OH rotational quantum state distributions and relaxation efficiencies for the reaction system O(1D) + H2O → 2OH

Rotational and vibrational state distributions of the OH radicals produced in the reaction 160( I D) "at" H21So ~ x6OH + IsOH have been determined using a laser-induced fluorescence technique. 160(ID) was prepared by the 193 nm photodissociation of N20. The rotational distributions for 16OH and 1sOH

The effect on the thermal rate constant and the differential cross-sections of varying the dimensionality of quantum scattering calculations of a polyatomic reaction is investigated. The rotating bond approximation (RBA, 3D) and a rotating line approximation (RLA, 2D) are used for the CH, + OH + CH,

Photolysis of HCI with an ArF excimer laser at 193 nm yields H atoms with well-defined high translational energy ( I .86 eV) which react with CO2 to form OH and CO. The product OH radicals are detected by laser-induced fluorescence (LIF). From LIF spectra the nascent OH vibrational, rotational and t

We report H, and OH rotational distributions for the H+H20 reaction, and HD and OD rotational distributions for the H t D,O obtain the rotational distributions. A realistic, six-degree-of-freedom potential is used to describe the four-atom reaction, and the bending eigenstates are accurately calcula