Atmospheric chemistry of 1-octene, 1-decene, and cyclohexene: Gas-phase carbonyl and peroxyacyl nitrate products

Atmospheric reactions of 1-octene, 1-decene, and cyclohexene have been studied in laboratory experiments involving alkene-ozone mixtures in the dark and alkene-NO and aldehyde-NO mixtures in sunlight. Major carbonyl products of the alkene-ozone reaction (with sufficient cyclohexane added to scavenge OH) were heptanal from 1-octene, nonanal from 1-decene, formaldehyde from both, and pentanal from cyclohexene. For 1-octene and 1-decene, carbonyl formation yields were consistent with the simple mechanism: RCH = CH2 + O-3 --> 0.5(HCHO + RCHOO) + 0.5(RCHO + H2COO). Other carbonyls were formed and accounted for ca. 0.10-0.20 of the subsequent reactions of the RCHOO biradical. Pentanal accounted for ca. 0.16 of the cyclohexene-O-3 reaction. Sunlight irradiation of alkene-NO and aldehyde-NO mixtures leads to carbonyls, alkyl nitrates, and peroxyacyl nitrates. Major carbonyl products of the OH-alkene reaction were heptanal from 1-octene, nonanal from 1-decene, and formaldehyde from both. Experimental data indicated that addition is an important pathway of the overall OH-1-alkene reaction, decomposition is important for the beta-hydroxyalkoxy radicals that form following OH addition, and reaction with O-2 is Of some importance for the alkoxy radicals that form in several pathways in the alkene-NO (sunlight), aldehyde-NO (sunlight), and peroxyacyl nitrate-NO (dark) systems. The extent of isomerization of alkoxy and beta-hydroxyalkoxy radicals could not be assessed. Several peroxyacyl nitrates [RC(O)OONO2] were formed including those with R = n-C4H9 from cyclohexene, R = n-C5H11 from hexanal, and R = n-C6H13 from heptanal and from 1-octene. The thermal decomposition rates of n-C5H11C(O)OONO2 and n-C5H13C(O)OONO2, which were synthesized in the liquid phase and were characterized in a number of tests using electron capture gas chromatography, were (in units of 10(-4) s(-1)) 0.72-2.02 (T = 291-299 K) and 0.61-1.19 (T = 291-295 K), respectively, at p 1 = atm of air. Comparison with data for lower molecular weight homologues including PAN (R = CH3) suggests that the thermal stability of peroxyacyl nitrates may increase with the size of the n-alkyl substituent. The atmospheric persistence of the atmospheric oxidation products of 1-octene, 1-decene, and cyclohexene is briefly discussed.