Reactive molecular dynamics of pyrolysis and combustion of alternative jet fuels: A ReaxFF study

•Simulation of the pyrolysis and combustion of alternative jet fuels performed by reactive force field molecular dynamics methods.•Comparison performed among saturated hydrocarbon farnesane and two unsaturated compounds, α-farnesene and β-farnesene.•Significant differences observed among the compoun...

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Published inFuel (Guildford) Vol. 310; p. 122157
Main Authors Goncalves, Rene F.B., Iha, Bruno K.V., Rocco, José A.F.F., Kuznetsov, Aleksey E.
Format Journal Article
LanguageEnglish
Published Kidlington Elsevier Ltd 15.02.2022
Elsevier BV
Subjects
Activation energy
Arrhenius parameters
Combustion
Computer applications
Decomposition reactions
Farnesene
Fermentation
Fuels
Hydrocarbon fuels
Hydrocarbons
Jet engine fuels
Jet fuel
Molecular dynamics
Process parameters
Pyrolysis
Reaction mechanism
Reactive molecular dynamics
Reactivity
Saturated hydrocarbons
Simulation
Sugar
Sugarcane
Unsaturated hydrocarbons
Vapor phases
Reaction mechanism
Pyrolysis
Combustion
Arrhenius parameters
Jet fuel
Reactive molecular dynamics
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Summary:•Simulation of the pyrolysis and combustion of alternative jet fuels performed by reactive force field molecular dynamics methods.•Comparison performed among saturated hydrocarbon farnesane and two unsaturated compounds, α-farnesene and β-farnesene.•Significant differences observed among the compound reactions during the decomposition processes.•For the pyrolysis, the obtained activation energies for farnesane, α-farnesene and β-farnesene found to be 132.55, 117.28 and 112.88 kJ mol−1, respectively, and for the combustion, the obtained activation energies found to be 71.63, 37.99 and 37.98 kJ mol−1, respectively. The current work presents the simulation of the pyrolysis and combustion of alternative jet fuels by reactive force field molecular dynamics methods. A comparison has been done between saturated hydrocarbon farnesane and two unsaturated compounds, α-farnesene and β-farnesene, all of them obtained by the fermentation of sugars present in sugarcane juice. The pyrolysis and combustion mechanisms were elucidated for all the three species at a specified temperature. Significant differences have been observed among the compound reactions during the decompositions. Using a first-order approach, the Arrhenius parameters of the global process were obtained with three different temperatures, held constant over time. For the pyrolysis, the obtained activation energies for farnesane, α-farnesene, and β-farnesene were 132.55, 117.28, and 112.88 kJ mol−1, respectively, and for the combustion, the obtained activation energies were 71.63, 37.99, and 37.98 kJ mol−1, respectively. These data are compatible with the results found in the literature for hydrocarbon fuels. A detailed computational study of all three compounds was performed using the B3LYP/6–311 + G(d,p) approach in the gas phase. Analysis of structures, NBO charges, FMOs, MEP plots, and global reactivity parameters unequivocally supports the simulation results obtained using the ReaxFF code, proving noticeably higher potential reactivity of α- and β-farnesenes compared to farnesane, and furthermore higher reactivity of β-farnesene compared to α-farnesene.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2021.122157