Single-Shot Smith-Purcell Longitudinal Bunch Profile Monitor for CLARA with fs resolution

用于 CLARA 的单次 Smith-Purcell 纵向束剖面监测仪，具有 fs 分辨率

• 批准号: 2275182
• 金额: --
• 依托单位: University of Oxford
• 依托单位国家: 英国
• 项目类别: Studentship
• 财政年份: 2019
• 资助国家: 英国
• 起止时间: 2019 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=studentship-2275182
• 关键词: Single; Shot; Smith; Purcell; Longitudinal

Accurate knowledge of the longitudinal (time) profile of an electron bunch is important in the context of linear colliders, wake-field accelerators and next-generation light sources including X-ray FELs, THz sources and Compton lasers. The profile becomes progressively more difficult to measure as the particle bunches become shorter (fs-scale) or more complex (micro-modulated bunches). Therefore, it is essential to be able to determine the temporal profile with fs resolution, non-destructively and in a single shot. Without this capability it will be very difficult to satisfy the criteria for the next generation light sources (generation of spectrally stable, high intensity and luminosity X-ray pulses) and improve further the performance of wake-field accelerators. The objectives of this project are: 1/ to design and build the first prototype of a single-shot longitudinal bunch-profile monitor based on coherent Smith-Purcell radiation;2/ to install it at CLARA facility (Daresbury Laboratory, STFC) and to commission it;3/ to measure beam profiles with fs resolution and to compare the results with those from other diagnostic devices at CLARA. 4/ to write the research papers, complete and submit the PhD thesis. The work will be carried out in close collaboration with FMB Oxford and CLARA team. This is essential for reaching objectives and the project success. The design will be based on the results of recent studies and on a conceptual design previously developed. The studies and the conceptual design were supported by STFC (PRD grant and studentship). The monitor development is a part of the JAI research plan.The operational principles of the conceptual design have been tested at FACET, SLAC (USA) and LUCX, KEK (Japan). It was shown that coherent Smith Purcell radiation (cSPr) is highly polarised while the background radiation is not. This property will be exploited in the design of the monitor, in order to minimise its size and complexity. To reduce time and cost, the construction of the first prototype will use some of the hardware built for the original multi-shot monitor studied at FACET. The prototype will have a single grating, 22 optical channels (11 channels per each polarisation) and beam positioning monitors installed before and after the vacuum chamber. Sampling and analysis of the cSPr signal at 11 frequencies in the frequency range 0.2THz to 1THz will achieve 10fs resolution. The industrial partner's involvement in the project is crucial to its success. FMB Oxford will bring its expertise in design of diagnostics for particle accelerators and knowledge of specialist techniques which will be required to design and test the monitor. The student will work at FMB facilities, developing the monitor's technical design and testing its components. FMB will supervise, mentor and provide training within the competitive business environment, broadening the student's experience beyond the usual academic framework.

电子束团的纵向（时间）分布的准确知识是重要的线性对撞机，尾场加速器和下一代光源，包括X射线自由电子激光，太赫兹源和康普顿激光器的上下文中。随着粒子束变得更短（fs尺度）或更复杂（微调制束），轮廓变得越来越难以测量。因此，必须能够以fs分辨率、非破坏性地并且在单次激发中确定时间剖面。如果没有这种能力，将很难满足下一代光源的标准（产生光谱稳定，高强度和亮度的X射线脉冲），并进一步提高尾场加速器的性能。该项目的目标是：1/设计和制造基于相干Smith-Purcell辐射的单次纵向束团轮廓监测器的第一个原型;2/将其安装在STFC设施（达雷斯伯里实验室，STFC）并进行调试;3/测量具有fs分辨率的束团轮廓并将结果与STFC的其他诊断设备的结果进行比较。4/撰写研究论文，完成并提交博士论文。这项工作将与FMB Oxford和CNOAA团队密切合作。这对于实现目标和项目成功至关重要。该设计将以最近的研究结果和以前制定的概念设计为基础。研究和概念设计得到了STFC（珠三角赠款和助学金）的支持。监测器的开发是JAI研究计划的一部分，概念设计的操作原理已经在FACET，SLAC（美国）和LUCX，KEK（日本）进行了测试。结果表明，相干史密斯珀塞尔辐射（cSPr）是高度极化的，而背景辐射不是。该属性将在监视器的设计中被利用，以最小化其尺寸和复杂性。为了减少时间和成本，第一个原型的建造将使用一些在FACET研究的原始多拍摄监视器的硬件。原型将有一个单一的光栅，22个光学通道（每个偏振11个通道）和光束定位监测器安装在真空室之前和之后。在0.2THz至1 THz频率范围内的11个频率处对cSPr信号进行采样和分析将实现10 fs分辨率。工业合作伙伴对该项目的参与对其成功至关重要。FMB牛津将带来其在粒子加速器诊断设计方面的专业知识和设计和测试监视器所需的专业技术知识。学生将在FMB设施工作，开发监视器的技术设计和测试其组件。FMB将在竞争激烈的商业环境中监督，指导和提供培训，扩大学生的经验，超越通常的学术框架。