A high pressure rate constant for CH3 + H and an analysis of the kinetics of the CH3 + H → CH4 reaction

## Abstract The Laser Photolysis‐Shock Tube technique coupled with H‐atom atomic resonance absorption spectrometry has been used to study the reaction, H + CH~4~ → CH~3~ + H~2~, over the temperature range, 928–1697 K. Shock‐tube studies on the reverse of this reaction, CH~3~ + H~2~ → H + CH~4~, usi

Using a potential-energy surface obtained in part from ab initio calculations, the H + CH3 -CH4 bimolecular rate constant at T = 300 K is determined from a Monte Carlo classical trajectory study. Representing the C-H stretching potential with n standard Morse fun&on instead ofthe ab inirio curveincr

The shock tube technique with H-and D-atom atomic resonance absorption spectrometry detection has been used to study the thermal decomposition of C 2 D 5 I and the reaction, 3 2 over the temperature ranges 924-1370 and 1294-1753 K, respectively. First-order rate constants for the thermal decomposit

The reaction of hydrogen atoms with methyl nitrite was studied in a fast-flow system The associated biusing photoionization mass spectrometry and excess atomic hydrogen. molecular rate coefficient can be expressed by k, = (4.3 f 0.9) x 10-13 exp [ -(1900 f 110) cal/mol . R T ] cm3/molecule . sec in

The reactions of ten metastable immonium ions of general structure R'R2C=NH+C4H9 (R' = H, R2 = CH, , C2H, ; R' = R2 = CH,) are reported and discussed. Elimination of C4H, is usually the dominant fragmentation pathway. This process gives rise to a Gaussian metastable peak; it is interpreted in terms