软 X 射线自由电子激光器的双束播种

E. Schneidmiller, I. Zagorodnov
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摘要

有源自由电子激光器(FEL)具有良好的性能,并成功应用于不同用户的极紫外和软 X 射线实验中。本文提出了对播种方案的一个简单修改,即依靠产生两个具有截然不同特性的紧密间隔束:一个低电流播种束和一个放大由播种束产生的相干辐射的高电流束。这种方法可以消除不同的限制,并减轻标准方案中的一些有害影响。特别是,在简单的高增益谐波发生(HGHG)方案中,可以用中等激光功率产生非常高的谐波数。或者,在谐波数适中的情况下,可以大大降低所需的激光功率,从而简化高重复率 FEL 的设计。光束动力学效应(如电子束纵向相空间的非线性、相干同步辐射、纵向空间电荷、几何唤醒场、微束流不稳定性等)对输出辐射特性(频谱展宽、基座、稳定性)的影响在很大程度上可以通过建议的方案来降低。在本文中,我们通过对软 X 射线用户设施 FLASH 进行真实的端到端模拟,说明了双束播种方案在 HGHG 配置中的运行情况。我们的研究表明,利用目前紧凑型设计的起落架系统,可以在 4 纳米波长上产生近傅立叶限的多兆瓦脉冲。
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Two-bunch seeding of soft X-ray free electron lasers
Seeded Free Electron Lasers (FELs) demonstrate a good performance and are successfully used in different user experiments in extreme ultraviolet and soft X-ray regimes. In this paper a simple modification of the seeding scenario is proposed relying on generation of two closely spaced bunches with very different properties: a low-current seeding bunch, and a high-current bunch that amplifies coherent radiation, produced by the seeding bunch. This approach eliminates different limitations and mitigates some harmful effects in the standard scenario. In particular, one can generate very high harmonic numbers with a moderate laser power in a simple high-gain harmonic generation (HGHG) scheme. Alternatively, in case of moderate harmonic numbers, one can strongly reduce the required laser power thus simplifying design of high repetition rate seeded FELs. An influence of beam dynamics effects (like nonlinearities of the longitudinal phase space of electron beams, coherent synchrotron radiation, longitudinal space charge, geometrical wakefields, microbunching instabilities etc.) on properties of output radiation (spectrum broadening, pedestals, stability) can be to a large extent reduced in the proposed scheme. In this paper we illustrate the operation of the two-bunch seeding scheme in HGHG configuration with realistic start-to-end simulations for the soft X-ray user facility FLASH. We show that nearly Fourier-limited multi-gigawatt pulses can be generated at 4 nm using the present compact design of the undulator system. With several thousand pulses per second this can be a unique source for photon science.
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