Reactive molecular dynamics simulation and chemical kinetic modeling of pyrolysis and combustion of n-dodecane

• Published in: Combustion and flame Vol. 158; no. 2; pp. 217 - 226
• Main Authors: Wang, Quan-De, Wang, Jing-Bo, Li, Juan-Qin, Tan, Ning-Xin, Li, Xiang-Yuan
• Format: Journal Article
• Language: English
• Published: Amsterdam Elsevier Inc 01.02.2011; Elsevier
• Subjects: Applied sciences; chemical bonding; Chemical kinetic modeling; COMBUSTION; COMBUSTION KINETICS; COMBUSTION PRODUCTS; Combustion. Flame; DEHYDROGENATION; DENSITY; DISTRIBUTION; DODECANE; Energy; Energy. Thermal use of fuels; Exact sciences and technology; FORMALDEHYDE; free radicals; FUELS; HYDROCARBONS; INORGANIC, ORGANIC, PHYSICAL AND ANALYTICAL CHEMISTRY; molecular dynamics; MOLECULAR DYNAMICS METHOD; n-Dodecane; PRESSURE DEPENDENCE; PYROLYSIS; ReaxFF; SIMULATION; Theoretical studies. Data and constants. Metering; ReaxFF; Pyrolysis; Combustion; n-Dodecane; Chemical kinetic modeling; Dodecane; Hydrocarbon; Molecular dynamics; Flame propagation; Modeling; Chemical reaction kinetics; Formaldehyde; Combustion kinetics; Pressure effect; Simulation; Reaction mechanism; Flame structure; Oxidation; Comparative study
• ISSN: 0010-2180; 1556-2921
• DOI: 10.1016/j.combustflame.2010.08.010

The initiation mechanisms and kinetics of pyrolysis and combustion of n-dodecane are investigated by using the reactive molecular dynamics (ReaxFF MD) simulation and chemical kinetic modeling. From ReaxFF MD simulations, we find the initiation mechanisms of pyrolysis of n-dodecane are mainly through two pathways, (1) the cleavage of C–C bond to form smaller hydrocarbon radicals, and (2) the dehydrogenation reaction to form an H radical and the corresponding n-C 12H 25 radical. Another pathway is the H-abstraction reactions by small radicals including H, CH 3, and C 2H 5, which are the products after the initiation reaction of n-dodecane pyrolysis. ReaxFF MD simulations lead to reasonable Arrhenius parameters compared with experimental results based on first-order kinetic analysis of n-dodecane pyrolysis. The density/pressure effects on the pyrolysis of n-dodecane are also analyzed. By appropriate mapping of the length and time from macroscopic kinetic modeling to ReaxFF MD, a simple comparison of the conversion of n-dodecane from ReaxFF MD simulations and that from kinetic modeling is performed. In addition, the oxidation of n-dodecane is studied by ReaxFF MD simulations. We find that formaldehyde molecule is an important intermediate in the oxidation of n-dodecane, which has been confirmed by kinetic modeling, and ReaxFF leads to reasonable reaction pathways for the oxidation of n-dodecane. These results indicate that ReaxFF MD simulations can give an atomistic description of the initiation mechanism and product distributions of pyrolysis and combustion for hydrocarbon fuels, and can be further used to provide molecular based robust kinetic reaction mechanism for chemical kinetic modeling of hydrocarbon fuels.