Molecular beam studies of vibrational energy transfer and vibrational activation in molecule-surface collisions

possibk RSSOIIS for the non-monotonous tempa-aturs dependencf oE the q~~~d-rescmzm~~ emcrgy trmsf'er probability and relative contributions of short-range and long-range forces are discussed. Particular calcuhtions are made for the caze Nz-C02(v3) vibrational energy exchange.

Classical tujectory calculations for a model of 12 scattering from a surface show that in hi~h-xtergy collisions the amount of translational energy trancferred to rotation geatlv exceeds the amount transferred to vibration\_ The sudden approximation is used to qualitative& interpret the results.

A simple approximate method for the vlbradon-vibration (V-V) energy-transrer process dunng coILnear collision of LWO CO molecules in the presence of an mrrared laser beam usmg a quasi-energy approach (non-perturbarive) is presented-The efrecl of radiation on V-V process is investigated by changing m

## Accurate quantum mechanical transition probabilities for vIbrationa to vibrational and vibrational to translational cncr- gy txm\fcr in collmcar colliaons of two hydrogen molecules were calculated for a model pootentki by numerica integration of the Sduodmgcr equation. The accuracy of these cal