Correlation Between Kinetic-Energy Transfer to Rotation and to Phonons in Gas-Surface Collisions of NO with Ag(111)
- 20 October 1986
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 57 (16), 2053-2056
- https://doi.org/10.1103/physrevlett.57.2053
Abstract
Velocities of NO molecules scattered from Ag(111) have been measured as a function of rotational state for a wide range of incidence energies and angles. We find that increasing rotational excitation is accompanied by decreasing energy transfer to phonons. Results agree quantitatively with an extensive trajectory simulation employing a realistic multidimensional interaction potential, which shows that this correlation is mediated largely by the orientation angle of the colliding molecule. A simple kinematic model suggests that this behavior is a general feature of molecule-surface scattering.Keywords
This publication has 41 references indexed in Scilit:
- Gas—surface interactions and dynamics; Thermal energy atomic and molecular beam studiesSurface Science Reports, 1984
- Direct inelastic scattering of nitric oxide from clean Ag(111): Rotational and fine structure distributionsThe Journal of Chemical Physics, 1983
- Reactive scattering from solid surfacesSurface Science Reports, 1983
- Laser-induced-fluorescence studies of no scattering from Ag(111)Surface Science, 1982
- Observation of rotational polarization produced in molecule-surface collisionsPhysical Review B, 1982
- Rotationally inelastic scattering from surfaces CO(g) + LiF(OO1)Chemical Physics Letters, 1982
- Partitioning of electronic energy in NO collisions with a Ag(111) surfaceThe Journal of Chemical Physics, 1982
- Rotational Energy Transfer in Direct Inelastic Surface Scattering: NO on Ag(111)Physical Review Letters, 1981
- Determination of Internal-State Distributions of Surface Scattered Molecules: Incomplete Rotational Accommodation of NO on Ag(111)Physical Review Letters, 1981
- Rotationally Inelastic Gas-Surface Scattering Investigated by Laser-Induced FluorescencePhysical Review Letters, 1981