用于提高量子效率的单片双层高Z PAL Si硬X射线CMOS图像传感器的设计

Q3 Physics and Astronomy
Eldred Lee, K. D. Larkin, Xin Yue, Zhehui Wang, E. Fossum, Jifeng Liu
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引用次数: 0

摘要

本文通过实验研究了一种创新的硬x射线光子能量衰减层(PAL)的开始,以推进高能x射线探测(20-50 keV)。一种双层设计,上面是薄膜高z PAL,下面是Si图像传感器,之前已经通过光子能量下转换(PEDC)原理的计算方法证明了量子产率的提高,其中高能x射线光子能量通过非弹性散射衰减到≤10 keV,适合于Si的高效光电吸收。通过使用pal集成的硅基CMOS图像传感器(Si CIS)的初步演示,实验证实了量子产率的增强。此外,用低z材料sn代替高z PAL,或者与传统闪烁体材料LYSO耦合,已经证明了高z PAL在Si CIS上的单片集成检测硬x射线的最突出效果,为下一代高能x射线检测方法铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Design of Monolithic Bi-Layer High-Z PAL-Si Hard X-ray CMOS Image Sensors for Quantum Efficiency Enhancement
This article experimentally investigates the inception of an innovative hard X-ray photon energy attenuation layer (PAL) to advance high-energy X-ray detection (20–50 keV). A bi-layer design with a thin film high-Z PAL on the top and Si image sensor on the bottom has previously demon-strated quantum yield enhancement via computational methods by the principle of photon energy down conversion (PEDC), where high-energy X-ray photon energies are attenuated via inelastic scattering down to ≤10 keV, which is suitable for efficient photoelectric absorption by Si. Quantum yield enhancement has been experimentally confirmed via a preliminary demonstration using PAL-integrated Si-based CMOS image sensors (Si CIS). Furthermore, substituting the high-Z PAL with a lower-Z material—Sn—and alternatively coupling it with a conventional scintillator ma-terial—Lutetium-yttrium oxyorthosilicate (LYSO)—have been compared to demonstrate the most prominent efficacy of monolithic integration of high-Z PAL on Si CIS to detect hard X-rays, paving the way for next-generation high-energy X-ray detection methods.
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来源期刊
Instruments
Instruments Physics and Astronomy-Instrumentation
CiteScore
2.60
自引率
0.00%
发文量
70
审稿时长
11 weeks
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