Simulation of electron transport in a catoptric photomultiplier tube concept for large rectangular scintillator crystals

Journal of Instrumentation Pub Date : 2024-04-01 DOI:10.1088/1748-0221/19/04/p04025

J. Beavers, K. Huddleston, N. Hines, W. McNeil

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Abstract

Spectroscopic scintillation detector form factors have been guided primarily by the design of commercially available photonic sensors. These devices, such as photomultiplier tubes, silicon photomultipliers, and hybrid photodetectors have underperformed in one or more areas such as size, power consumption, and resolution. A novel photomultiplier tube having a 50.8×152.4 mm2 rectangular window, utilizing a reflection-mode photocathode, and a low-gain, miniaturized dynode set is considered here to improve photosensor packaging while enabling high-efficiency, low-resolution scintillation spectroscopy with large, planar scintillators. Using a phenomenological multiphysics simulation process informed by empirical data, photoelectron collection efficiency, single-photoelectron response, electron transit time, and transit time spread have been modeled over a range of operating potentials. At 750 V between the photocathode and anode, 72.5% of photoelectrons are collected at the first dynode, and the average gain is estimated to be 805. The most probable transit time is 14.9 ns, with a transit time spread of 2.7 ns full-width at half-maximum.

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模拟大型矩形闪烁晶体的猫眼光电倍增管概念中的电子传输

光谱闪烁探测器的外形尺寸主要受市场上现有光子传感器设计的指导。这些设备，如光电倍增管、硅光电倍增管和混合光电探测器在尺寸、功耗和分辨率等一个或多个方面表现不佳。本文考虑采用一种具有 50.8×152.4 平方毫米矩形窗口的新型光电倍增管，利用反射模式光电阴极和低增益、小型化的 dynode 组来改进光传感器封装，同时利用大型平面闪烁体实现高效率、低分辨率闪烁光谱。利用以经验数据为依据的现象学多物理场仿真过程，对一系列工作电位下的光电子收集效率、单光电子响应、电子传输时间和传输时间差进行了建模。当光电阴极和阳极之间的电压为 750 V 时，72.5% 的光电子被收集到第一个阳极，平均增益估计为 805。最可能的传输时间为 14.9 毫微秒，传输时间差为 2.7 毫微秒半最大全宽。

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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Journal of Instrumentation

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