Abstract
Numerous experimental and theoretical evidence indicates that polycyclic aromatic hydrocarbon (PAH) is the precursor of soot. However, the formation mechanism of PAH at flame conditions is not well understood. In this study, the growth of PAHs with a 5-membered ring via the hydrogen-abstraction-acetylene-addition route was systematically investigated using acenaphthylene (A2R5) as a model molecule. Potential energy surfaces were searched using DFT/B3LYP/6-311+G(d,p) and ROCCSD(T)/cc-pVDZ methods. The reaction rate coefficients of elementary reactions were evaluated using the transition state theory in the temperature range of 500–2500 K. The results showed that H abstractions by H, OH, and CH3 radicals, and the subsequent C2H2 addition reactions, were highly sensitive to the 5-membered ring. H abstraction reaction from the C atom on a 5-membered ring is not favorable due to the relatively higher energy barrier among all competing reactions. In contrast, the reaction rate coefficient of subsequent C2H2 addition reaction on a 5-membered ring is the highest. The planar PAH with no substitution, planar PAH with C2H substitution, curved PAH with two adjacent 5-membered rings, and PAH with a CCH2C functional group, can be formed in the A2R5H-C2H2 system investigated. The reactions investigated were merged into a detailed PAH mechanism to check the product distribution in a premixed C2H4 sooting flame. Owing to the existence of the 5-membered ring, the formation of planar PAHs with a C2H substitution was much more favorable than the formation of new 5-membered ring and 6-membered rings. The predicted mole fraction of all C14H8 species with one C2H substitution was as high as 2.8 × 10−5, higher than that of phenanthrene with same C atom number (1.2 × 10−5). A similar phenomenon was observed for C16H8 species with two C2H substitutions. In the future, more attention should be given to PAHs with C2H substitution, due to their high concentrations and enhanced reactivity, as compared to the benzenoid PAH.
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