Laboratory measurements of the ~(12)C/~(13)C kinetic isotope effects in the gas-phase reactions of unsaturated hydrocarbons with Cl atoms at 298±3 K

摘要

The carbon kinetic isotope effects (KIEs) in the reactions of several unsaturated hydrocarbons with chlorine atoms were measured at room temperature and ambient pressure using gas chromatography combustion isotope ratio mass spectrometry (GCC-IRMS). All measured KIEs, defined as the ratio of the rate constants for the unlabeled and labeled hydrocarbon reaction k_(12)/k_(13), are greater than unity or normal KIEs. The KIEs, reported in per mil according to ~(Cl)ε=(k_(12)/k_(13)-1)x1000per thousand with the number of experimental determinations in parenthesis, are as follows: ethene, 5.65±0.34 (1); propene, 5.56±0.18 (2); 1-butene, 5.93±1.16 (1); 1-pentene, 4.86±0.63 (1); cyclopentene, 3.75±0.14 (1); toluene, 2.89±0.31 (2); ethylbenzene, 2.17±0.17 (2); o-xylene, 1.85±0.54 (2). To our knowledge, these are the first reported KIE measurements for reactions of unsaturated NMHC with Cl atoms. Relative rate constants were determined concurrently to the KIE measurements. For the reactions of cyclopentene and ethylbenzene with Cl atoms, no rate constant has been reported in refereed literature. Our measured rate constants are: cyclopentene (7.32±0.88) relative to propene (2.68±0.32); ethylbenzene (1.15±0.04) relative to o-xylene (1.35±0.21), all x 10~(-10) cm~3 molecule~(-1) s~(-1). The KIEs in reactions of aromatic hydrocarbons with Cl atoms are similar to previously reported KIEs in Cl-reactions of alkanes with the same numbers of carbon atoms. Unlike the KIEs for previously studied gas-phase hydrocarbon reactions, the KIEs for alkene-Cl reactions do not exhibit a simple inverse dependence on carbon number. This can be explained by competing contributions of normal and inverse isotope effects of individual steps in the reaction mechanism. Implications for the symmetries of the transition state structures in these reactions and the potential relevance of Cl-atom reactions on stable carbon isotope ratios of atmospheric NMHC are discussed.