High Efficiency Silicon Detectors for Synchrontron XRF

用于同步加速器 XRF 的高效硅探测器

• 批准号: 6945927
• 负责人: Carolyn Rossington Tull
• 金额: $ 37.07万
• 依托单位: PHOTON IMAGING, INC.
• 依托单位国家: 美国
• 财政年份: 2004
• 资助国家: 美国
• 起止时间: 2004-09-01 至 2006-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/6945927
• 关键词: X ray; X ray spectrometry; biomedical equipment development; biosensor device; electromagnetic radiation; radiofluorescent probe; silicon; synchrotrons

DESCRIPTION (provided by applicant): We will develop a new x-ray spectrometer, based on novel high efficiency silicon x-ray detectors; with good energy resolution and high count rate capability for synchrotron x-ray fluorescence (XRF) applications. In Phase I, we extended the very successful silicon drift detector design, currently fabricated on thin 0.3 mm thick substrates, into the realm of thick detectors (up to 1.5 mm thick). This added thickness is critical in extending the x-ray absorption capability of the detectors from 15 keV to 40 keV. Synchrotron XRF techniques are becoming essential tools for biological, chemical and materials analysis. Third generation synchrotrons, such as the Advanced Photon Source (APS), have photon flux brilliance in the 6-40 keV region that allow efficient x-ray fluorescence analysis with probe sizes of a micrometer and below. All of these beam-lines require high-count rate, good energy resolution energy dispersive x-ray detectors that have efficient absorption up to 40 keV. The new, thicker drift detectors will have the advantages of non-cryogenic cooling, good energy resolution, and an order of magnitude improvement in count rates compared with conventional silicon and germanium XRF detectors, while providing a significant increase in efficiency above 10 keV. The Phase II work will include the optimization of the thick detector prototypes including increase in area from 20 mm2 to 50 mm2; improve the yield and design of the process for transfer to a commercial silicon foundry. The detectors will be evaluated with respect to noise, energy resolution, and efficiency and count rate capability in response to x-rays in the 5-60 keV range. The best devices will be selected to be incorporated into a three-channel x-ray spectrometer. The spectrometer will be custom-designed and evaluated in a hard x-ray microprobe application at the Advanced Photon Source at Argonne National Laboratory, in collaboration with APS staff. The commercial applications for such high efficiency spectrometers include chemical analysis in steel, materials, chemical, geological and biological applications.

描述(由申请人提供)： 我们将开发一种基于新型高效硅X射线探测器的新型X射线光谱仪，具有良好的能量分辨率和高计数率能力，适用于同步辐射X射线荧光(XRF)应用。在第一阶段，我们将目前在0.3 mm厚的薄衬底上制造的非常成功的硅漂移探测器设计扩展到厚探测器(厚达1.5 mm)领域。这一增加的厚度对于将探测器的X射线吸收能力从15keV扩展到40keV至关重要。同步辐射X射线荧光技术正在成为生物、化学和材料分析的重要工具。第三代同步加速器，如先进光子源(APS)，具有6-40keV范围内的光子通量亮度，使探测器尺寸在微米及以下的情况下能够进行高效的X射线荧光分析。所有这些光束线都需要高计数率、高能量分辨率、能量色散的X射线探测器，其有效吸收高达40keV。与传统的硅和锗XRF探测器相比，新的、更厚的漂移探测器将具有非低温冷却、良好的能量分辨率和数量级的计数速率改进的优势，同时提供10keV以上的效率显著提高。 第二阶段的工作将包括优化厚探测器原型，包括将面积从20mm2增加到50mm2；提高产量和设计转移到商业硅铸造厂的工艺。探测器将根据噪声、能量分辨率以及对5-60keV范围内X射线的响应效率和计数率能力进行评估。最好的设备将被选入三通道X射线光谱仪。该光谱仪将在阿贡国家实验室的高级光子源与APS工作人员的合作下，在硬X射线微探针应用中进行定制设计和评估。这种高效光谱仪的商业应用包括钢铁中的化学分析、材料、化学、地质和生物应用。