Chemisorption and oxidation reactions of nickel group cluster anions with N2, O2, CO2, and N2O

Abstract

Reactions of nickel (Ni⁻_n, n=3–10), palladium (Pd⁻_n, n=3–8), and platinum (Pt⁻_n, n=3–7) cluster anions are investigated in a flow tube reactor. Rate coefficients are measured for reactions with N₂, O₂, CO₂, and N₂O. Reactions with O₂, CO₂, and N₂O have rates that are greater than 10% of the collision rate for most clusters of four atoms or larger, while N₂ reactions generally exhibit much lower reaction efficiencies. All the reactions studied show a strong dependence on cluster elemental composition. Many of the palladium cluster reactions are significantly faster than the corresponding nickel and platinum cluster reactions, while Ni⁻_n and Pt⁻_n have similar rate coefficients. Pt⁻₆ is observed to have anomalously low rate constants for reactions with N₂, CO₂, and N₂O compared to neighboring platinum clusters sizes and the nickel and palladium hexamers. N₂, CO₂, and O₂ reactions are generally association reactions with varying degrees of cluster fragmentation observed. N₂O reactions result in sequential addition of O atoms to the cluster. The extent of cluster fragmentation for the various reagents can be correlated with the estimated exothermicities of the adsorption processes.