Tunable Wavelength, High Efficiency Scintillator for Neutron Crystallography

用于中子晶体学的可调谐波长、高效闪烁体

基本信息

批准号：
7746047
负责人：
VIVEK V NAGARKAR
金额：
$ 19.75万
依托单位：
RADIATION MONITORING DEVICES, INC.
依托单位国家：
美国
项目类别：
财政年份：
2009
资助国家：
美国
起止时间：
2009-09-27 至 2011-03-26
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/7746047
关键词：
Address Biomedical Research Blood capillaries Boron Characteristics Collaborations Color Complex Crystallography Data Detection Development Diagnostic radiologic examination Drug Formulations Effectiveness Ensure Evaluation Gamma Rays Germany Goals Government Housing Image Individual Laboratories Letters Light Marketing Materials Testing Measurement Mechanics Medical Imaging Nanomanufacturing Neutrons Nuclear Nuclear Physics Ohio Optics Output Performance Persons Phase Physics Physiologic pulse Plastics Play Polymers Positioning Attribute Production Property Protocols documentation Quantum Dots Quartz Radiation Radiation Monitoring Radioactive Waste Reading Reporting Research Research Personnel Resolution Resources Roentgen Rays Role Saints Sampling Science Series Shapes Signal Transduction Silicon Source Specimen Structure System Techniques Technology Testing Thick Time Treaty Writing absorption base capillary commercialization cost design detector experience imaging detector improved instrument instrumentation molecular dynamics monitoring device nanomaterials new technology novel programs protein structure protein structure function public health relevance quantum research study response sensor solid state symposium

项目摘要

DESCRIPTION (provided by applicant): Despite their unique advantages and great promise for elucidating the structure of proteins, neutron techniques have been underutilized compared to X-ray measurement techniques, primarily because of the lack of adequate neutron sources and suitable imaging detectors. The former limitation has now been effectively addressed, at least regionally, by the development of intense pulsed neutron sources such as the Spallation Neutron Source (SNS) at Oak Ridge National Laboratory. The latter limitation, however, remains a challenge, and improved detectors will play a vital role in the effective utilization of new and existing neutron sources by facilitating many important studies. While highly promising new designs of detectors now exist, they are nonetheless limited by current neutron-sensitive scintillators that are used as converters. New and efficient scintillators that can match the performance of these novel readouts are critically important to realize the full benefit of new neutron sources. To address these limitations we propose to develop a novel scintillator with tunable emissions that can be matched to the individual performances of new high resolution, high frame rate readouts. The key component in this scintillator development is a quantum dot wavelength shifter that will allow unprecedented color matching between scintillator emissions and quantum efficiencies of individual photosensors to optimize overall detection efficiency. Our novel scintillator will attain high neutron detection efficiency with low sensitivity to gamma rays and fast temporal response, and will demonstrate the tremendous potential of nanomanufacturing -techniques to significantly improve performance and dramatically reduce production cost. Commercialization efforts will be undertaken in collaboration with an industrial partner who has well-established production capabilities and marketing groups around the globe. Specific aims. The goal of the Phase I research is to optimize the synthesis of scintillators incorporating quantum dots as very high efficiency tunable wavelength shifters to match the absorption characteristics of novel imaging photodetectors. Structured scintillators will also be fabricated from these wavelength-shifted neutron sensors and optically integrated with imaging instruments. Several scintillator specimens will be produced using optimized fabrication parameters, and then thoroughly evaluated to quantify their optical, scintillation and imaging properties for comparison with current scintillators to demonstrate the usefulness of this approach. PUBLIC HEALTH RELEVANCE: High-performance neutron detectors are critically important for neutron scattering studies that investigate the structure of proteins to advance biomedical research. Many other applications such as neutron imaging, nuclear and high energy physics research, medical imaging, diffraction, nuclear waste clean-up, nuclear treaty verification and safeguards, as well as geological exploration would benefit from advances in new technologies for detecting neutrons. The proposed research seeks to improve the light output for a neutron-sensitive plastic scintillator that can detect neutrons with high sensitivity and fine spatial resolution.

描述（由申请人提供）：尽管中子技术在阐明蛋白质结构方面具有独特的优势和巨大的前景，但与 X 射线测量技术相比，中子技术尚未得到充分利用，这主要是因为缺乏足够的中子源和合适的成像探测器。通过开发强脉冲中子源（例如橡树岭国家实验室的散裂中子源（SNS）），前一个限制现已得到有效解决（至少在区域范围内）。然而，后一个限制仍然是一个挑战，改进的探测器将通过促进许多重要的研究，在有效利用新的和现有的中子源方面发挥至关重要的作用。虽然现在存在非常有前途的新型探测器设计，但它们仍然受到当前用作转换器的中子敏感闪烁体的限制。能够与这些新型读数器的性能相匹配的新型高效闪烁体对于实现新中子源的全部优势至关重要。为了解决这些限制，我们建议开发一种具有可调谐发射的新型闪烁体，该闪烁体可以与新的高分辨率、高帧率读数的单独性能相匹配。该闪烁体开发的关键组件是量子点波长移位器，它将在闪烁体发射和单个光电传感器的量子效率之间实现前所未有的颜色匹配，以优化整体检测效率。我们的新型闪烁体将实现高中子探测效率、对伽马射线的低灵敏度和快速的时间响应，并将展示纳米制造技术在显着提高性能和大幅降低生产成本方面的巨大潜力。商业化工作将与在全球拥有完善生产能力和营销团队的工业合作伙伴合作进行。具体目标。第一阶段研究的目标是优化闪烁体的合成，将量子点作为非常高效的可调谐波长移位器，以匹配新型成像光电探测器的吸收特性。结构化闪烁体也将由这些波长位移中子传感器制成，并与成像仪器光学集成。将使用优化的制造参数生产几个闪烁体样本，然后进行彻底评估以量化其光学、闪烁和成像特性，以便与当前闪烁体进行比较，以证明该方法的有用性。公共健康相关性：高性能中子探测器对于研究蛋白质结构以推进生物医学研究的中子散射研究至关重要。中子成像、核和高能物理研究、医学成像、衍射、核废料清理、核条约核查和保障以及地质勘探等许多其他应用将受益于检测中子的新技术的进步。拟议的研究旨在提高中子敏感塑料闪烁体的光输出，该闪烁体可以高灵敏度和精细空间分辨率检测中子。