The kinetics and the mechanism of the thermal decomposition of bis(trifluoromethyl) trioxide. The influence of carbonmonoxide on its decomposition

The thermal decomposition of SF503SF5 has been investigated between 5 and 25°C. In the presence of sufficient high pressures of 0 2 the only products formed are S F ~O ~S F S and

## Abstract The kinetics of gas‐phase decomposition of methyl isocyanate have been investigated in the range of 427–548°C. Two decomposition routes are followed; the predominant one is a radical‐chain process giving CO, H~2~, and HCN as major products, which has an order of 1.5 and an Arrhenius equ

The kinetics of the gas-phase decomposition of ethyl, isopropyl, and t -butyl isocyanates have been studied in the temperature range of 380-530OC. t -Butyl isocyanate decomposes almost exclusively by a unimolecular route to isobutene and HNCO, but in EtNCO and i - PrNCO this route competes with a fr

The thermal decomposition of SFsOsSFs in the presence of CO has been investigated between -9.8"C and + 9.9"C. Besides traces of S2F10, equimolecular amounts of SFsOrSFs ;ind CO? are formed. The reaction is homogeneous. Its rate is proportional to the pressure of the trioxide and independent of the

## Abstract Thermal decomposition of bis(trifluoromethyl) peroxydicarbonate has been studied. The mechanism of decomposition is a simple bond fission, homogeneous first‐order process when the reaction is carried out in the presence of inert gases such as N~2~ or CO. An activation energy of 28.5 kca

At 298 K the rate constant for the decomposition of N-chloroleucine has the constant value 3.20 >: lo-\* s-' over the range pH 5-12, increases with increasing acidity at pH < 5, and increases with pH a t pH > 12. A mechanism is put forward which explains these results.