An evaluation of the rate data for the reaction CO + OH → CO2 + H

The rate coefficient of the reaction H + CO z ~ CO + OH (1) was measured using OH concentration measurements in shock-heated N20-H2-CO 2 mixtures and through the inhibiting effect of CO 2 on methane ignition. For 2170 < T < 3150 K the two methods give concordant results and imply k I = 2.0 × 1014exp

The results of an experimental investigation designed to determine t-he vibrational energy content in the praducts of the reaction OH + CO + CO\* + H are presented. No 1R emission wm observed in any of the fundamental or strong combination bands of C02, 3nd thus OUT results are expressed as bounds o

Relative rate measurements of the reactions of the HO-radical with CO [HO + CO -+ H + COa (1) ] and with isobutane [HO f iso-C4H10 -t Hz0 f f-(or iso-)CaHg ( 3)J have been made through the photolysis of dilute mixtures of HONO with CO, ixo-Cd H ro, N0a, and NO in simulated air at 700 and 100 torr pr

The effect of pressure on the rate constant of the OH + CO reaction has been measured for Ar, N,, and SF, over the pressure range 200-730 torr. All experiments were at room temperature. The method involved laser-induced fluorescence to measure steady-state OH concentrations in the 184.9 nm photolysi

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