A Systematic Investigation into the Mechanism of the Reaction Between CF3 Radicals and CO/O2

The reaction of CF, with NO, was studied at 296 2 2 K using two different absolute techniques Absolute rate constants of ( I 6 ? 0.3) X lo-" and ( 2 1-03+07) X lo-" cm3 molecule-' s-' were derived by IR fluorescence and UV absorption spectroscopy, respectively The reaction proceeds via two reaction

The thermal addition of CF,0sCF3(T 1 to CF2CCl2(E) has been investigated between 49.6 and 69.5"C. The initial pressure of CFJ03CF3 was varied between 7 and 240 torr and that of CF2CC12 between 4 and 600 torr. Four products of formula CF30(E),00CF3, wherej = 1 + 4 are formed. The sum of the products

The mechanism of the [HRh(CO) 4 ]-catalyzed hydrogenation of carbon monoxide has been studied with the help of ab initio quantumchemical calculations at the MP2 level of theory. A quasirelativistic effective core potential was used at rhodium in combination with valence basis sets of double-zeta qua

The kinetics of the self-reactions of HO 2 , CF 3 CFHO 2 , and CF 3 O 2 radicals and the cross reactions of HO 2 with FO 2 , HO 2 with CF 3 CFHO 2 , and HO 2 with CF 3 O 2 radicals, were studied by pulse radiolysis combined with time resolved UV absorption spectroscopy at 295 K. The rate constants f

or from the thermal decomposition of larger radicals formed in the degradation of oxygenated hydrocarbons, e.g., the OH-initiated oxidation of methylglyoxal [2]: (2)

## Abstract By means of the dual‐level direct dynamics method, the mechanisms of the reactions, CH~3~CF~2~Cl + OH → products (R1) and CH~3~CFCl~2~ + OH → products (R2), are studied over a wide temperature range 200–2000 K. The optimized geometries and frequencies of the stationary points are calcul