Development of diamond dynodes for the next generation high throughput photon counting detectors

开发用于下一代高通量光子计数探测器的金刚石倍增极

• 批准号: EP/E014011/1
• 负责人: Paul May
• 金额: $ 2.49万
• 依托单位: University of Bristol
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2007
• 资助国家: 英国
• 起止时间: 2007 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=EP%2FE014011%2F1
• 关键词: Development; diamond; dynodes; next; generation

VisionThe diamond dynode technology we propose is the precursor to a potential step change from vacuum tube devices, photomultiplier tubes and image intensifiers, towards the promise of large area, flat panel photon counting detector designs utilising micro-machined 2D pixel arrays; a revolution analogous to the replacement of the cathode ray tube (CRT) with todays's flat screen liquid crystal displays (LCDs).Improved photon and particle counting detector systems are crucial for continuing technological progress in wide variety of diverse applications from the life sciences to particle physics, environmental monitoring to astronomy. The aim of this project is to investigate the properties of artificially deposited diamond as a dynode material for electron multiplication in high performance detectors. Previous studies suggest that diamond could be exceptionally well suited candidate for this role, but thus far its properties have not been exploited thus far in this field. The one-year project will be a collaboration between the Space Research Centre, University of Leicester and the Department of Chemistry at Bristol University, and has a total full economic cost of 121,400. Manpower will be provided by a PDRA project scientist employed fulltime for 12 months, under the supervision of the PI from Leicester and Co-Is from Bristol, and assisted by one month mechanical technician effort at Leicester. The year long schedule comprises 5 work packages :-1. A review of existing data on deposited diamond film characteristics, identification of likely dynode candidates (dopant concentrations, process parameters, etc., surface modification) and simulation and modelling of dynode performance.2. Investigation of diamond coating techniques including CVD deposition and inkjet printing of diamond powder in a conductive nano-particle matrix.3. Manufacture of diamond coated dynodes using a preferred range of process parameters, dopant concentrations, and surface modification, including investigation of transparent dynode structures using diamond coated meshes. Following characterization, one process iteration will be undertaken.4. Measurement of secondary electron emission characteristics (emission coefficient, energy and angular distribution) for various diamond coated dynode samples as a function of input electron energy and angle.5. Performance evaluation of a discrete dynode photomultiplier tube designed for, and using diamond coated dynodesThe collaboration with Photek Ltd. will enable the project team to demonstrate diamond dynode proof-of-concept using a photo-multiplier tube specially designed for this purpose. Photek will contribute in-kind assistance with PMT design and assembly and dynode performance demonstration in return for the academic partners' development of suitable diamond coating techniques and agreement to negotiate arrangements for possible commercialization.This project is synergistic with an imminent Basic technology Consortium Building proposal to establish a developer and end-user network for the development of revolutionary technologies for generic photon and counting particle sensor systems. The goal is to provide step change in detector performance enabling ground-braking application across a broad range of disciplines.

我们提出的金刚石dynode技术是一个潜在的阶跃变化的先驱，从真空管器件，光电倍增管和图像增强器，到利用微加工二维像素阵列的大面积平板光子计数探测器设计；类似于用今天的平板液晶显示器（lcd）取代阴极射线管（CRT）的革命。改进的光子和粒子计数探测器系统对于从生命科学到粒子物理学、环境监测到天文学等各种不同应用的持续技术进步至关重要。本项目的目的是研究人工沉积的金刚石作为高性能探测器中电子倍增的dynode材料的性能。以前的研究表明，钻石可能是非常适合这个角色的候选者，但到目前为止，它的性质还没有在这个领域得到充分利用。这个为期一年的项目将由莱斯特大学空间研究中心和布里斯托尔大学化学系合作开展，总经济成本为12.14万英镑。人力将由一名全职的PDRA项目科学家提供，为期12个月，在莱斯特大学PI和Co-Is的监督下，并由莱斯特大学一个月的机械技术人员协助。一年的计划包括5个工作包：综述了沉积金刚石膜特性的现有数据，确定可能的dynode候选者（掺杂剂浓度，工艺参数等，表面改性）以及dynode性能的模拟和建模。金刚石涂层技术的研究，包括CVD沉积和喷墨打印在导电纳米颗粒基体上的金刚石粉末。使用优选的工艺参数、掺杂剂浓度和表面修饰范围制造金刚石涂层节点，包括使用金刚石涂层网格研究透明节点结构。在描述之后，将进行一次过程迭代。4 .测量不同金刚石涂层样品的二次电子发射特性（发射系数、能量和角度分布）与输入电子能量和角度的关系与Photek有限公司的合作将使项目团队能够使用专门为此目的设计的光倍增管演示钻石dynode的概念验证。Photek将在PMT设计、组装和dynode性能演示方面提供实物援助，以换取学术合作伙伴开发合适的金刚石涂层技术，并同意就可能的商业化安排进行谈判。该项目与即将到来的基础技术联盟建设提案协同作用，该提案旨在建立一个开发人员和最终用户网络，以开发通用光子和计数粒子传感器系统的革命性技术。目标是提供探测器性能的阶跃变化，从而实现跨广泛学科的突破性应用。

项目成果

Investigation of the secondary electron emission characteristics of alternative dynode materials for imaging photomultipliers

用于成像光电倍增管的替代打拿极材料的二次电子发射特性的研究

• DOI: 10.1088/1748-0221/7/03/c03018
• 发表时间: 2012
• 期刊: Journal of Instrumentation
• 影响因子: 1.3
• 作者: Lapington J

Measurement of the secondary electron emission from CVD diamond films using phosphor screen detectors

使用荧光屏检测器测量 CVD 金刚石薄膜的二次电子发射

• DOI: 10.1088/1748-0221/10/03/p03004
• 发表时间: 2015
• 期刊: Journal of Instrumentation
• 影响因子: 1.3
• 作者: Vaz R