Open AccessEffects of non-local exchange on core level shifts for gas-phase and adsorbed molecules
Author(s) -
Maxime Van den Bossche,
Natalia M. Martin,
Johan Gustafson,
Can Hakanoglu,
Jason F. Weaver,
Edvin Lundgren,
Henrik Grönbeck
Publication year - 2014
Publication title -
the journal of chemical physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.071
H-Index - 357
eISSN - 1089-7690
pISSN - 0021-9606
DOI - 10.1063/1.4889919
Subject(s) - cls upper limits , density functional theory , chemistry , molecule , adsorption , core (optical fiber) , binding energy , gas phase , series (stratigraphy) , beta (programming language) , computational chemistry , atomic physics , thermodynamics , molecular physics , materials science , physics , organic chemistry , optometry , composite material , biology , computer science , programming language , medicine , paleontology
Density functional theory calculations are often used to interpret experimental shifts in core level binding energies. Calculations based on gradient-corrected (GC) exchange-correlation functionals are known to reproduce measured core level shifts (CLS) of isolated molecules and metal surfaces with reasonable accuracy. In the present study, we discuss a series of examples where the shifts calculated within a GC-functional significantly deviate from the experimental values, namely the CLS of C 1s in ethyl trifluoroacetate, Pd 3d in PdO and the O 1s shift for CO adsorbed on PdO(101). The deviations are traced to effects of the electronic self-interaction error with GC-functionals and substantially better agreements between calculated and measured CLS are obtained when a fraction of exact exchange is used in the exchange-correlation functional
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