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将日本兵库县的SPring-8进行绿色升级,以产生稳定、超亮的硬X射线束。

Green upgrading of SPring-8 to produce stable, ultrabrilliant hard X-ray beams.

作者信息

Tanaka Hitoshi, Watanabe Takahiro, Abe Toshinori, Azumi Noriyoshi, Aoki Tsuyoshi, Dewa Hideki, Fujita Takahiro, Fukami Kenji, Fukui Toru, Hara Toru, Hiraiwa Toshihiko, Imamura Kei, Inagaki Takahiro, Iwai Eito, Kagamihata Akihiro, Kawase Morihiro, Kida Yuichiro, Kondo Chikara, Maesaka Hirokazu, Magome Tamotsu, Masaki Mitsuhiro, Masuda Takemasa, Matsubara Shinichi, Matsui Sakuo, Ohshima Takashi, Oishi Masaya, Seike Takamitsu, Shoji Masazumi, Soutome Kouichi, Sugimoto Takashi, Suzuki Shinji, Tajima Minori, Takano Shiro, Tamura Kazuhiro, Tanaka Takashi, Taniuchi Tsutomu, Taniuchi Yukiko, Togawa Kazuaki, Tomai Takato, Ueda Yosuke, Yamaguchi Hiroshi, Yabashi Makina, Ishikawa Tetsuya

机构信息

RIKEN SPring-8 Center, 1-1-1 Kouto, Sayo, Hyogo 679-5148, Japan.

Japan Synchrotron Radiation Research Institute (JASRI), 1-1-1 Kouto, Sayo, Hyogo 679-5198, Japan.

出版信息

J Synchrotron Radiat. 2024 Nov 1;31(Pt 6):1420-1437. doi: 10.1107/S1600577524008348. Epub 2024 Oct 24.

DOI:10.1107/S1600577524008348
PMID:39443835
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11542666/
Abstract

SPring-8-II is a major upgrade project of SPring-8 that was inaugurated in October 1997 as a third-generation synchrotron radiation light source. This upgrade project aims to achieve three goals simultaneously: achievement of excellent light source performance, refurbishment of aged systems, and significant reduction in power consumption for the entire facility. A small emittance of 50 pm rad will be achieved by (1) replacing the existing double-bend lattice structure with a five-bend achromat one, (2) lowering the stored beam energy from 8 to 6 GeV, (3) increasing the horizontal damping partition number from 1 to 1.3, and (4) enhancing horizontal radiation damping by installing damping wigglers in long straight sections. The use of short-period in-vacuum undulators allows ultrabrilliant X-rays to be provided while keeping a high-energy spectral range even at the reduced electron-beam energy of 6 GeV. To reduce power consumption, the dedicated, aged injector system has been shut down and the high-performance linear accelerator of SACLA, a compact X-ray free-electron laser (XFEL) facility, is used as the injector of the ring in a time-shared manner. This allows the simultaneous operation of XFEL experiments at SACLA and full/top-up injection of the electron beam into the ring. This paper overviews the concept of the SPring-8-II project, the system design of the light source and the details of the accelerator component design.

摘要

SPring-8-II是SPring-8的一个重大升级项目,它于1997年10月落成,作为第三代同步辐射光源。该升级项目旨在同时实现三个目标:实现优异的光源性能、翻新老化系统以及大幅降低整个设施的功耗。通过以下方式将实现50 pm rad的小发射度:(1) 用五弯消色差结构取代现有的双弯晶格结构;(2) 将储存束流能量从8 GeV降至6 GeV;(3) 将水平阻尼分区数从1提高到1.3;(4) 通过在长直段安装阻尼波荡器增强水平辐射阻尼。使用短周期真空型波荡器可在电子束能量降至6 GeV的情况下仍保持高能谱范围的同时提供极亮的X射线。为降低功耗,已关闭专用的老化注入器系统,并分时使用紧凑型X射线自由电子激光(XFEL)设施SACLA的高性能直线加速器作为环的注入器。这使得能够同时在SACLA进行XFEL实验以及将电子束全能量/满能量注入环中。本文概述了SPring-8-II项目的概念、光源的系统设计以及加速器部件设计的细节。

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