Compact, inexpensive, high-energy-resolution, room-temperature-operated, semiconductor gamma-ray detectors for isotope identification

2010 IEEE International Conference on Technologies for Homeland Security (HST) Pub Date : 2010-12-03 DOI:10.1109/THS.2010.5654940

P. Ugorowski, A. Ariesanti, D. Mcgregor, A. Kargar

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Abstract

Many homeland security applications involving gamma-ray detectors require energy resolution of better than 1%–2% for isotope identification. Existing High-Purity germanium (HPGe) detectors have the needed energy resolution but suffer from large size and the need for liquid-nitrogen or electromechanical cooling. Compact, inexpensive, room-temperature-operated devices are needed for handheld monitors, portal monitors, and monitors for nuclear materials in storage or transit. At Kansas State University, CdZnTe (CZT) gamma-ray detectors with better than 1% energy resolution have been developed. Mercuric Iodide detectors with better than 2% energy resolution have also been developed. Both devices make use of the Frisch-collar technology developed at KSU, and the quoted results were achieved without electronic corrections. The goal of the research at KSU is to maximize the energy resolution of the signals coming from the detectors, before any electronic corrections are made. The characteristics of these small, inexpensive devices will be discussed.

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紧凑，廉价，高能量分辨率，室温操作，用于同位素鉴定的半导体伽马射线探测器

许多涉及伽玛射线探测器的国土安全应用要求同位素识别的能量分辨率优于1%-2%。现有的高纯度锗(HPGe)探测器具有所需的能量分辨率，但尺寸较大，需要液氮或机电冷却。手持式监测仪、门户监测仪和储存或运输中的核材料监测仪需要小巧、廉价、室温操作的设备。在堪萨斯州立大学，已经开发出能量分辨率超过1%的CdZnTe (CZT)伽马射线探测器。能量分辨率高于2%的碘化汞探测器也已研制成功。这两种设备都使用了KSU开发的Frisch-collar技术，并且引用的结果无需电子校正即可实现。KSU的研究目标是在进行任何电子校正之前，最大限度地提高来自探测器的信号的能量分辨率。我们将讨论这些小型、廉价设备的特点。

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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2010 IEEE International Conference on Technologies for Homeland Security (HST)

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