Journal of Synchrotron Radiation (Jul 2022)

Shot-to-shot two-dimensional photon intensity diagnostics within megahertz pulse-trains at the European XFEL

  • Trey W. Guest,
  • Richard Bean,
  • Johan Bielecki,
  • Sarlota Birnsteinova,
  • Gianluca Geloni,
  • Marc Guetg,
  • Raimund Kammering,
  • Henry J. Kirkwood,
  • Andreas Koch,
  • David M. Paganin,
  • Grant van Riessen,
  • Patrik Vagovič,
  • Raphael de Wijn,
  • Adrian P. Mancuso,
  • Brian Abbey

DOI
https://doi.org/10.1107/S1600577522005720
Journal volume & issue
Vol. 29, no. 4
pp. 939 – 946

Abstract

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Characterizing the properties of X-ray free-electron laser (XFEL) sources is a critical step for optimization of performance and experiment planning. The recent availability of MHz XFELs has opened up a range of new opportunities for novel experiments but also highlighted the need for systematic measurements of the source properties. Here, MHz-enabled beam imaging diagnostics developed for the SPB/SFX instrument at the European XFEL are exploited to measure the shot-to-shot intensity statistics of X-ray pulses. The ability to record pulse-integrated two-dimensional transverse intensity measurements at multiple planes along an XFEL beamline at MHz rates yields an improved understanding of the shot-to-shot photon beam intensity variations. These variations can play a critical role, for example, in determining the outcome of single-particle imaging experiments and other experiments that are sensitive to the transverse profile of the incident beam. It is observed that shot-to-shot variations in the statistical properties of a recorded ensemble of radiant intensity distributions are sensitive to changes in electron beam current density. These changes typically occur during pulse-distribution to the instrument and are currently not accounted for by the existing suite of imaging diagnostics. Modulations of the electron beam orbit in the accelerator are observed to induce a time-dependence in the statistics of individual pulses – this is demonstrated by applying radio-frequency trajectory tilts to electron bunch-trains delivered to the instrument. We discuss how these modifications of the beam trajectory might be used to modify the statistical properties of the source and potential future applications.

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