Atmospheric Chemistry of n-C6F13CH2CHO: Formation from n-C6F13CH2CH2OH, Kinetics and Mechanisms of Reactions with Chlorine Atoms and OH Radicals.

MALISA S. CHIAPPERO, GUSTAVO A. ARGÜELLO, MICHAEL D. HURLEY, TIMOTHY J. WALLINGTON

JOURNAL OF PHYSICAL CHEMISTRY A

AMER CHEMICAL SOC

Año: 2010 vol. 114 p. 6131 - 6137

1089-5639

Smog chamber FTIR techniques were used to measure k(Cl + n-C6F13CH2CHO) ) (1.84 ( 0.22) × 10-11,k(Cl + n-C6F13CHO) ) (1.75 ( 0.70) × 10-12, and k(OH + n-C6F13CH2CHO) ) (2.15 ( 0.26) × 10-12 cm3molecule-1 s-1 in 700 Torr of N2 or air diluent at 296 ( 2K. The chlorine-atom-initiated oxidation ofn-C6F13CH2CH2OH in air gives n-C6F13CH2CHO in a molar yield of 99 ( 8%. The atmospheric fateof n-C6F13CH2C(O) radicals is reaction with O2, while the fate of n-C6F13C(O) radicals is decomposition togive n-C6F13 radicals and CO. The results are discussed with respect to the atmospheric chemistry of fluorinatedalcohols and the formation of perfluorocarboxylic acids.