Megahertz-rate ultrafast X-ray scattering and holographic imaging at the European XFEL

Hagström, Nanna Zhou; Schneider, Michael; Kerber, Nico; Yaroslavtsev, Alexander; Burgos-Parra, Erick; Beg, Marijan; Lang, Martin; Günther, C.; Seng, Boris; Kammerbauer, Fabian; Popescu, Horia; Pancaldi, Matteo; Neeraj, Kumar; Polley, Debanjan; Jangid, Rahul; Hrkac, Stjepan; Patel, Sheena K. K.; Ovcharenko, Sergei; Turenne, Diego; Ksenzov, Dmitriy; Boeglin, C.; Байдакова, М. В.; Schmising, Clemens von Korff; Borchert, Martin; Vodungbo, Boris; Chen, Kai; Luo, Chen; Radu, F.; Müller, Leonard; Martínez, Flórez, Miriam; Philippi-Kobs, André; Riepp, Matthias; Roseker, Wojciech; Grübel, G.; Carley, Robert; Schlappa, Justine; Kuiken, Benjamin E. Van; Gort, Rafael; Mercadier, Laurent; Agarwal, Naman; Guyader, Löic Le; Mercurio, Giuseppe; Teichmann, Martin; Delitz, Jan Torben; Reich, Alexander; Broers, Carsten; Hickin, David; Deiter, C.; Moore, James W.; Rompotis, Dimitrios; Wang, Jinxiong; Kane, Daniel; Venkatesan, Sandhya; Meier, Joachim; Pallas, Florent; Jeżyński, Tomasz; Lederer, Maximilian; Boukhelef, Djelloul; Szuba, J.; Wrona, K.; Hauf, Steffen; Zhu, Jun; Bergemann, Martin; Kamil, E.; Kluyver, Thomas; Robert, Rosca,; Spirzewski, Michał; Kuster, M.; Turcato, M.; Lomidze, D.; Samartsev, A.; Engelke, Jan; Porro, M.; Maffessanti, S.; Hansen, Karsten; Erdinger, Florian; Fischer, P.; Fiorini, C.; Castoldi, A.; Manghisoni, M.; Wunderer, C.; Fullerton, Eric E.; Shpyrko, Oleg; Gutt, Christian; Sánchez-Hanke, Cecilia; Dürr, H. A.; Iacocca, Ezio; Nembach, Hans T.; Keller, Mark W.; Shaw, Justin M.; Silva, Thomas J.; Kukreja, Roopali; Fangohr, Hans; Eisebitt, Stefan; Kläui, Mathias; Jaouen, N.; Scherz, Andreas; Bonetti, Stefano; Jal, Emmanuelle

doi:10.1107/s1600577522008414

Cited by 9 publications

(2 citation statements)

References 66 publications

(43 reference statements)

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“…The X-ray scattering is collected on the DSSC 2D detector, able to match the repetition rate of the XFEL [35]. The DSSC records data at twice the X-ray repetition rate in order to collect so-called "dark" data frames in between pulses for the best background correction [36]. The sample to detector distance is fixed to 3 m.…”

Section: Methodsmentioning

confidence: 99%

Symmetry-dependent ultrafast manipulation of nanoscale magnetic domains

Hagström¹,

Jangid²,

Madhavi³

et al. 2022

Phys. Rev. B

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Section: Methodsmentioning

confidence: 99%

Symmetry-dependent ultrafast manipulation of nanoscale magnetic domains

Hagström¹,

Jangid²,

Madhavi³

et al. 2022

Phys. Rev. B

Self Cite

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“…The macrobunch structure of the Eu-XFEL perhaps presents the most challenging conditions and therefore requirements of an optical laser source to support ultrafast studies. The development and operation of the high-end burst laser system at Eu-XFEL − is a good example of current technology and limits to application. , The PP laser system is capable of running up to a 4.5 MHz repetition rate, and the fundamental was designed to be at 800 nm, supporting pulse durations of as short as 15 fs in the fundamental. Frequency conversion, besides SHG and THG, is done using conventional colinear OPAs that can support up to a 1.1 MHz repetition rate at Eu-XFEL.…”

Section: Introductionmentioning

confidence: 99%

XFEL Beamline Optical Instrumentation for Ultrafast Science

Hutchison,

Perrett,

van Thor

2024

J. Phys. Chem. B

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Free electron lasers operating in the soft and hard X-ray regime provide capabilities for ultrafast science in many areas, including X-ray spectroscopy, diffractive imaging, solution and material scattering, and X-ray crystallography. Ultrafast timeresolved applications in the picosecond, femtosecond, and attosecond regimes are often possible using single-shot experimental configurations. Aside from X-ray pump and X-ray probe measurements, all other types of ultrafast experiments require the synchronized operation of pulsed laser excitation for resonant or nonresonant pumping. This Perspective focuses on the opportunities for the optical control of structural dynamics by applying techniques from nonlinear spectroscopy to ultrafast X-ray experiments. This typically requires the synthesis of two or more optical pulses with full control of pulse and interpulse parameters. To this end, full characterization of the femtosecond optical pulses is also highly desirable. It has recently been shown that two-color and two-pulse femtosecond excitation of fluorescent protein crystals allowed a Tannor-Rice coherent control experiment, performed under characterized conditions. Pulse shaping and the ability to synthesize multicolor and multipulse conditions are highly desirable and would enable XFEL facilities to offer capabilities for structural dynamics. This Perspective will give a summary of examples of the types of experiments that could be achieved, and it will additionally summarize the laser, pulse shaping, and characterization that would be recommended as standard equipment for time-resolved XFEL beamlines, with an emphasis on ultrafast time-resolved serial femtosecond crystallography.

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Probing Laser‐Driven Structure Formation at Extreme Scales in Space and Time

Bonse,

Sokolowski‐Tinten

2024

Laser & Photonics Reviews

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Irradiation of solid surfaces with high intensity, ultrashort laser pulses triggers a variety of secondary processes that can lead to the formation of transient and permanent structures over a large range of length scales from mm down to the nano‐range. One of the most prominent examples are LIPSS – Laser‐Induced Periodic Surface Structures. While LIPSS have been a scientific evergreen for of almost 60 years, experimental methods that combine ultrafast temporal with the required nm spatial resolution have become available only recently with the advent of short pulse, short wavelength free electron lasers. Here, the current status and future perspectives in this field are discussed by exploiting the unique possibilities of these 4th‐generation light sources to address by time‐domain experimental techniques the fundamental LIPSS‐question, namely why and how laser irradiation can initiate the transition of a “chaotic” (rough) surface from an aperiodic into a periodic structure.

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Megahertz-rate ultrafast X-ray scattering and holographic imaging at the European XFEL

Cited by 9 publications

References 66 publications

Symmetry-dependent ultrafast manipulation of nanoscale magnetic domains

Symmetry-dependent ultrafast manipulation of nanoscale magnetic domains

XFEL Beamline Optical Instrumentation for Ultrafast Science

Probing Laser‐Driven Structure Formation at Extreme Scales in Space and Time

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