X-ray diffraction performance of thermally distorted crystals

IF 5.2 1区 物理与天体物理 Q1 OPTICS High Power Laser Science and Engineering Pub Date : 2023-07-05 DOI:10.1017/hpl.2023.56
Chuan Yang, T. Liu, Kai Hu, Ye Zhu, Xiaohao Dong, Zhongmin Xu, C. Feng, Weiqing Zhang
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Abstract

Abstract The development of high-brightness X-ray free electron lasers (XFELs), such as hard X-ray self-seeding free electron lasers and XFEL oscillators (XFELOs), brings a severe challenge to the crystal monochromator due to a strong non-uniform thermal load. The distortion caused by spatial temperature gradients can severely affect the optical performance of crystals. Therefore, this paper presents a model to estimate the performance of non-uniform thermally distorted crystals. The model not only takes into account thermal strain, slope error and incident angle deviation, but also considers temperature-dependent factors such as the Debye–Waller factor and electric susceptibility. Our investigation indicates that the Debye–Waller factor reduces the height and bandwidth of rocking curves, and the impact of the electric susceptibility is tiny. The proposed model can describe the distortion of the reflectivity and transmissivity curves of non-uniform thermally loaded crystals and can be applied in the design of crystal monochromators, crystal splitters, crystal compressors and XFELOs.
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热变形晶体的x射线衍射性能
高亮度x射线自由电子激光器(XFELs)的发展,如硬x射线自播种自由电子激光器和XFEL振荡器(XFELOs),由于其强烈的非均匀热负载,给晶体单色仪带来了严峻的挑战。空间温度梯度引起的畸变会严重影响晶体的光学性能。因此,本文提出了一个模型来估计非均匀热畸变晶体的性能。该模型不仅考虑了热应变、斜率误差和入射角偏差,还考虑了与温度相关的Debye-Waller因子和电敏感性等因素。我们的研究表明,Debye-Waller因子降低了摇摆曲线的高度和带宽,而电磁化率的影响很小。该模型可以描述非均匀热负载晶体的反射率和透射率曲线的畸变,可用于晶体单色仪、晶体分配器、晶体压缩器和XFELOs的设计。
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来源期刊
High Power Laser Science and Engineering
High Power Laser Science and Engineering Physics and Astronomy-Nuclear and High Energy Physics
CiteScore
7.10
自引率
4.20%
发文量
401
审稿时长
21 weeks
期刊介绍: High Power Laser Science and Engineering (HPLaser) is an international, peer-reviewed open access journal which focuses on all aspects of high power laser science and engineering. HPLaser publishes research that seeks to uncover the underlying science and engineering in the fields of high energy density physics, high power lasers, advanced laser technology and applications and laser components. Topics covered include laser-plasma interaction, ultra-intense ultra-short pulse laser interaction with matter, attosecond physics, laser design, modelling and optimization, laser amplifiers, nonlinear optics, laser engineering, optical materials, optical devices, fiber lasers, diode-pumped solid state lasers and excimer lasers.
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