Vibrational relaxation of CO2(0001) in pure CO2

intramoleculv vibration--vibration energy transfer cross sections ha--e been calculated for COs(OO" 1) -I-Ne and COa(OO" 1) + COa (OOOO) over the tempemture range 100-3000 K. It is shown that (00'1) + (11'0) is the most important process at lower temperatures, while (00'1) + (10'0) dominates others

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

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

The vibrationaI energy relaxation rates of the liquid nitrogen-CO system have been measured by optically pumping the collision-induced fundamentalvibrational absorption band of liquid Nz with the output of an HBr TEA laser. A rad2atively dominated value of 56 f 10 s is found for the intrinsic nitrog

The vibrational relasation time for COz(v3) + O(3P) has been mcasurcd by Inscr fluorescence. The observed value, pCo2,0 = 0.21 \* 0.04 fiscc, is an order of mqniludc lower than the relaxation time for self-collisions.