A MHz-repetition-rate hard X-ray free-electron laser driven by a superconducting linear accelerator

Decking, Winfried; Abeghyan, Suren; Abramian, P.; Abramsky, A.; Aguirre, Aaron D.; Albrecht, C.; Alou, P.; Altarelli, M.; Altmann, P.; Amyan, K.; Anashin, V.V.; Apostolov, Evstati; Appel, Karen; Auguste, Didier; Ayvazyan, V.; Baark, S.; Babies, F.; Baboi, N.; Bak, P. A.; Balandin, V.; Baldinger, R.; Baranasic, B.; Barbanotti, S.; Belikov, Oleg; Belokurov, V. A.; Belova, L.; Belyakov, V. A.; Berry, S.; Bertucci, Michele; Beutner, Bolko; Block, Andreas; Blöcher, M.; Böckmann, T.; Bohm, C.; Böhnert, M.; Bondar, V. A.; Bondarchuk, E. N.; Bonezzi, M.; Borowiec, Pawel; Bosch, Coleen S.; Bösenberg, Ulrike; Bosotti, A.; Böspflug, R.; Bousonville, Michael; Boyd, E.; Bozhko, Y.; Brand, André; Branlard, Julien; Briechle, S.; Brinker, Frank; Brinker, Sascha; Brinkmann, R.; Brockhauser, Sándor; Brovko, Oleg; Brück, H.; Brüdgam, A.; Butkowski, Łukasz; Büttner, T.; Calero, J.; Castro-Carballo, E.; Cattalanotto, G.; Charrier, Joël; Chen, J.; Cherepenko, A.; Cheskidov, V. G.; Chiodini, Marco; Chong, Andy; Choroba, S.; Chorowski, M.; Churanov, D V; Cichalewski, W.; Clausen, M.; Clement, William Andrew; Cloué, Christelle; Cobos, J.A.; Coppola, N.; Cunis, S.; Czuba, Krzysztof; Czwalinna, Marie Kristin; Dalmagne, B.; Dammann, J.A.; Danared, H.; Wagner, Albrecht; Delfs, A.; Delfs, T.; Dietrich, Florian; Dietrich, Tom; Dohlus, M.; Dommach, M.; Donat, A.; Dong, Xiaohao; Doynikov, N.; Dressel, M.; Duda, Martin; Duda, P.; Eckoldt, Hans-Jörg; Ehsan, Wajid; Eidam, J.; Eints, F.; Engling, Claudia; Englisch, Uwe; Ермаков, А.; Escherich, K.; Eschke, J.; Saldin, Evgeni; Faesing, M.; Fallou, A.; Felber, M.; Fenner, Michael; Fernandes, Bruno; Fernández, José M.; Feuker, S.; Filippakopoulos, K.; Floettmann, K.; Fogel, V.; Fontaine, M.; Frances, Airan; Martín, Idoia Freijo; Freund, Wolfgang; Freyermuth, T.; Friedland, Michael; Fröhlich, Lars; Fusetti, M.; Fydrych, J.; Gallas, A.; García, Oscar; García-Tabarés, L.; Geloni, Gianluca; Gerasimova, Natalia; Gerth, Ch.; Geßler, P.; Gharibyan, V.; Gloor, M.; Głowinkowski, J.; Goessel, A.; Gołębiewski, Z.; Golubeva, N.; Grabowski, W.; Graeff, W.; Grebentsov, Alexander; Grecki, M.; Grevsmuehl, T.; Groß, Matthias; Grosse‐Wortmann, Uwe; Grünert, Jan; Grünewald, S.; Grzegory, P.; Gao, Feng; Güler, H.; Gusev, G.; Gutiérrez, Jose Luis; Hagge, Lars; Hamberg, Mathias; Hanneken, R.; Harms, E.; Hartl, Ingmar; Hauberg, A.; Hauf, Steffen; Hauschildt, J.; Hauser, Jens; Havlíček, Jan; Hedqvist, Anders; Heidbrook, Niels; Hellberg, F.; Henning, Denis; Hensler, O.; Hermann, Tobias; Hidvégi, A.; Hierholzer, M.; Hintz, Heiko; Hoffmann, Frank; Hoffmann, M.; Hoffmann, Matthias; Holler, Y.; Hüning, M.; Ignatenko, Alexandr; Ilchen, Markus; Iluk, A.; Iversen, J.; Izquierdo, M.; Jachmann, L.; Jardon, N.; Jastrow, U.; Jensch, Kay; Jensen, J.; Jeżabek, M.; Jidda, M.; Jin, Hyunchang; Johannson, N.; Jonas, R.; Kaabi, W.; Kaefer, Daniela; Kammering, R.; Kapitza, H.; Karabekyan, S.; Karstensen, S.; Kasprzak, Karol; Katalev, V.; Keese, D.; Keil, Boris; Kholopov, M.A.; Killenberger, M.; Kitaev, B.; Klimchenko, Y.; Klos, Ronald; Knebel, Lennart; Koch, Andreas; Koepke, M. E.; Köhler, Sebastian; Köhler, W.; Kohlstrunk, N.; Konôpková, Zuzana; Konstantinov, A. O.; Kook, W.; Koprek, Waldemar; Körfer, M.; Korth, Olaf; Kosarev, А. А.; Kosiński, K.; Kostin, D.; Kot, Yauhen; Kotarba, A.; Kozak, Tomasz; Козак, В. Р.; Kramert, R.; Krasilnikov, M.; Краснов, А. А.; Krause, B.; Kravchuk, L.; Krebs, Olaf; Kretschmer, R.; Kreutzkamp, J.; Kröplin, O.; Krzysik, Krzysztof; Kube, G.; Kuehn, H.; Kujala, Naresh; Kulikov, V.; Kuzminych, V.; Civita, Daniele La; Lacroix, M.; Lamb, Thorsten; Lancetov, A.; Larsson, Mårten; Pinvidic, David Le; Lederer, S.; Lensch, Timmy-Jan; Lenz, Dan; Leuschner, A.; Levenhagen, F.; Li, Y.; Liebing, J.; Lilje, L.; Limberg, T.; Lipka, D.; List, B.; Liu, J.; Liu, S.; Lorbeer, B.; Lorkiewicz, J.; Lu, Huihua; Ludwig, Frank; Machau, Karsten; Maciocha, W.; Madec, Catherine; Magueur, Christopher; Maiano, C.; Maksimova, Irina L.; Malcher, K.; Maltezopoulos, Theophilos; Mamoshkina, E.V.; Manschwetus, Bastian; Marcellini, F.; Marinković, Goran; Martı́nez, T.; Martirosyan, H.; Maschmann, W.; Maslov, M.; Matheisen, A.; Mavrič, Uroš; Meißner, J.; Meißner, K. W.; Messerschmidt, Marc; Meyners, N.; Michalski, G.; Michelato, P.; Mildner, N.; Moe, M. K.; Moglia, Francesca; Mohr, Christian; Mohr, S.; Möller, W.-D.; Mommerz, M.; Monaco, Laura; Montiel, C.; Moretti, Massimiliano; Морозов, И. И.; Morozov, Petr; Mross, David F.; Mueller, J.J.; Müller, Carsten; Müller, Jost; Müller, K.P.; Munilla, Javier; Münnich, A.; Muratov, V. R.; Napoly, O.; Naser, Ban A.; Nefedov, N.; Neumann, R.; Neumann, Rudolf; Ngada, N.; Noelle, D.; Obier, F.; Okunev, I.N.; Oliver, J. A.; Omet, Mathieu; Oppelt, A.; Ottmar, Andrey; Oublaid, Maryam; Pagani, C.; Paparella, Rocco; Paramonov, V.; Peitzmann, C.; Penning, Jan; Perus, A.; Peters, F.; Petersen, B.; Petrov, Alexander Yu.; Petrov, Ilia; Pfeiffer, Sven; Pflüger, J.; Philipp, Sebastian; Pienaud, Y.; Pierini, P.; Pivovarov, S.; Planas, Marc; Pławski, E.; Pohl, Martin; Poliński, J.; Popov, V.; Prat, S.; Prenting, J.; Priebe, G.; Pryschelski, Heinrich; Przygoda, Konrad; Pyata, E.E.; Racky, B.; Rathjen, A.; Ratuschni, W.; Regnaud-Campderros, S.; Rehlich, K.; Reschke, D.; Robson, C.C.W.; Roever, Jan; Roggli, M.; Rothenburg, Jens; Rusiński, E.; Rybaniec, Radosław; Sahling, H.; Salmani, M.; Samoylova, Liubov; Sanzone, D.; Saretzki, F.; Sawlanski, Olaf; Schaffran, J.; Schlarb, H.; Schlosser, Markus E.; Schlott, V.; Schmidt, Carlo; Schmidt-Foehre, F.; Schmitz, M.; Schmökel, Manuela; Schnautz, T; Schneidmiller, E.A.; Scholz, Matthias; Schöneburg, B.; Schultze, J.; Schulz, Claus-Peter; Schwarz, A. S.; Sekutowicz, J.; Sellmann, D.; Semenov, E. S.; Serkez, Svitozar; Sertore, D.; Shehzad, Nadeem; Shemarykin, P.; Shi, Lei; Sienkiewicz, Michał; Sikora, Dominik; Sikorski, Marcin; Silenzi, A.; Simon, Claire; Singer, W.; Singer, X.; Sinn, H.; Sinram, K.; Skvorodnev, N.; Smirnow, P.; Sommer, T.; Сорокин, А. А.; Stadler, Markus; Steckel, M.; Steffen, B.; Steinhau-Kühl, Nicolai; Stephan, F.; Stodulski, M.; Stolper, M.; Сулимов, А. А.; Susen, Rainer; Świerblewski, Jacek; Sydlo, Cezary; Syresin, E. M.; Sytchev, V.; Szuba, J.; Tesch, N.; Thie, Jan-Hendrik; Thiébault, Alice; Tiedtke, K.; Tischhauser, D.; Tolkiehn, J.; Tomin, Sergey; Tonisch, F.; Toral, Fernando; Torbin, I. D.; Trapp, Alexander; Treyer, Daniel; Trowitzsch, G.; Trublet, Thierry; Tschentscher, Thomas; Ullrich, F.; Vannoni, Maurizio; Varela, Pablo Gabriel; Varghese, G.; Vashchenko, G.; Vasić, Miroslav; Vazquez-Velez, C.; Verguet, A.; Vilcins-Czvitkovits, Silke; Villanueva, R.; Visentin, B.; Viti, M.; Vogel, Elmar; Volobuev, E.; Wagner, R.; Walker, Nick; Wamsat, Thomas; Weddig, Henning; Weichert, G.; Weise, H.; Wenndorf, R.; Werner, Michael; Wichmann, Romy; Wiebers, C.; Wiencek, Mateusz; Wilksen, T.; Will, I.; Winkelmann, L.; Winkowski, Mateusz; Wittenburg, K.; Witzig, Andreas; Wlk, P.; Wohlenberg, T.; Wojciechowski, M.; Wolff-Fabris, F.; Wrochna, G.; Wrona, K.; Yakopov, Mikhail; Yang, B. X.; Yang, Fujia; Yurkov, M.V.; Zagorodnov, Igor; Zalden, Peter; Zavadtsev, A. A.; Zavadtsev, D. A.; Жирнов, А. Д.; Жуков, А. А.; Ziemann, Volker; Zolotov, A. N.; Zolotukhina, N.; Zummack, Falco; Zybin, D.

doi:10.1038/s41566-020-0607-z

Cited by 379 publications

(211 citation statements)

References 31 publications

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“…The advancing XFELs feature super-conducting accelerator technologies which boost further the brilliance of the current XFEL sources reaching MHz repetition rates. [5][6][7][8] X-ray Photon Correlation Spectroscopy (XPCS) [9][10][11][12][13][14][15][16] is a coherent scattering technique that benefits particularly from this increase in coherent flux holding the potential of capturing structural dynamics at variable length scales, ranging from the nanoscale down to atomic scales. [17][18][19][20] One distinct advantage of XPCS experiments employing the new X-ray sources is the possibility to study dynamics in transient samples (e.g., deeply supercooled water) which are only stable for a short period of time.…”

Section: Introductionmentioning

confidence: 99%

Towards molecular movies with X-ray photon correlation spectroscopy

Perakis

Gutt

2020

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Towards molecular movies with X-ray photon correlation spectroscopy

Perakis

Gutt

2020

Phys. Chem. Chem. Phys.

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“…X-ray free-electron-lasers (XFELs) are state-of-the-art research instruments that have revolutionized science by enabling the observation of matter at atomic length and time scales [1][2][3][4][5][6][7][8][9][10]. The FEL process is driven by a highbrightness electron beam that travels through an undulator.…”

Section: Introductionmentioning

confidence: 99%

High-resolution dispersion-based measurement of the electron beam energy spread

Prat

Dijkstal

Malyzhenkov

et al. 2020

Phys. Rev. Accel. Beams

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The energy spread of the electron beam is a critical parameter in x-ray free-electron lasers (XFELs) and needs to be optimized for best performance. The uncorrelated energy spread of the electrons can be a few keV or less in XFEL injectors, thus very challenging to measure. The standard method to characterize the electron beam energy spread, consisting in streaking the beam with a transverse deflector and measuring the time-resolved beam size of the electrons in a dispersive location for a single electron beam energy, has a typical resolution of several keV. To overcome this limitation we introduce a novel method to measure the beam size at a dispersive location for different beam energies so that it is possible to disentangle the beam size contributions related to the energy spread, the intrinsic beam size and the monitor resolution. As a consequence, the energy spread can be characterized with a much higher precision and resolution than in the standard approach. We also suggest to perform measurements for different deflection amplitudes so that the energy spread induced by the transverse deflector can be subtracted properly. The scheme does not require any additional hardware and thus can be readily applied in any standard XFEL facility. Numerical simulations and experimental results at SwissFEL confirm the validity of our method. Our calculations show that the approach can be used to significantly overcome the resolution of the standard approach and measure energy spreads well below 1 keV. As an example we present energy spreads of few keV measured at the SwissFEL injector.

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“…The extreme peak brightness and ultrashort pulses provided by X-ray free-electron lasers (XFEL) [1][2][3][4][5] allow data collection from micrometersized protein crystals at room temperature (the functional temperature of their constituent molecules) while outrunning radiation damage. This 'diffraction-before-destruction approach' has been applied in serial femtosecond crystallography (SFX), which has revolutionized X-ray crystallography and has been considered an important tool to determine the structure of proteins that are di cult to crystallize [6][7][8][9] .…”

Section: Introductionmentioning

confidence: 99%

High-Brightness Self-seeded X-ray Free Electron Laser to Precisely Map Macromolecular Structure

Kang

Min

Nam

et al. 2020

Preprint

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We demonstrate a hard-X-ray self-seeded (HXRSS) free-electron laser (FEL) at Pohang Accelerator Laboratory with an unprecedented peak brightness (3.2 × 1035 photons/(s·mm2·mrad2·0.1%BW)). The self-seeded FEL generates hard X-ray pulses with improved spectral purity; the average pulse energy was 0.85 mJ at 9.7 keV, almost as high as in SASE mode; the bandwidth (0.19 eV) is about 1/70 as wide, the peak spectral brightness is 40 times higher than in self-amplified spontaneous emission (SASE) mode, and the stability is excellent with > 94% of shots exceeding the average SASE intensity. Using this self-seeded XFEL, we conducted serial femtosecond crystallography (SFX) experiments to map the structure of lysozyme protein; data-quality metrics such as Rsplit, multiplicity, and signal-to-noise ratio for the SFX were substantially increased. We precisely map out the structure of lysozyme protein with substantially better statistics for the diffraction data and significantly sharper electron density maps compared to maps obtained using SASE mode.

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A MHz-repetition-rate hard X-ray free-electron laser driven by a superconducting linear accelerator

Cited by 379 publications

References 31 publications

Towards molecular movies with X-ray photon correlation spectroscopy

Towards molecular movies with X-ray photon correlation spectroscopy

High-resolution dispersion-based measurement of the electron beam energy spread

High-Brightness Self-seeded X-ray Free Electron Laser to Precisely Map Macromolecular Structure

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