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Theoretical studies on the hydrogen abstraction reactions of methyl esters with HO 2 radical and the following β‐scission reactions
Author(s) -
Wang QuanDe
Publication year - 2017
Publication title -
journal of physical organic chemistry
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.325
H-Index - 66
eISSN - 1099-1395
pISSN - 0894-3230
DOI - 10.1002/poc.3668
Subject(s) - chemistry , hydrogen atom abstraction , radical , arrhenius equation , transition state theory , photochemistry , reaction rate constant , activation energy , biodiesel , elementary reaction , reaction mechanism , combustion , computational chemistry , hydrogen , bond cleavage , kinetics , organic chemistry , catalysis , physics , quantum mechanics
Unsaturated fatty acid methyl esters are ubiquitous in biodiesel fuels. The C = C double bond greatly affects the combustion characteristics of biodiesel, especially its ignition behavior at low temperatures. In this work, we report detailed theoretical study on the mechanism and kinetics of the hydrogen abstraction reactions of linear unsaturated C6 methyl esters with hydroperoxy radical (HO 2 ), which play a critical role in the low‐temperature combustion of biodiesel. Reaction profiles are obtained via intrinsic reaction coordinate (IRC) analysis including the formation of reactant complexes and product complexes at the entrance and exit channels, respectively. The potential energy surfaces are explored at the CBS‐QB3 level. The following β‐scission reactions of the forming radicals are also investigated at the same level of theory. The high‐pressure limit rate constants for all the reactions in the temperature range from 500 to 2000 K are calculated via conventional transition‐state theory with quantum tunneling effect and fitted to the modified Arrhenius expression.