Oxidation kinetic mechanism of n-decane under high temperature and pressure: a first-principles molecular dynamics study†
Abstract
The n-decane/air (C10H22/air) combustion reaction kinetics has attracted much research attention because of its potential application in the aerospace field. In this work, C10H22 oxidation in O2 under high temperature and pressure is simulated based on the first-principles molecular dynamics method for the first time. Our results show that C–C bond breaking and H-abstraction are the two main initial reactions in the oxidation process of C10H22. However, there exists an obvious difference under high and atmospheric pressures. Under high pressure, C–C bond dissociation reactions of hydrocarbon molecules are the main reaction types, while H-abstraction reactions are the main reaction types under atmospheric pressure. The radicals (HO2, OH, O, etc.) play key roles in promoting the oxidation of hydrocarbon molecules. A detailed chemical kinetic model (76 species and 435 elementary reactions), the FP-C10H22 model, of C10H22/air mixture combustion is constructed and verified. The predicted values of FP-C10H22 model on the ignition delay time, laminar flame speed and species concentration of jet stirred reactor (JSR) species concentration are in good agreement with the experimental data.