Hot-electron-mediated desorption rates calculated from excited-state potential energy surfaces

Thomas Olsen, Jeppe Gavnholt, Jakob Schiøtz

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Abstract

We present a model for desorption induced by (multiple) electronic transitions [DIET (DIMET)] based on potential energy surfaces calculated with the delta self-consistent field extension of density-functional theory. We calculate potential energy surfaces of CO and NO molecules adsorbed on various transition-metal surfaces and show that classical nuclear dynamics does not suffice for propagation in the excited state. We present a simple Hamiltonian describing the system with parameters obtained from the excited-state potential energy surface and show that this model can describe desorption dynamics in both the DIET and DIMET regimes and reproduce the power-law behavior observed experimentally. We observe that the internal stretch degree of freedom in the molecules is crucial for the energy transfer between the hot electrons and the molecule when the coupling to the surface is strong.
Original languageEnglish
JournalPhysical Review B Condensed Matter
Volume79
Issue number3
Pages (from-to)035403
ISSN0163-1829
DOIs
Publication statusPublished - 2009

Bibliographical note

Copyright 2009 American Physical Society

Keywords

  • palladium
  • nitrogen compounds
  • desorption
  • potential energy surfaces
  • adsorbed layers
  • SCF calculations
  • density functional theory
  • platinum
  • rhodium
  • carbon compounds
  • ruthenium
  • excited states

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