Nature Communications (Apr 2023)

A sensitive high repetition rate arrival time monitor for X-ray free electron lasers

  • Michael Diez,
  • Henning Kirchberg,
  • Andreas Galler,
  • Sebastian Schulz,
  • Mykola Biednov,
  • Christina Bömer,
  • Tae-Kyu Choi,
  • Angel Rodriguez-Fernandez,
  • Wojciech Gawelda,
  • Dmitry Khakhulin,
  • Katharina Kubicek,
  • Frederico Lima,
  • Florian Otte,
  • Peter Zalden,
  • Ryan Coffee,
  • Michael Thorwart,
  • Christian Bressler

DOI
https://doi.org/10.1038/s41467-023-38143-y
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 9

Abstract

Read online

Abstract X-ray free-electron laser sources enable time-resolved X-ray studies with unmatched temporal resolution. To fully exploit ultrashort X-ray pulses, timing tools are essential. However, new high repetition rate X-ray facilities present challenges for currently used timing tool schemes. Here we address this issue by demonstrating a sensitive timing tool scheme to enhance experimental time resolution in pump-probe experiments at very high pulse repetition rates. Our method employs a self-referenced detection scheme using a time-sheared chirped optical pulse traversing an X-ray stimulated diamond plate. By formulating an effective medium theory, we confirm subtle refractive index changes, induced by sub-milli-Joule intense X-ray pulses, that are measured in our experiment. The system utilizes a Common-Path-Interferometer to detect X-ray-induced phase shifts of the optical probe pulse transmitted through the diamond sample. Owing to the thermal stability of diamond, our approach is well-suited for MHz pulse repetition rates in superconducting linear accelerator-based free-electron lasers.