The pyrolysis of ethane in the presence of nitric oxide

Although our pyrolytic studies of five alkyl nitrites (RONO) have shown that it is possible to determine precise, acceptable values for k 1: (0 RONO -RO + NO we have been uncertain about the mechanism for the first order production of nitroxyl from primary and secondary nitrites. Nitroxyl could ari

The recombination of iodine atoms following the flash photolysis of iodine in the presence of nitric oxide is interpreted through the mechanism ki k-i with k~ = 3.5 X lo9 1.2/rno12-sec; kz = 1 X 10" l./rnol.sec; k3 = 2.1 X LO7 l./mol-sec at 298°K; E3 = 11 kJ/ rnol; and AH"] = 76 f 6 kJ/mol. Lower a

The pyrolyses of trimethylethylene and tetramethylethylene have been investigated in It appears that apart from a unimolecular the presence and absence of nitric oxide. split, e.g., a disproportionation reaction such as may play an important role in initiation. Nitric oxide had no effect on Hz prod

At 540°C, H,S (0.1 to 5 mm Hg) diminishes the initial rate of pyrolysis of C,H, (50 mm Hg) into C,H, + H, and, even more strongly, the rate of appearance of the traces of nC,H,; on the contrary, the initial rate of formation of the traces of CH, is practically not modified. A mechanism is proposed

The kinetics of methane pyrolysis were studied in a tubular flow reactor in the temperature range 1200 to 1500°C at atmospheric pressure. To avoid excessive carbon formation the reaction time was short and the methane feed was diluted with hydrogen. Ethene, ethyne, benzene and hydrogen were the main