SiPM 及其在粒子和天体粒子物理学微光探测中的应用实例

Luigi Pio Rignanese, Pietro Antonioli, Preghenella Roberto, Scapparone Eugenio
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摘要

硅光电倍增管(SiPM)自 20 世纪 90 年代末问世以来,已成为实验物理学中的主要光子探测器。硅光电倍增管具有优于传统光电探测器的性能特点,其光子探测效率高达 60%,信号上升时间快,并能抵抗磁场。其固态结构可实现批量生产,结构紧凑,空间分辨率高,便于集成到各种实验装置中。虽然 SiPM 容易受到辐射损伤,但目前正在研究缓解策略,以使其即使在辐射水平较高的环境中也能可靠运行。SiPM 擅长探测低水平的光,因此非常适合涉及闪烁和切伦科夫光的应用。由于 SiPM 能够在低温环境下有效工作,因此可以建造新型多吨稀有事件搜索实验,如 Darkside-20k。对磁场的不敏感性和对辐射损伤的缓解使 SiPM 非常适合用于加速器驱动的物理学,例如未来电子离子对撞机(EIC)中用于粒子识别(PID)的切伦科夫光探测器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

SiPMs and examples of applications for low light detection in particle and astroparticle physics

SiPMs and examples of applications for low light detection in particle and astroparticle physics

Silicon Photomultipliers (SiPMs) have emerged as leading photon detectors in experimental physics since their introduction in the late 1990s. With performance characteristics superior to those of traditional photodetectors, SiPMs exhibit up to 60% photon detection efficiency, rapid signal rise times, and resistance to magnetic fields. Their solid-state construction enables mass production, compactness, and high spatial resolution, facilitating their integration into a wide range of experimental setups. Although susceptible to radiation damage, mitigation strategies are being studied to allow their reliable operation even in environments with elevated radiation levels. SiPMs excel in detecting low levels of light, making them well suited for applications involving scintillation and Cherenkov light. Their ability to operate effectively at cryogenic temperatures allows the construction of a new class of multi-tons rare event search experiments such as Darkside-20k. Insensitivity to the magnetic field and mitigation of the radiation damages are making SiPMs well-suited to be used in accelerator driven physics such as Cherenkov light detectors for Particle IDentification (PID) in the future Electron Ion Collider (EIC).

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