Electronic-vibrational energy transfer in the reaction of O(1D) atoms with molecular oxygen

An upper bbund of 6 X 10" cm3/mole s on the rate constant for the reaction. of atomic oxygen with vibrntional-I$ excited Yz has been deduced from laboiatory'observations and from detailed computer &ulations. From this result it can be shown that no more than 30% of the vibrational energy of Hz is e

Measurements of the enhancement of CbrationalIyexcited 02('Zi) formation by added 02 in the UV flashphotolysis of 03'indicate that 02(3Z$v\*r,~ is formed in the deactitition cf O('D) by 02 with an efficiency of 5 0.3. These measurements are also consistent with the formation of 02(3~-) g y",,-, in t

Structured emïssion spectra have been observed in tbe wavelengtb range 470-720 & from the reaction of oxygen atoms wïtb tetrafluoroetbylene. The emïssion is tentatively assigned to the CF2eBI) + CFz(t At) phosphorescence tiansition. The excited singlet CFz('Bt) is also formed through the triplet-Mp:

Measurements have been made of the vibrational branching ratio iv = O)/(u' = 1) in Nz (C ' l$) formed in electronic energy transfer collisions between argon metastable atoms and ground state nitrogen molecules, using crossed molecular beams. In the relative collision energy range, 0.08-0.20 eV, this

The rotational and vibrational energy distributions of S2(a 1~ and X 3y.~-) generated in the reaction ofS(3p 4, 1D) with thiirane C2H4S are measured, using the laser-induced fluorescence technique. Nascent energy distributions are approximated by Boltzmann distributions with rotational and vibration