Rate Constants and Products of the OH Reaction with Isoprene-Derived Epoxides
Abstract
Recent laboratory and field work has shown that isoprene-derived epoxides (IEPOX) are crucial intermediates that can explain the existence of a variety of compounds found in ambient secondary organic aerosol (SOA). However, IEPOX species are also able to undergo gas phase oxidation, which competes with the aerosol phase processing of IEPOX. In order to better quantify the atmospheric fate of IEPOX, the gas phase OH reaction rate constants and product formation mechanisms have been determined using a flow tube chemical ionization mass spectrometry technique. The new OH rate constants are generally larger than previous estimations and some features of the product mechanism are well predicted by the Master Chemical Mechanism Version 3.2 (MCM v3.2), while other features are at odds with MCM v3.2. Using a previously proposed kinetic model for the quantitative prediction of the atmospheric fate of IEPOX, it is found that gas phase OH reaction is an even more dominant fate for chemical processing of IEPOX than previously suggested. The present results suggest that aerosol phase processing of IEPOX will be competitive with gas phase OH oxidation only under SOA conditions of high liquid water content and low pH.
Repository Citation
Jacobs, M.I., A.I. Darer, and M.J. Elrod. 2013. “Rate Constants and Products of the OH Reaction with Isoprene-Derived Epoxides.” Environmental Science and Technology 47(22): 12686-12876.
Publisher
American Chemical Society
Publication Date
1-1-2013
Publication Title
Environmental Science and Technology
Department
Chemistry and Biochemistry
Document Type
Article
DOI
https://dx.doi.org/10.1021/es403340g
Keywords
Secondary organic aerosol, Mass-spectrometry, Gas-phase, Hydroxyl radicals, Ambient aerosol, Photooxidation, Kinetics, Organosulfates, Epoxydiols, Temperature
Language
English
Format
text