AIP Advances (Nov 2020)

Accuracy of XAS theory for unraveling structural changes of adsorbates: CO on Ni(100)

  • Elias Diesen,
  • Gabriel L. S. Rodrigues,
  • Alan C. Luntz,
  • Frank Abild-Pedersen,
  • Lars G. M. Pettersson,
  • Johannes Voss

DOI
https://doi.org/10.1063/5.0028002
Journal volume & issue
Vol. 10, no. 11
pp. 115014 – 115014-6

Abstract

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Studying surface reactions using ultrafast optical pump and x-ray probe experiments relies on accurate calculations of x-ray spectra of adsorbates for the correct identification of the spectral signatures and their dynamical evolution. We show that experimental x-ray absorption can be well reproduced for different binding sites in a static prototype system CO/Ni(100) at a standard density functional theory generalized-gradient-approximation level of theory using a plane-wave basis and pseudopotentials. This validates its utility in analyzing ultrafast x-ray probe experiments. The accuracy of computed relative core level binding energies is about 0.2 eV, representing a lower limit for which spectral features can be resolved with this method. We also show that the commonly used Z + 1 approximation gives very good core binding energy shifts overall. However, we find a discrepancy for CO adsorbed in the hollow site, which we assign to the significantly stronger hybridization in hollow bonding than in on-top.