Physical Review X (Dec 2020)

Mapping Resonance Structures in Transient Core-Ionized Atoms

  • T. Mazza,
  • M. Ilchen,
  • M. D. Kiselev,
  • E. V. Gryzlova,
  • T. M. Baumann,
  • R. Boll,
  • A. De Fanis,
  • P. Grychtol,
  • J. Montaño,
  • V. Music,
  • Y. Ovcharenko,
  • N. Rennhack,
  • D. E. Rivas,
  • Ph. Schmidt,
  • R. Wagner,
  • P. Ziolkowski,
  • N. Berrah,
  • B. Erk,
  • P. Johnsson,
  • C. Küstner-Wetekam,
  • L. Marder,
  • M. Martins,
  • C. Ott,
  • S. Pathak,
  • T. Pfeifer,
  • D. Rolles,
  • O. Zatsarinny,
  • A. N. Grum-Grzhimailo,
  • M. Meyer

DOI
https://doi.org/10.1103/PhysRevX.10.041056
Journal volume & issue
Vol. 10, no. 4
p. 041056

Abstract

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The nature of transient electronic states created by photoabsorption critically determines the dynamics of the subsequently evolving system. Here, we investigate K-shell photoionized atomic neon by absorbing a second photon within the Auger-decay lifetime of 2.4 fs using the European XFEL, a unique high-repetition-rate, wavelength-tunable x-ray free-electron laser. By high-resolution electron spectroscopy, we map out the transient Rydberg resonances unraveling the details of the subsequent decay of the hollow atom. So far, ultra-short-lived electronic transients, which are often inaccessible by experiments, were mainly inferred from theory but are now addressed by nonlinear x-ray absorption. The successful characterization of these resonances with femtosecond lifetimes provides the basis for a novel class of site-specific, nonlinear, and time-resolved studies with strong impact for a wide range of topics in physics and chemistry.