ARI-MA: Cavity Resonance Kinetic Inductance Detectors (CaRKIDs)

ARI-MA：腔谐振动感电感探测器 (CaRKID)

• 批准号: 1039309
• 负责人: Albert Betz
• 金额: $ 38.12万
• 依托单位: University of Colorado at Boulder
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-09-15 至 2011-08-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1039309&HistoricalAwards=false
• 关键词: ARI; MA; Cavity; Resonance; Kinetic

1039309BetzThe objective of this proposal is to develop detectors with high efficiency and high resolution. Currently, the best high-purity germanium detectors (HPGe) used in nuclear spectroscopy provide a fractional energy resolution of only 0.5% in the 100 keV region important in nuclear spectroscopy. In many cases this resolution is inadequate to discriminate between threatening nuclear materials and more mundane substances which are part of the natural background. For example, the most common source of false alarms at US border crossings is the confusion between the naturally occurring emission of 226Ra (an element commonly found in clay-bearing materials and soils) at 186.211 keV and the185.715 keV emission of fissile 235U. Another spectroscopic challenge in nuclear materials analysis is separating the intense 104.2 keV line of 240Pu from the nearby 103.7 keV X-ray of Pu X. These and other line overlaps in the 100-200 keV region set the error budget for nondestructive analysis of mixed actinide samples. Determining the isotopic mix in a reactor fuel sample provides both a characteristic fingerprint and specific information about the intended purpose of the fuel (weapons production or electricity generation), the type of reactor, and the history of chemical processing, if any. Further, detectors with high efficiency and high resolution can provide new capabilities for detecting fissile material. Detectors with better resolution produce a better signal-to-noise ratio when measuring faint emission lines from trace quantities of radioactive material in the presence of background or overlapping lines. The new superconducting detectors proposed here offer the promise of 30 times better energy resolution than HPGe, and perhaps 1000 times greater cross-sectional sensitivity compared to cryogenic microcalorimeters.The intellectual merit of the proposed activity derives from its potential to produce more than an order of magnitude improvement in the energy resolution of gamma ray detectors, and the scientific fallout this advance would have, not only for nuclear security, but also in astrophysics and nuclear medicine. The detectors proposed rely on an effect called kinetic inductance, in which the macroscopic inductance of the surface of a superconductor can be influenced by the creation of unpaired electrons (quasiparticles) through the absorption of ionizing radiation. The change in inductance is picked up by a high-Q microwave circuit, and the signal event is counted as with any another photon counter, but with the difference that the pulse heights can be measured with 30 eV energy resolution in the gamma absorption.The broader impact of this effort will be felt in several areas. First in science the development of high-energy kinetic inductance detectors will influence the direction of gamma ray astronomy and perhaps even the search for dark matter. In technology, the impact will be felt in the development of non-contact nuclear assay methods of unprecedented sensitivity. Finally, in education, the participants in the research, the graduate student and postdoc, will be free to explore a wide open area as part of thesis and postdoctoral research. Finally the senior personnel will have something exciting to do, and something new to convey to the K-12 students in the science fair and outreach activities.

1039309Betz这项提议的目标是开发高效率和高分辨率的探测器。目前，用于核光谱学的最好的高纯锗探测器(HPGe)在核光谱学中重要的100keV区域提供的分数能量分辨率仅为0.5%。在许多情况下，这项决议不足以区分具有威胁性的核材料和属于自然背景的更普通的物质。例如，美国边境口岸最常见的假警报来源是186.211 keV的226Ra(一种常见于粘土材料和土壤中的元素)的自然排放与185.715keV的裂变235U排放之间的混淆。在核材料分析中的另一个光谱挑战是将240Pu的强104.2 keV谱线与附近的Pu X的103.7 keV X射线分开。这些谱线和在100keV-200keV区域的其他谱线重叠设置了对混合鳗系元素样品进行无损分析的误差预算。确定反应堆燃料样本中的同位素混合物既提供了特征指纹，也提供了有关燃料的预定目的(武器生产或发电)、反应堆类型和化学处理历史(如果有)的具体信息。此外，高效率和高分辨率的探测器可以为探测裂变材料提供新的能力。在测量有背景或重叠线存在的微量放射性物质的微弱发射线时，分辨率更高的探测器产生更好的信噪比。这里提出的新超导探测器的能量分辨率是HPGe的30倍，截面灵敏度可能是低温微热量的1000倍。拟议活动的智力优势来自于它有潜力在伽马射线探测器的能量分辨率上提高一个数量级以上，以及这种进步将产生的科学后果，不仅是为了核安全，也是在天体物理和核医学方面。提出的探测器依赖于一种被称为动力学电感的效应，在这种效应中，超导体表面的宏观电感可以受到通过吸收电离辐射而产生的未配对电子(准粒子)的影响。电感的变化由高Q微波电路获取，信号事件与任何其他光子计数器一样进行计数，但不同的是，脉冲高度可以在伽马吸收中以30 eV的能量分辨率测量。这一努力将在几个领域感受到更广泛的影响。首先，在科学方面，高能动感探测器的发展将影响伽马射线天文学的方向，甚至可能影响暗物质的搜索。在技术上，非接触性核分析方法的发展将感受到前所未有的敏感性。最后，在教育方面，研究的参与者，研究生和博士后，将可以自由探索广阔的领域，作为论文和博士后研究的一部分。最后，高级人员将有一些令人兴奋的事情要做，并在科学博览会和外展活动中向K-12学生传达一些新的东西。