Fast reaction products from the oxidation of CO on Pt(111): Angular and velocity distributions of the CO2 product molecules

Abstract

Angular and velocity distributions of CO₂ desorbing as reaction product of CO oxidation on Pt(111) were measured during heating of layers of initially molecular oxygen and CO adsorbed at a surface temperature of 100 K. In the velocity integrated desorption spectra of the reaction product CO₂ four different peaks (α, β₃, β₂, β₁) can be discriminated which, for linear heating rates of 5 K/s, appear at 145, 210, 250, and 330 K, respectively. They can be attributed to different reaction mechanisms which depend on the binding conditions of oxygen and the geometric arrangement and coverages of both species. Whereas α‐CO₂ coincides with the O₂ desorption from and the dissociation of pure chemisorbed molecular oxygen, and thus indicates a reaction channel coupled with desorption and dissociation of O₂, β₁‐CO₂ corresponds to the reaction path investigated before by many researchers and is most likely due to the reaction at the boundaries of ordered CO and oxygen islands. The structural conditions for β₃ and β₂ are less clear, but we believe them to stem from reactions in mixed and/or partly mixed layers at high coverages of O and CO. The α‐CO₂ species is most likely due to reaction of CO with O atoms stemming from O₂ dissociation which react before becoming accommodated. The velocity distributions of α, β₂, and β₃ are far from thermal equilibrium with the surface as indicated by average kinetic energies between 220 and 360 meV, corresponding to ≂10 (for β₃ and β₂) and ≂30 kT_s (for α), normalized speed ratios between 0.6 and 0.8, and strongly peaked angular distributions (∼cosⁿ ϑ, n=8 for α, n≳10 for β₃ and β₂). For β₁ both the angular and velocity distributions show bimodal behavior with one channel fully accommodated to the surface whereas the other contains again an appreciable amount of reaction energy as kinetic energy (〈E〉≂330 meV) resulting in a strongly peaked angular distribution with n≂9. Some TOF results for steady state reaction at high temperatures (420–800 K) obtained in the same apparatus are given for comparison. The fraction of reaction energy channelled into the translational degree of freedom for the nonequilibrated part of reaction peak β₁ is estimated to about 40%. A discussion of the various possible mechanisms is given.