Temperature dependence of intramolecular vibrational energy transfer in CO2: CO2(0001) + Ne/CO2 → CO2(nml0) + Ne/CO2

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

## Method of solution A molecular hamiltonian describing carbon dioxide, which is Ciztalogue number: ABWC a linear triatomic, is diagonalized [3-6]. The effect of Fermi Program obtainable from: CPC Program Libary, Queen's Uni-resonance is considered. The vibrational energies and rotationversity of

Collisional deactivation rate constants of CO+ A 'fI(v=O and 2) by He, Ne. Ar, N,, and CO have been determined by using a time-resolved laser-induced fluorescence technique. The results were combined with the previously determined Y= 1 rate constants to obtain an interesting u dependence of the rate

The deactivation of C&(OO"l) by ethane in.ihe temperature ran9 300-600 K has been strrdied using 2 laser induced fluorescence technique. Thhd energ transfer cross section dccrased from 0.23 A2 at 3CO K to 0.16 AZ at 600 K. The magnitude of the cross section is consistent with the expectation that nc