The OH(X2Π, υ = 0) rotational energy distribution in the reaction of O(1D) + H2

A lower limit to t?re OH(X a 11) vibrational escitation produced by the reaction O(r D) + Ha has been obsewed using a low-pressure infrared chemilumiuescence anoaratus. The O(' D) was generated by laser photolysis of OS\_ The measured \_\* OH(v') vibrational distribution is inverted; it peaks at U'

The product hydroxyl radical arising from the reaction 0( 1D 2)-t-H 2 ---, OH + H was detected by LIF following excitation of the off-diagonal transition OH(A2E +, v' = 1 6-X 2II, v" = 2) in the region 348-357 nm. The rotational population distribution in v" = 2 appears to be inverted and quite simi

Pure rotational transitions have been used to probe high rotational states of OH(X 'H, v=O) formed in the reaction H+O+ OH+0 at 2.6 eV collision energy. The infrared diode absorption/gain technique is complementary to laser-induced fluorescence (LIF) and particularly useful for probing those high ro

The ;truIysir of the obsened OH (v" = 0, 1) concentrations in the laser enhanced reactions of KC1 (u' = 1,2) with O('P) atoms demonstrates that v~brstional energy in e\*xcess of the therm4 aztivation eneq barrier continues to enhance the reaction ate. This reaction also e.+ibits a preferential conve