James Rosenzweig, G. Andonian, R. Agustsson, P. Anisimov, Aurora Araujo, Fabio Bosco, Martina Carillo, E. Chiadroni, L. Giannessi, Zhirong Huang, Atsushi Fukasawa, Dongsung Kim, S. Kutsaev, G. Lawler, Zenghai Li, N. Majernik, Pratik Manwani, J. Maxson, Janwei Miao, M. Migliorati, A. Mostacci, Pietro Musumeci, A. Murokh, E. Nanni, Sean O’Tool, L. Palumbo, R. Robles, Yusuke Sakai, E. Simakov, Madison Singleton, B. Spataro, Jingyi Tang, Sami Tantawi, Oliver Williams, Haoran Xu, M. Yadav
{"title":"A High-Flux Compact X-ray Free-Electron Laser for Next-Generation Chip Metrology Needs","authors":"James Rosenzweig, G. Andonian, R. Agustsson, P. Anisimov, Aurora Araujo, Fabio Bosco, Martina Carillo, E. Chiadroni, L. Giannessi, Zhirong Huang, Atsushi Fukasawa, Dongsung Kim, S. Kutsaev, G. Lawler, Zenghai Li, N. Majernik, Pratik Manwani, J. Maxson, Janwei Miao, M. Migliorati, A. Mostacci, Pietro Musumeci, A. Murokh, E. Nanni, Sean O’Tool, L. Palumbo, R. Robles, Yusuke Sakai, E. Simakov, Madison Singleton, B. Spataro, Jingyi Tang, Sami Tantawi, Oliver Williams, Haoran Xu, M. Yadav","doi":"10.3390/instruments8010019","DOIUrl":null,"url":null,"abstract":"Recently, considerable work has been directed at the development of an ultracompact X-ray free-electron laser (UCXFEL) based on emerging techniques in high-field cryogenic acceleration, with attendant dramatic improvements in electron beam brightness and state-of-the-art concepts in beam dynamics, magnetic undulators, and X-ray optics. A full conceptual design of a 1 nm (1.24 keV) UCXFEL with a length and cost over an order of magnitude below current X-ray free-electron lasers (XFELs) has resulted from this effort. This instrument has been developed with an emphasis on permitting exploratory scientific research in a wide variety of fields in a university setting. Concurrently, compact FELs are being vigorously developed for use as instruments to enable next-generation chip manufacturing through use as a high-flux, few nm lithography source. This new role suggests consideration of XFELs to urgently address emerging demands in the semiconductor device sector, as identified by recent national need studies, for new radiation sources aimed at chip manufacturing. Indeed, it has been shown that one may use coherent X-rays to perform 10–20 nm class resolution surveys of macroscopic, cm scale structures such as chips, using ptychographic laminography techniques. As the XFEL is a very promising candidate for realizing such methods, we present here an analysis of the issues and likely solutions associated with extending the UCXFEL to harder X-rays (above 7 keV), much higher fluxes, and increased levels of coherence, as well as methods of applying such a source for ptychographic laminography to microelectronic device measurements. We discuss the development path to move the concept to rapid realization of a transformative XFEL-based application, outlining both FEL and metrology system challenges.","PeriodicalId":13582,"journal":{"name":"Instruments","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2024-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Instruments","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.3390/instruments8010019","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"Physics and Astronomy","Score":null,"Total":0}
引用次数: 0
Abstract
Recently, considerable work has been directed at the development of an ultracompact X-ray free-electron laser (UCXFEL) based on emerging techniques in high-field cryogenic acceleration, with attendant dramatic improvements in electron beam brightness and state-of-the-art concepts in beam dynamics, magnetic undulators, and X-ray optics. A full conceptual design of a 1 nm (1.24 keV) UCXFEL with a length and cost over an order of magnitude below current X-ray free-electron lasers (XFELs) has resulted from this effort. This instrument has been developed with an emphasis on permitting exploratory scientific research in a wide variety of fields in a university setting. Concurrently, compact FELs are being vigorously developed for use as instruments to enable next-generation chip manufacturing through use as a high-flux, few nm lithography source. This new role suggests consideration of XFELs to urgently address emerging demands in the semiconductor device sector, as identified by recent national need studies, for new radiation sources aimed at chip manufacturing. Indeed, it has been shown that one may use coherent X-rays to perform 10–20 nm class resolution surveys of macroscopic, cm scale structures such as chips, using ptychographic laminography techniques. As the XFEL is a very promising candidate for realizing such methods, we present here an analysis of the issues and likely solutions associated with extending the UCXFEL to harder X-rays (above 7 keV), much higher fluxes, and increased levels of coherence, as well as methods of applying such a source for ptychographic laminography to microelectronic device measurements. We discuss the development path to move the concept to rapid realization of a transformative XFEL-based application, outlining both FEL and metrology system challenges.
最近,在高场低温加速新兴技术的基础上,超小型 X 射线自由电子激光器(UCXFEL)的研发工作取得了长足进展,电子束亮度随之大幅提高,光束动力学、磁起落器和 X 射线光学方面的概念也达到了最先进的水平。在这项工作的基础上,我们完成了 1 nm(1.24 keV)UCXFEL 的完整概念设计,其长度和成本比目前的 X 射线自由电子激光器(XFEL)低一个数量级。该仪器的开发重点是允许在大学环境中进行各种领域的探索性科学研究。与此同时,紧凑型 FEL 也在大力发展,以用作高通量、几纳米光刻源,从而实现下一代芯片制造。这一新角色建议考虑使用 XFEL 来紧急满足半导体设备领域新出现的需求,正如最近的国家需求研究报告所确定的,新辐射源的目标是芯片制造。事实上,已经有研究表明,可以利用相干 X 射线,通过层析成像技术,对芯片等厘米级的宏观结构进行 10-20 纳米分辨率的测量。由于 XFEL 是实现此类方法的一个非常有前途的候选方案,我们在此分析了与将 UCXFEL 扩展到更硬的 X 射线(7 千伏以上)、更高的通量和更高的相干水平相关的问题和可能的解决方案,以及将此类层析成像源应用于微电子设备测量的方法。我们讨论了从概念到快速实现基于 XFEL 的变革性应用的发展路径,概述了 FEL 和计量系统所面临的挑战。