H+H2O reaction dynamics: state distribution for the OH product

The nascent state distributions of OH produced in the reaction H+H20+0H+H2 were probed by fast atom-laser-induced fluorescence experiments. Translationally hot H atoms were formed by photolysis of HI at 250 and 270 nm leading to H+HrO c.m. collision energies E of 176 and 143 kJ/mol. With a calibrat

## Using translationally excited H atoms generated by laser photolysis of H2S at 193 nm, the reaction dynamics of H + H,O+OH + H2 and H + COIdOH + CO was investigated at collision energies of 2.2 and 2.3 eV, respectively. Nascent OH rotational and vibrational quantum-state distributions and OH pro

HZ0 was excited to the lowest electronic excited state, 'B,, at 157.6 nm and the OH product state distribution was completely analyzed by special laser-induced-fluorescence (LIF) experiments probing the fragment distribution by the transitions (u' = 0, 1 tvn ). The OH rotational excitation is relati

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

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