JUNO标定策略与仿真

Proceedings of 40th International Conference on High Energy physics — PoS(ICHEP2020) Pub Date : 2021-03-09 DOI:10.22323/1.390.0817

Kangfu Zhu, Qingmin Zhang

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引用次数: 0

摘要

江门地下中微子天文台(JUNO)主要是通过反β衰变探测反应堆反中微子来测量中微子的质量有序(MO)。朱诺还有其他丰富的物理潜力。它的中央探测器(CD)是一个直径35.4米的丙烯酸球体，填充了大约20千吨的液体闪烁体(LS)，配备了大型光电倍增管(CD为18k，水池为2k)和小型光电倍增管(25,600)来测量中微子的能量分辨率，能量分辨率达到前所未有的3%/ E，能量非线性优于1%。因此，包括自动校准单元(ACU)、电缆回路系统(CLS)、导管校准系统(GTCS)和远程操作液下闪烁器车辆(ROV)在内的校准综合体设计用于提供多个放射源，以覆盖反应堆中微子和CD的全体积能量。本文介绍了JUNO标定系统的最新设计细节和最新进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The JUNO Calibration Strategy and Simulation

The Jiangmen Underground Neutrino Observatory (JUNO) is designed to primarily measure the neutrino Mass Ordering (MO) by detecting reactor anti-neutrinos via inverse beta decay. JUNO also has other rich physical potentials. Its Central Detector (CD), which is an acrylic sphere with a diameter of 35.4 m, filled by approximately 20 kton of liquid scintillator (LS), is equipped with large photomultipliers (18k for the CD + 2k for the Water Pool) and small photomultipliers (25,600) to measure the energy resolution of neutrinos with an unprecedented energy resolution of 3%/ E and an energy non-linearity better than 1%. Accordingly, a calibration complex, including Automatic Calibration Unit (ACU), Cable Loop System (CLS), Guide Tube Calibration System (GTCS) and Remotely Operated under-liquid-scintillator Vehicles (ROV), is designed to deliver multiple radioactive sources for the energy coverage of reactor neutrinos and CD full-volume. In this proceeding, the new design details and up-to-date progress about JUNO calibration system are presented.

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Proceedings of 40th International Conference on High Energy physics — PoS(ICHEP2020)

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