Thermal Emittance Isolation by Cathode Retraction

arXiv - PHYS - Accelerator Physics Pub Date : 2024-09-05 DOI:arxiv-2409.03499

Benjamin Sims, John W. Lewellen, Xu Ting, Sergey V. Baryshev

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Abstract

In this work, a combination of cathode retraction and two-slit emittance measurement technique is proposed as an advanced means to individually modify emittance growth components, specifically, rf injector fringe fields, to isolate and directly measure the thermal emittance, the fundamental beam emittance metric for an electron beam. A case study of the LCLS-II-HE Low Emittance Injector (LEI), a state-of-the-art superconducting radiofrequency (SRF) gun, designed for LCLS-II HE upgrade is used to showcase the power of the two-slit technique. Particularly, it is demonstrated that generating a high resolution phase-space distribution map, dominated by the intrinsic emittance of the electron bunch, is possible. This result goes beyond the normal single-parameter distribution characterizations (e.g. RMS emittance and Twiss parameters) provided by the solenoid scan. One key feature making this technique work (and in the end practically useful) is the ability to retract the cathode, because it provides the ability to compensate for radiofrequency (rf) de-focusing. It is demonstrated how the cathode retraction can serve as an additional optimisation tool for tailoring the routine performance of the photoinjector. We posit that a variable position cathode may be a useful method for optimizing photoinjector performance across multiple parameters regimes.

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通过阴极回缩实现热辐射隔离

在这项工作中，提出了一种阴极回缩和双缝幅射测量技术的组合，作为单独修改幅射增长成分（特别是射频注入器边缘场）的先进手段，以分离和直接测量热幅射，这是电子束的基本束幅射指标。LCLS-II-HE 低幔度注入器（LEI）是最先进的超导射频（SRF）枪，专为 LCLS-II HE 升级而设计，通过对它的案例研究，展示了双缝技术的威力。特别是，它证明了生成由电子束本征发射率主导的高分辨率相空间分布图是可能的。这一结果超越了螺线管扫描所提供的常规单参数分布特性（例如均方根辐照度和捻度参数）。使这项技术发挥作用（并最终发挥实际作用）的一个关键特征是能够缩回阴极，因为它提供了补偿射频（rf）失焦的能力。我们展示了阴极缩回如何作为一种额外的优化工具，用于定制光电注射器的常规性能。我们认为，可变位置阴极可能是在多种参数条件下优化光注入器性能的有用方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Accelerator Physics

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