Probing the fuel-specific intermediates in the low-temperature oxidation of 1-heptene and modeling interpretation

Abstract

In this work, low temperature (low-T) oxidation of 1-heptene was investigated in a jet-stirred reactor (JSR) over the temperatures of 450–800 K, 770 Torr and equivalence ratios of 0.5–2.0. The intermediates were identified and quantified using synchrotron vacuum ultraviolet photoionization mass spectrometry (SVUV-PIMS) and gas chromatography combined with mass spectrometry (GC–MS). The SVUV-PIMS experiment combined with quantum chemistry calculation of ionization energy enables the identification of fuel-specific intermediates, including C7 alkenylperoxy radical and hydroperoxides, such as diolefinic-hydroperoxide, alkenylhydroperoxide, alkenyl-ketohydroperoxide and cyclic ether hydroperoxide. Among them, alkenylperoxy radical, diolefinic-hydroperoxide and cyclic ether hydroperoxide have not been detected in alkene oxidation before. In order to accurately identify and quantify other fuel-specific intermediates such as aldehyde and cyclic ether isomers, the GC–MS experiment was conducted under the same conditions as the SVUV-PIMS experiment. On the other hand, a detailed low-T oxidation model of 1-heptene was developed, which can reasonably capture the fuel oxidation rate and negative temperature coefficient behaviors observed in this work. The present model can not only interpret the formation of different kinds of hydroperoxides and predict their temperature windows, but also capture the formation of 2-heptenal, hexanal and heptanal, and branched tetrahydrofurans, which are derived from the H-abstraction by OH, OH addition and H addition reactions of 1-heptene, respectively, revealing that the competition between these reactions can be well characterized.