Vibration-rotation energy transfer between CO2(ν2) and orthohydrogen

A classical model for V-R and V-V energy transfer between two dissimilar diatomic molecules is proposed. For the exponential repulsive potentid, in the limit as the rotation of the mplecules goes to zero, the presenr model reduces to the previous resu!ts for V-T and V-V energy transfer. For the hydr

## Abstract The temperature dependence of the vibration–vibration energy transfer between the __v__~3~ mode of N~2~O and the first vibrational level of CO was determined over a range of 780 to 1400°K using a shock tube. Several mixtures of CO‐N~2~O were tested, diluted in 95% Ar. The Landau–Teller

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.

Intramolecular vibration-vibration energy transfer cross sections have beer. calculated for COz (0001) + H2,!Dz -+ COz(ll'0) + Hz/Dz,+ C02(10°0) + Hz/D\*, and-C02(20°0) + Hz/D2 based on the mechanism that the energy mismatch is transferred to the translational motion. For CO2 + Hz. the calculated cr

Transfer of rotational energy in CN (X, v= 2 ) in single collisions with argon atoms was investigated, and is compared with our earlier results for collisions between CN (X) and helium. Rates of transfer between individual rotational states and total rates of loss to all other states are determined

Emission intensities from the CO\* bands at 667, 2319 and 3700 cm-' arc monitored simultaneausiy behind shock wwes over temperatures of 900 to 2300°K. It is confirmed that the former emission intensity changes approximaceIy exponentially but the latter two have induction periods behind shock waves.