SNO+水相的中子探测。

arXiv: Instrumentation and Detectors Pub Date : 2018-08-21 DOI:10.5281/zenodo.1300938

Y. Liu, S. Andringa, D. Auty, F. Barão, R. Bayes, E. Caden, C. Grant, J. Grove, B. Krar, A. Latorre, L. Lebanowski, J. Lidgard, J. Maneira, P. Mekarski, S. Nae, T. Pershing, I. Semenec, K. Singh, P. Skensved, B. Tam, A. A. F. T. A. Collaboration

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摘要

SNO+是一个多用途中微子实验，位于加拿大萨德伯里的SNOLAB地下约2公里处。该探测器于2017年5月开始采集物理数据，目前正在完成其第一阶段，作为纯水切伦科夫探测器。SNO+探测器的低触发阈值允许大量的中子探测效率，正如部署的^{241}Am^{9}Be源所观察到的那样。通过对1小时AmBe校准数据的统计分析，我们报告了探测器中心的中子捕获常数为208.2 + 2.1(stat.) us，中子探测效率的下限为46%。

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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Neutron detection in the SNO+ water phase.

SNO+ is a multipurpose neutrino experiment located approximately 2 km underground in SNOLAB, Sudbury, Canada. The detector started taking physics data in May 2017 and is currently completing its first phase, as a pure water Cherenkov detector. The low trigger threshold of the SNO+ detector allows for a substantial neutron detection efficiency, as observed with a deployed ^{241}Am^{9}Be source. Using a statistical analysis of one hour AmBe calibration data, we report a neutron capture constant of 208.2 + 2.1(stat.) us and a lower bound of the neutron detection efficiency of 46% at the center of the detector.

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arXiv: Instrumentation and Detectors

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