利用光学随机结晶实现稳态微束化

M. WallbankFermi National Accelerator Laboratory, J. JarvisFermi National Accelerator Laboratory
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摘要

光学随机冷却(OSC)是一种最先进的光束冷却技术,2021年首次在费米实验室FAST设施的IOTA存储环上进行了演示。该研究计划的第二阶段计划于 2025 年初开始运行,并将纳入一个光放大器,以实现显著提高的冷却速率和更大的操作灵活性。除了光束冷却之外,还可以对 OSC 系统进行配置,以实现对光束相空间的高级控制。一种示例操作模式可以实现结晶,在这种模式下,粒子束中的粒子在 OSC 基本波长处被锁定为自我强化的规则微结构;我们称之为光学随机结晶 (OSX)。OSX 是实现稳态微束化(SSMB)的新途径,它可以使光源兼具自由电子激光器的高亮度和存储环的高重复率。这种光源的应用范围从太赫兹到极紫外(EUV),包括用于半导体光刻的高功率 EUV 生成。本文将讨论 OSC 实验计划的现状及其在即将开始的实验运行中首次演示SSMB 的潜力。
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Realizing Steady-State Microbunching with Optical Stochastic Crystallization
Optical Stochastic Cooling (OSC) is a state-of-the-art beam cooling technology first demonstrated in 2021 at the IOTA storage ring at Fermilab's FAST facility. A second phase of the research program is planned to run in early 2025 and will incorporate an optical amplifier to enable significantly increased cooling rates and greater operational flexibility. In addition to beam cooling, an OSC system can be configured to enable advanced control over the phase space of the beam. An example operational mode could enable crystallization, where the particles in a bunch are locked into a self-reinforcing, regular microstructure at the OSC fundamental wavelength; we refer to this as Optical Stochastic Crystallization (OSX). OSX represents a new path toward Steady-State Microbunching (SSMB), which may enable light sources combining the high brightness of a free-electron laser with the high repetition rate of a storage ring. Such a source has applications from the terahertz to the extreme ultraviolet (EUV), including high-power EUV generation for semiconductor lithography. This contribution will discuss the status of the OSC experimental program and its potential to achieve the first demonstration of SSMB during the upcoming experimental run.
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