Thermodynamic restrictions on the temperature and pressure dependence of the rate constant in chemical reaction kinetics

## Abstract Absolute rate constants for the reaction of OH with H~2~S have been measured over the temperature range of 239–425 K using the flash photolysis–resonance fluorescence technique. The results showed that the rate constants deviate slightly from Arrhenius behavior but can still be represen

Absolute rate constants for the reaction OD + DNOJ have been determined at 297 + 2 K, using a pulsed laser photolysis-resonance absorption technique. The values (in cm3 mol-' s-l) obtained for DN03 alone and in the presence of 107 Torr SF, and at + 3a are (5.47 zb 0.75) x lo9 and (8.51+ 0.72) x lo9

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

Absolute rate constants hav-e been measured for the reaction of SiH, with N,O at temperatures between 295-747 K. The rate constantsarefittedto the Arrheniusequation: log( k/cm' molecule-' s-l) = ( -12.09+0.04) t (2.02?0.31) kJ mol-'JRTln IO. The data are plausibly consistent with a mechanism involv

The rate constants of the reaction between OH and H2S in He, N,, and O2 over the temperature range 245-450 K have been determined using the discharge flow-resonance fluorescence technique. At 299 K, kl = (4.4 ? 0.7) x lo-'' cm3 molecule-' S K I . T h e t e m p e r a t u r e dependence of t h e r a

A laser flash photolysis-long path absorption technique has been employed to study the kinetics of the reaction BrO + NO2 + M Q products as a function of temperature (248-346 K), pressure (16-800 torr), and buffer gas identity (N2, CF4). The reaction is found to be in the falloff regime between thir