Atomistic insight into the effects of electrostatic fields on hydrocarbon reaction kinetics

Reactive Molecular Dynamics (MD) and Density Functional Theory (DFT) computations are performed to provide insight into the effects of external electrostatic fields on hydrocarbon reaction kinetics. By comparing the results from MD and DFT, the suitability of the MD method in modeling electrodynamic...

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Veröffentlicht in:	The Journal of chemical physics 2023-02, Vol.158 (5), p.054109-054109
Hauptverfasser:	Kritikos, Efstratios M., Lele, Aditya, van Duin, Adri C. T., Giusti, Andrea
Format:	Artikel
Sprache:	eng
Schlagworte:	Acceleration Charge transfer Chemical kinetics and dynamics Chemical reaction dynamics Chemically reactive flows Density functional theory Dipole moments Dodecane Electric fields Electrodynamics Electronegativity Electrostatics Energy transfer Hydrocarbons Induced polarization INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY Lorentz force Modelling Molecular conformation Molecular dynamics Molecular structure Oxidation Oxidizing agents Pyrolysis Reacting flow Reaction kinetics ReaxFF. electric fields Redox reactions Stabilization
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creator	Kritikos, Efstratios M. Lele, Aditya van Duin, Adri C. T. Giusti, Andrea
description	Reactive Molecular Dynamics (MD) and Density Functional Theory (DFT) computations are performed to provide insight into the effects of external electrostatic fields on hydrocarbon reaction kinetics. By comparing the results from MD and DFT, the suitability of the MD method in modeling electrodynamics is first assessed. Results show that the electric field-induced polarization predicted by the MD charge equilibration method is in good agreement with various DFT charge partitioning schemes. Then, the effects of oriented external electric fields on the transition pathways of non-redox reactions are investigated. Results on the minimum energy path suggest that electric fields can cause catalysis or inhibition of oxidation reactions, whereas pyrolysis reactions are not affected due to the weaker electronegativity of the hydrogen and carbon atoms. MD simulations of isolated reactions show that the reaction kinetics is also affected by applied external Lorentz forces and interatomic Coulomb forces since they can increase or decrease the energy of collision depending on the molecular conformation. In addition, electric fields can affect the kinetics of polar species and force them to align in the direction of field lines. These effects are attributed to energy transfer via intermolecular collisions and stabilization under the external Lorentz force. The kinetics of apolar species is not significantly affected mainly due to the weak induced dipole moment even under strong electric fields. The dynamics and reaction rates of species are studied by means of large-scale combustion simulations of n-dodecane and oxygen mixtures. Results show that under strong electric fields, the fuel, oxidizer, and most product molecules experience translational and rotational acceleration mainly due to close charge transfer along with a reduction in their vibrational energy due to stabilization. This study will serve as a basis to improve the current methods used in MD and to develop novel methodologies for the modeling of macroscale reacting flows under external electrostatic fields.
doi_str_mv	10.1063/5.0134785
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Results on the minimum energy path suggest that electric fields can cause catalysis or inhibition of oxidation reactions, whereas pyrolysis reactions are not affected due to the weaker electronegativity of the hydrogen and carbon atoms. MD simulations of isolated reactions show that the reaction kinetics is also affected by applied external Lorentz forces and interatomic Coulomb forces since they can increase or decrease the energy of collision depending on the molecular conformation. In addition, electric fields can affect the kinetics of polar species and force them to align in the direction of field lines. These effects are attributed to energy transfer via intermolecular collisions and stabilization under the external Lorentz force. The kinetics of apolar species is not significantly affected mainly due to the weak induced dipole moment even under strong electric fields. 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T.</au><au>Giusti, Andrea</au><aucorp>Pennsylvania State Univ., University Park, PA (United States)</aucorp><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Atomistic insight into the effects of electrostatic fields on hydrocarbon reaction kinetics</atitle><jtitle>The Journal of chemical physics</jtitle><addtitle>J Chem Phys</addtitle><date>2023-02-07</date><risdate>2023</risdate><volume>158</volume><issue>5</issue><spage>054109</spage><epage>054109</epage><pages>054109-054109</pages><issn>0021-9606</issn><eissn>1089-7690</eissn><coden>JCPSA6</coden><abstract>Reactive Molecular Dynamics (MD) and Density Functional Theory (DFT) computations are performed to provide insight into the effects of external electrostatic fields on hydrocarbon reaction kinetics. By comparing the results from MD and DFT, the suitability of the MD method in modeling electrodynamics is first assessed. Results show that the electric field-induced polarization predicted by the MD charge equilibration method is in good agreement with various DFT charge partitioning schemes. Then, the effects of oriented external electric fields on the transition pathways of non-redox reactions are investigated. Results on the minimum energy path suggest that electric fields can cause catalysis or inhibition of oxidation reactions, whereas pyrolysis reactions are not affected due to the weaker electronegativity of the hydrogen and carbon atoms. MD simulations of isolated reactions show that the reaction kinetics is also affected by applied external Lorentz forces and interatomic Coulomb forces since they can increase or decrease the energy of collision depending on the molecular conformation. In addition, electric fields can affect the kinetics of polar species and force them to align in the direction of field lines. These effects are attributed to energy transfer via intermolecular collisions and stabilization under the external Lorentz force. The kinetics of apolar species is not significantly affected mainly due to the weak induced dipole moment even under strong electric fields. The dynamics and reaction rates of species are studied by means of large-scale combustion simulations of n-dodecane and oxygen mixtures. Results show that under strong electric fields, the fuel, oxidizer, and most product molecules experience translational and rotational acceleration mainly due to close charge transfer along with a reduction in their vibrational energy due to stabilization. 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subjects	Acceleration Charge transfer Chemical kinetics and dynamics Chemical reaction dynamics Chemically reactive flows Density functional theory Dipole moments Dodecane Electric fields Electrodynamics Electronegativity Electrostatics Energy transfer Hydrocarbons Induced polarization INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY Lorentz force Modelling Molecular conformation Molecular dynamics Molecular structure Oxidation Oxidizing agents Pyrolysis Reacting flow Reaction kinetics ReaxFF. electric fields Redox reactions Stabilization
title	Atomistic insight into the effects of electrostatic fields on hydrocarbon reaction kinetics
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