Structural Dynamics (May 2021)

Design and characterization of a magnetic bottle electron spectrometer for time-resolved extreme UV and X-ray photoemission spectroscopy of liquid microjets

  • Naoya Kurahashi,
  • Stephan Thürmer,
  • Suet Yi Liu,
  • Yo-ichi Yamamoto,
  • Shutaro Karashima,
  • Atanu Bhattacharya,
  • Yoshihiro Ogi,
  • Takuya Horio,
  • Toshinori Suzuki

DOI
https://doi.org/10.1063/4.0000107
Journal volume & issue
Vol. 8, no. 3
pp. 034303 – 034303-11

Abstract

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We describe a magnetic bottle time-of-flight electron spectrometer designed for time-resolved photoemission spectroscopy of a liquid microjet using extreme UV and X-ray radiation. The spectrometer can be easily reconfigured depending on experimental requirements and the energy range of interest. To improve the energy resolution at high electron kinetic energy, a retarding potential can be applied either via a stack of electrodes or retarding mesh grids, and a flight-tube extension can be attached to increase the flight time. A gated electron detector was developed to reject intense parasitic signal from light scattered off the surface of the cylindrically shaped liquid microjet. This detector features a two-stage multiplication with a microchannel plate plus a fast-response scintillator followed by an image-intensified photon detector. The performance of the spectrometer was tested at SPring-8 and SACLA, and time-resolved photoelectron spectra were measured for an ultrafast charge transfer to solvent reaction in an aqueous NaI solution with a 200 nm UV pump pulses from a table-top ultrafast laser and the 5.5 keV hard X-ray probe pulses from SACLA.