Internal states distributions of NO thermally desorbed from Pt(111): Dependence on coverage and co-adsorbed CO
- 1 May 1986
- journal article
- research article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 84 (9) , 5131-5142
- https://doi.org/10.1063/1.450666
Abstract
The distribution of population in the internal energy levels of nitric oxide thermally desorbed from Pt(111) has been probed using laser excited fluorescence. The observed rotational distributions have been found to follow the Boltzmann distribution function, independent of NO coverage or the presence of pre- or post-adsorbed CO. Under all conditions of NO desorption, the observed NO was characterized by a temperature (0.95±0.05) times the surface temperature. No evidence of a preferred alignment of the rotational angular momentum vectors was observed, nor was there any difference between the two spin-orbit multiplets beyond that associated with the rotational temperature.Keywords
This publication has 44 references indexed in Scilit:
- State-selected photodissociation dynamics: Complete characterization of the OH fragment ejected by the HONO Ã stateThe Journal of Chemical Physics, 1984
- Direct inelastic scattering of nitric oxide from clean Ag(111): Rotational and fine structure distributionsThe Journal of Chemical Physics, 1983
- Energy redistribution among internal states of nitric oxide molecules upon scattering from Pt(111) crystal surfaceThe Journal of Chemical Physics, 1983
- Determination of product population and alignment using laser-induced fluorescenceThe Journal of Chemical Physics, 1983
- Observation of rotational polarization produced in molecule-surface collisionsPhysical Review B, 1982
- Partitioning of electronic energy in NO collisions with a Ag(111) surfaceThe Journal of Chemical Physics, 1982
- Rotational- and Spin-State Distributions: NO Thermally Desorbed from Ru(001)Physical Review Letters, 1981
- Molecular dynamics of infrequent events: Thermal desorption of xenon from a platinum surfaceThe Journal of Chemical Physics, 1981
- Collisionally induced hyperfine-structure transitions of OHThe Astrophysical Journal, 1976
- The transition state methodTransactions of the Faraday Society, 1938