A DFT study of the NO dissociation on gold surfaces doped with transition metals

The NO dissociation on a series of doped gold surfaces (type TM(n)@Au(111) or TM(n)@Au(110), with TM(n) = Ni, Ir, Rh, or Ag and referring n to the number of dopant atoms per unit cell) was investigated through periodic density functional theory calculations. Generally, doping of Au(111) and Au(110)...

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Bibliographic Details
Published in:The Journal of chemical physics 2013-02, Vol.138 (7), p.074701-074701
Main Authors: Fajín, José L C, Cordeiro, M Natália D S, Gomes, José R B
Format: Article
Language:English
Subjects:
Barriers
Dopants
Energy of dissociation
Gold
Iridium
Mathematical models
Nickel
Silver
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Summary:The NO dissociation on a series of doped gold surfaces (type TM(n)@Au(111) or TM(n)@Au(110), with TM(n) = Ni, Ir, Rh, or Ag and referring n to the number of dopant atoms per unit cell) was investigated through periodic density functional theory calculations. Generally, doping of Au(111) and Au(110) matrices was found to strengthen the interaction with NO species, with the exception of Ag, and was found to increase the energy barrier for dissociation, with the exception of Ni on Au(111). The calculations suggest that the NO dissociation is only possible in the case of the Ir@Au(110) bimetallic surface but only at high temperatures. The increase of the contents of Ir on Au(110) was found to improve significantly the catalytic activity of gold towards the NO dissociation (E(act) = ∼1 eV). Nevertheless, this energy barrier is almost the double of that calculated for NO dissociation on pure Ir(110). However, mixing the two most interesting dopant atoms resulted in a catalyst model of the type Ir@Ni(110) that was found to decrease the energy barrier to values close to those calculated for pure Ir surfaces, i.e., ∼0.4 eV, and at the same time the dissociation reaction became mildly exothermic.
ISSN:0021-9606
1089-7690
DOI:10.1063/1.4790602