Development of X-ray Wavefront Sensing Techniques for Adaptive Optics Control at the Advanced Photon Source

Q3 Physics and Astronomy Synchrotron Radiation News Pub Date : 2022-03-04 DOI:10.1080/08940886.2022.2066440

Xianbo Shi, Z. Qiao, L. Rebuffi, M. Wojcik, M. Highland, Matthew G. Frith, R. Harder, D. Shu, S. Mashrafi, J. Anton, S. Kearney, Max Wyman,, L. Assoufid

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Abstract

Introduction The planning and construction of new and upgraded high-brightness X-ray synchrotron and free electron laser sources, such as the Advanced Photon Source upgrade project (APS-U) [1], are driving numerous opportunities to advance X-ray science and technologies. At the same time, an increasing number of highly diverse beamline experiments demand wavefront-preserving adaptive X-ray optics with both high precision and flexibility. At the APS, significant effort has been devoted to developing next-generation adaptive and corrective optics combined with state-of-the-art at-wavelength wavefront sensing techniques and an intelligent feedback control system for the automation and self-alignment of beamline optical systems. This article reviews recent achievements in these areas at the APS [2–11]. These include the development of in-situ wavefront sensing [2, 3], the application in active feedback control of ultra-precision deformable mirrors [4, 5], and the exploration of non-invasive wavefront sensing techniques for adaptive optics and beamline diagnostics [6–8].

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先进光子源自适应光学控制x射线波前传感技术的发展

新的和升级的高亮度x射线同步加速器和自由电子激光源的规划和建设，如先进光子源升级项目(APS-U)[1]，为推进x射线科学和技术带来了许多机会。同时，越来越多的高度多样化的光束线实验要求保持波前的自适应x射线光学具有高精度和灵活性。APS致力于开发下一代自适应和校正光学，结合最先进的波长波前传感技术和用于光束线光学系统自动化和自对准的智能反馈控制系统。本文综述了APS在这些领域的最新成果[2-11]。其中包括原位波前传感的发展[2,3]，在超精密变形镜主动反馈控制中的应用[4,5]，以及自适应光学和光束线诊断的非侵入性波前传感技术的探索[6-8]。

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Synchrotron Radiation News Physics and Astronomy-Nuclear and High Energy Physics

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1.30

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