A tight-binding study of the electronic structure of and chemisorbed CO

Abstract: Experiments on CO chemisorption at the transition-metal alloy find the molecule bound more weakly than at Pt(111). There was, however, disagreement in experimental interpretation supporting either the bulk termination or pure platinum surface. A recent LEED study strongly supports the latter possibility. We have performed extended self-consistent tight-binding calculations for bulk and surface electronic structure of the alloy and for CO chemisorption at selected adsorption sites. For the bulk we get in the i… Show more

“…The LDOS region of the Pt atom nearby E F decreases sharply, which originates from the hybridization of Pt 5d orbitals with Sn 5p orbitals. This hybridization of Pt 5d orbitals with electron orbitals of the companion atom nearby E F is a common bonding mechanism observed on previous studies of PtSn 64 and similar systems, 65,66 and accounts for the better selectivity of bond scissions on the Pt 3 Sn surface. 64 It thus confirms that the Sn atom could effectively adjust the electronic structure of Pt, that is, the "ligand effect" mechanism.…”

CO tolerance of a Pt₃Sn(111) catalyst in ethanol decomposition

“…The LDOS region of the Pt atom nearby E F decreases sharply, which originates from the hybridization of Pt 5d orbitals with Sn 5p orbitals. This hybridization of Pt 5d orbitals with electron orbitals of the companion atom nearby E F is a common bonding mechanism observed on previous studies of PtSn 64 and similar systems, 65,66 and accounts for the better selectivity of bond scissions on the Pt 3 Sn surface. 64 It thus confirms that the Sn atom could effectively adjust the electronic structure of Pt, that is, the "ligand effect" mechanism.…”

CO tolerance of a Pt₃Sn(111) catalyst in ethanol decomposition

3.7.1 CO and N2 adsorption on metal surfaces - CO adsorption

Model of gas adsorption on magnetic surfaces