摘要
An attempt has been made to analyze the effect of surface site on the spin state for the interaction of NO with Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh nanoparticles that supported at regular and defective MgO(001) surfaces. The adsorption properties of NO on homonuclear, Pd<sub>2</sub>, Rh<sub>2</sub>, and heteronuclear transition metal dimers, PdRh, that deposited on MgO(001) surface have been studied by means of hybrid density functional theory calculations and embedded cluster model. The most stable NO chemisorption geometry is in a bridge position on Pd<sub>2</sub> and a top configuration of Rh<sub>2</sub> and PdRh with N-down oriented. NO prefers binding to Rh site when both Rh and Pd atoms co-exist in the PdRh. The natural bond orbital analysis (NBO) reveals that the electronic structure of the adsorbed metal represents a qualitative change with respect to that of the free metal. The adsorption properties of NO have been analyzed with reference to the NBO, charge transfer, band gaps, pairwise and non-pairwise additivity. The binding of NO precursor is dominated by the E<sub>(i)</sub>M<sub>x</sub>-NO</sup> pairwise additive components and the role of the support was not restricted to supporting the metal. The adsorbed dimers on the MgO surface lose most of the metal-metal interaction due to the relatively strong bond with the substrate. Spin polarized calculations were performed and the results concern the systems in their more stable spin states. Spin quenching occurs for Rh atom, Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh complexes at the terrace and defective surfaces. The adsorption energies of the low spin states of spin quenched complexes are always greater than those of the high spin states. The metal-support and dimer-support interactions stabilize the low spin states of the adsorbed metals with respect to the isolated metals and dimers. Although the interaction of Pd, Rh, Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh particles with Fs sites is much stronger than the regular sites O<sup>2-</sup>, the adsorpt
An attempt has been made to analyze the effect of surface site on the spin state for the interaction of NO with Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh nanoparticles that supported at regular and defective MgO(001) surfaces. The adsorption properties of NO on homonuclear, Pd<sub>2</sub>, Rh<sub>2</sub>, and heteronuclear transition metal dimers, PdRh, that deposited on MgO(001) surface have been studied by means of hybrid density functional theory calculations and embedded cluster model. The most stable NO chemisorption geometry is in a bridge position on Pd<sub>2</sub> and a top configuration of Rh<sub>2</sub> and PdRh with N-down oriented. NO prefers binding to Rh site when both Rh and Pd atoms co-exist in the PdRh. The natural bond orbital analysis (NBO) reveals that the electronic structure of the adsorbed metal represents a qualitative change with respect to that of the free metal. The adsorption properties of NO have been analyzed with reference to the NBO, charge transfer, band gaps, pairwise and non-pairwise additivity. The binding of NO precursor is dominated by the E<sub>(i)</sub>M<sub>x</sub>-NO</sup> pairwise additive components and the role of the support was not restricted to supporting the metal. The adsorbed dimers on the MgO surface lose most of the metal-metal interaction due to the relatively strong bond with the substrate. Spin polarized calculations were performed and the results concern the systems in their more stable spin states. Spin quenching occurs for Rh atom, Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh complexes at the terrace and defective surfaces. The adsorption energies of the low spin states of spin quenched complexes are always greater than those of the high spin states. The metal-support and dimer-support interactions stabilize the low spin states of the adsorbed metals with respect to the isolated metals and dimers. Although the interaction of Pd, Rh, Pd<sub>2</sub>, Rh<sub>2</sub> and PdRh particles with Fs sites is much stronger than the regular sites O<sup>2-</sup>, the adsorpt
作者
S. Abdel Aal
S. Abdel Aal(Department of Chemistry, Faculty of Science, Benha University, Benha, Egypt)
