Haoqi Lu,
  • Sibo Wang,
  • Vit Vorobel,
  • Tomas Tmej,
  • Changgen Yang,
  • Yongpeng Zhang,
  • Junyou Chen,
  • Hongzhao Yu,
  • Junwei Zhang

摘要

Purpose

Water Cherenkov detectors play a fundamental role in neutrino physics and cosmic-ray research. The water attenuation length (WAL, also called water transparency) is the parameter serving as an indicator of water quality within the detector. This paper presents the design, implementation, and performance of a dedicated monitoring system developed to measure the WAL in situ in the water Cherenkov (Veto) detector of the Jiangmen Underground Neutrino Observatory (JUNO).

Method

The system incorporates five 20-inch PMTs with light guides, a stable LED light source and a calibration LED light source with optical fibers, and deployed at the bottom of the JUNO water pool.

Result

The system provides the capability to continuously monitor water transparency throughout the water filling and commissioning phases in JUNO. Long-term monitoring data demonstrate a systematic improvement in water quality. The measured WAL increased from an initial value of 23 m at the beginning of filling operations to a stable value of about 60 m during detector commissioning. With the ongoing operation of the water purification and recirculation system, the attenuation length has further improved, currently reaching about 75 m.

Conclusion

The system operates stably, monitor detector performance and validating water circulation in JUNO water Cherenkov detector.