Physical Review X (Jul 2021)

All-XUV Pump-Probe Transient Absorption Spectroscopy of the Structural Molecular Dynamics of Di-iodomethane

  • Marc Rebholz,
  • Thomas Ding,
  • Victor Despré,
  • Lennart Aufleger,
  • Maximilian Hartmann,
  • Kristina Meyer,
  • Veit Stooß,
  • Alexander Magunia,
  • David Wachs,
  • Paul Birk,
  • Yonghao Mi,
  • Gergana Dimitrova Borisova,
  • Carina da Costa Castanheira,
  • Patrick Rupprecht,
  • Georg Schmid,
  • Kirsten Schnorr,
  • Claus Dieter Schröter,
  • Robert Moshammer,
  • Zhi-Heng Loh,
  • Andrew R. Attar,
  • Stephen R. Leone,
  • Thomas Gaumnitz,
  • Hans Jakob Wörner,
  • Sebastian Roling,
  • Marco Butz,
  • Helmut Zacharias,
  • Stefan Düsterer,
  • Rolf Treusch,
  • Günter Brenner,
  • Jonas Vester,
  • Alexander I. Kuleff,
  • Christian Ott,
  • Thomas Pfeifer

DOI
https://doi.org/10.1103/PhysRevX.11.031001
Journal volume & issue
Vol. 11, no. 3
p. 031001

Abstract

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In this work, we use an extreme-ultraviolet (XUV) free-electron laser (FEL) to resonantly excite the I: 4d_{5/2}–σ^{*} transition of a gas-phase di-iodomethane (CH_{2}I_{2}) target. This site-specific excitation generates a 4d core hole located at an iodine site, which leaves the molecule in a well-defined excited state. We subsequently measure the time-dependent absorption change of the molecule with the FEL probe spectrum centered on the same I: 4d resonance. Using ab initio calculations of absorption spectra of a transient isomerization pathway observed in earlier studies, our time-resolved measurements allow us to assign the timescales of the previously reported direct and indirect dissociation pathways. The presented method is thus sensitive to excited-state molecular geometries in a time-resolved manner, following a core-resonant site-specific trigger.