Recent Progress in the Development of a-Se/CMOS Sensors for X-ray Detection

IF 1.3 Q3 INSTRUMENTS & INSTRUMENTATION

Quantum Beam Science Pub Date : 2021-10-18 DOI:10.3390/qubs5040029

K. Hellier, Emmie Benard, C. Scott, K. Karim, S. Abbaszadeh

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引用次数: 6

Abstract

Amorphous selenium (a-Se) is a glass-former capable of deposition at high rates by thermal evaporation over a large area. It was chosen as a direct conversion material due to its appealing properties for imaging in both low and high X-ray energy ranges (<30 keV and <30 keV, respectively). It has a bandgap of 2.2 eV and can achieve high photodetection efficiency at short wavelengths less than 400 nm which makes it appealing for indirect conversion detectors. The integration of a-Se with readout integrated circuits started with thin-film transistors for digital flat panel X-ray detectors. With increasing applications in life science, biomedical imaging, X-ray imaging, high energy physics, and industrial imaging that require high spatial resolution, the integration of a-Se and CMOS is one direct way to improve the high-contrast visualization and high-frequency response. Over the past decade, significant improvements in a-Se/CMOS technologies have been achieved with improvements to modulation transfer function and detective quantum efficiency. We summarize recent advances in integrating and photon-counting detectors based on a-Se coupled with CMOS readout and discuss some of the shortcomings in the detector structure, such as low charge conversion efficiency at low electric field and high dark current at high electric field. Different pixel architectures and their performance will be highlighted.

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a-Se/CMOS X射线探测传感器的研究进展

非晶态硒（a-Se）是一种能够通过大面积热蒸发以高速率沉积的玻璃形成物。它之所以被选为直接转换材料，是因为它在低和高X射线能量范围（分别<30keV和<30keV）成像时具有吸引力。它具有2.2eV的带隙，并且可以在小于400nm的短波长下实现高的光电探测效率，这使得它对间接转换探测器很有吸引力。a-Se与读出集成电路的集成始于用于数字平板X射线探测器的薄膜晶体管。随着在生命科学、生物医学成像、X射线成像、高能物理和工业成像中对高空间分辨率的要求越来越高，a-Se和CMOS的集成是提高高对比度可视化和高频响应的一种直接方法。在过去的十年里，随着调制传递函数和探测量子效率的提高，a-Se/CMOS技术得到了显著的改进。我们总结了基于a-Se与CMOS读出耦合的积分和光子计数探测器的最新进展，并讨论了探测器结构中的一些缺点，如低电场下的低电荷转换效率和高电场下的高暗电流。将重点介绍不同的像素架构及其性能。

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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