M Sauppe, T Bischoff, C Bomme, C Bostedt, A Colombo, B Erk, T Feigl, L Flückiger, T Gorkhover, A Heilrath, K Kolatzki, Y Kumagai, B Langbehn, J P Müller, C Passow, D Ramm, D Rolles, D Rompotis, J Schäfer-Zimmermann, B Senfftleben, R Treusch, A Ulmer, J Zimbalski, T Möller and D Rupp
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We present a technique to track x-ray induced structural changes in time and space by recording two consecutive diffraction patterns of the same single, free-flying nanoparticle, acquired separately on two large-area detectors opposite to each other, thus examining both the initial and evolved particle structure. We demonstrate the method at the extreme ultraviolet (XUV) and soft x-ray Free-electron LASer in Hamburg (FLASH), investigating xenon clusters as model systems. By splitting a single XUV pulse, two diffraction patterns from the same particle can be obtained. For focus intensities of about W cm−2 we observe still largely intact clusters even at the longest delays of up to 650 picoseconds of the second pulse, indicating that in the highly absorbing systems the damage remains confined to one side of the cluster. Instead, in case of five times higher flux, the diffraction patterns show clear signatures of disintegration, namely increased diameters and density fluctuations in the fragmenting clusters. 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引用次数: 0
摘要
由于 X 射线自由电子激光器(FEL)具有高光子通量,因此可以在单个 X 射线脉冲内通过相干衍射成像(CDI)解析单个纳米粒子的结构。由于样品不可避免的快速破坏限制了可实现的分辨率,因此透彻了解辐照后纳米尺度物质的时空演变至关重要。我们提出了一种在时间和空间上跟踪 X 射线诱导的结构变化的技术,即在两个相对的大面积探测器上分别记录同一单个自由飞行纳米粒子的两个连续衍射图样,从而检查粒子的初始结构和演变结构。我们在汉堡的极紫外(XUV)和软 X 射线自由电子激光仪(FLASH)上演示了这种方法,并将氙簇作为模型系统进行了研究。通过分离单个 XUV 脉冲,可以获得同一粒子的两种衍射图样。在聚焦强度约为 W cm-2 的情况下,即使第二个脉冲的延迟时间最长达 650 皮秒,我们也能观察到基本完好无损的星团,这表明在高吸收系统中,损伤仍局限于星团的一侧。相反,在通量高出五倍的情况下,衍射图样显示出明显的解体特征,即直径增大和碎片星团的密度波动。本文讨论了该方法在动态范围和时间分辨率方面的未来改进。
Double diffraction imaging of x-ray induced structural dynamics in single free nanoparticles
Because of their high photon flux, x-ray free-electron lasers (FEL) allow to resolve the structure of individual nanoparticles via coherent diffractive imaging (CDI) within a single x-ray pulse. Since the inevitable rapid destruction of the sample limits the achievable resolution, a thorough understanding of the spatiotemporal evolution of matter on the nanoscale following the irradiation is crucial. We present a technique to track x-ray induced structural changes in time and space by recording two consecutive diffraction patterns of the same single, free-flying nanoparticle, acquired separately on two large-area detectors opposite to each other, thus examining both the initial and evolved particle structure. We demonstrate the method at the extreme ultraviolet (XUV) and soft x-ray Free-electron LASer in Hamburg (FLASH), investigating xenon clusters as model systems. By splitting a single XUV pulse, two diffraction patterns from the same particle can be obtained. For focus intensities of about W cm−2 we observe still largely intact clusters even at the longest delays of up to 650 picoseconds of the second pulse, indicating that in the highly absorbing systems the damage remains confined to one side of the cluster. Instead, in case of five times higher flux, the diffraction patterns show clear signatures of disintegration, namely increased diameters and density fluctuations in the fragmenting clusters. Future improvements to the accessible range of dynamics and time resolution of the approach are discussed.
期刊介绍:
New Journal of Physics publishes across the whole of physics, encompassing pure, applied, theoretical and experimental research, as well as interdisciplinary topics where physics forms the central theme. All content is permanently free to read and the journal is funded by an article publication charge.