Shock damage analysis in serial femtosecond crystallography data collected at MHz X-ray free-electron lasers

Gorel, A; Grünbein, ML; Bean, R; Bielecki, J; Hilpert, M; Cascella, M; Colletier, JP; Fangohr, H; Foucar, L; Hartmann, E; Hunter, MS; Kirkwood, Henry; Kloos, M; Letrun, R; Michelat, T; Shoeman, RL; Sztuk-Dambietz, J; Tetreau, G; Zimmermann, H; Mancuso, Adrian; Barends, TRM; Doak, RB; Stan, CA; Schlichting, I

doi:10.26181/60135e1bca85a

Shock damage analysis in serial femtosecond crystallography data collected at MHz X-ray free-electron lasers

journal contribution

posted on 2021-01-29, 01:00 authored by A Gorel, ML Grünbein, R Bean, J Bielecki, M Hilpert, M Cascella, JP Colletier, H Fangohr, L Foucar, E Hartmann, MS Hunter, Henry KirkwoodHenry Kirkwood, M Kloos, R Letrun, T Michelat, RL Shoeman, J Sztuk-Dambietz, G Tetreau, H Zimmermann, Adrian MancusoAdrian Mancuso, TRM Barends, RB Doak, CA Stan, I Schlichting

© 2020 by the authors. Serial femtosecond crystallography (SFX) data were recorded at the European X-ray free-electron laser facility (EuXFEL) with protein microcrystals delivered via a microscopic liquid jet. An XFEL beam striking such a jet may launch supersonic shock waves up the jet, compromising the oncoming sample. To investigate this efficiently, we employed a novel XFEL pulse pattern to nominally expose the sample to between zero and four shock waves before being probed. Analyzing hit rate, indexing rate, and resolution for diffraction data recorded at MHz pulse rates, we found no evidence of damage. Notably, however, this conclusion could only be drawn after careful identification and assimilation of numerous interrelated experimental factors, which we describe in detail. Failure to do so would have led to an erroneous conclusion. Femtosecond photography of the sample-carrying jet revealed critically different jet behavior from that of all homogeneous liquid jets studied to date in this manner.

Funding

This research was supported by the Max Planck Society and travel grants from the European XFEL. C.A.S. was supported by startup funds from Rutgers University-Newark. Contributions by J.-P.C. and G.T. were supported by the Agence Nationale de la Recherche (grants ANR-17-CE11-0018-01 to J.-P.C.).

History

Publication Date

2020-12-01

Journal

Crystals

Volume

10

Issue

12

Article Number

1145

Pagination

12p. (p. 1-12)

Publisher

Multidisciplinary Digital Publishing Institute (MDPI)

ISSN

2073-4352

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