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Please use this identifier to cite or link to this item: http://hdl.handle.net/11375/27881
Title: Solving the Extremely High Dead Time During Ultra-High-rate Gamma-ray Spectrometry Using a LaBr3(Ce) Detector
Authors: Ren, Tianyi
Advisor: Byun, Soohyun
Department: Radiation Sciences (Medical Physics/Radiation Biology)
Keywords: LaBr3 detector;Gamma-ray Spectrometry
Publication Date: 2022
Abstract: One of the main challenges during the ultra-high count rate gamma-ray spectrometry is the large dead time. Using a LaBr3(Ce) detector (TRT 0.3 µs, TFT 0.5 µs), with an input count rate of 4.8×10E5 cps, the dead time could be as high as 87%. Such high dead time could significantly reduce the quality of the data collected as a considerable number of counts would be lost. Thus, this project aimed to reduce the dead time by modifying the detector system. Based on the setup used by previous research, the new system has its preamp, which is normally used for signal processing, removed. Experiments were made with calibration sources to optimize the new system. The calibration sources (Cs-137 and Co-60), Cs-137 resin sources, and Shephard Cs-137 sources were used to create different count rates, with the highest being 1.22×10E6 cps, for measurements. Side-by-side measurements were performed with the setup with preamp and the one without preamp at various count rates. The analysis, which focused on the dead time and resolution, shows the setup without preamp would have much lower dead time, especially during ultra-high count rate measurements. The method was proved to be successful, for, at 4.8×10E5 cps, the dead time decreased from 87% to 54%.
URI: http://hdl.handle.net/11375/27881
Appears in Collections:Open Access Dissertations and Theses

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