Soot Oxidation by OH: Theory Development, Model, and Experimental Validation

Hossein Ghiassi; David Lignell; Jo Ann S. Lighty

doi:10.1021/acs.energyfuels.6b02193

Soot Oxidation by OH: Theory Development, Model, and Experimental Validation

Hossein Ghiassi, David Lignell, Jo Ann S. Lighty

College of Engineering Administration

Research output: Contribution to journal › Article › peer-review

14 Scopus citations

Abstract

Soot oxidation by OH has been represented by an equation developed by Neoh that includes the efficiency of OH radicals to react, the collision efficiency. The focus of this study is the theoretical development of the collision efficiency, enabling a more accurate prediction of soot oxidation where OH is the principle oxidizer. In addition to the traditional parameters, such as OH concentration and temperature, this approach aims to improve the prediction of soot oxidation by considering the fraction of the active area as well as the size of the soot particle and aggregate. The fraction of the active area was correlated with the type of C-H bond on the surface of particles and the concentration of H radicals that causes hydrogen abstraction from C-H bonds to create radical sites. The model was validated using experimental data for various fuels and two burner configurations.

Original language	English
Pages (from-to)	2236-2245
Number of pages	10
Journal	Energy and Fuels
Volume	31
Issue number	3
DOIs	https://doi.org/10.1021/acs.energyfuels.6b02193
State	Published - 16 Mar 2017

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10.1021/acs.energyfuels.6b02193

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title = "Soot Oxidation by OH: Theory Development, Model, and Experimental Validation",

abstract = "Soot oxidation by OH has been represented by an equation developed by Neoh that includes the efficiency of OH radicals to react, the collision efficiency. The focus of this study is the theoretical development of the collision efficiency, enabling a more accurate prediction of soot oxidation where OH is the principle oxidizer. In addition to the traditional parameters, such as OH concentration and temperature, this approach aims to improve the prediction of soot oxidation by considering the fraction of the active area as well as the size of the soot particle and aggregate. The fraction of the active area was correlated with the type of C-H bond on the surface of particles and the concentration of H radicals that causes hydrogen abstraction from C-H bonds to create radical sites. The model was validated using experimental data for various fuels and two burner configurations.",

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Y1 - 2017/3/16

N2 - Soot oxidation by OH has been represented by an equation developed by Neoh that includes the efficiency of OH radicals to react, the collision efficiency. The focus of this study is the theoretical development of the collision efficiency, enabling a more accurate prediction of soot oxidation where OH is the principle oxidizer. In addition to the traditional parameters, such as OH concentration and temperature, this approach aims to improve the prediction of soot oxidation by considering the fraction of the active area as well as the size of the soot particle and aggregate. The fraction of the active area was correlated with the type of C-H bond on the surface of particles and the concentration of H radicals that causes hydrogen abstraction from C-H bonds to create radical sites. The model was validated using experimental data for various fuels and two burner configurations.

AB - Soot oxidation by OH has been represented by an equation developed by Neoh that includes the efficiency of OH radicals to react, the collision efficiency. The focus of this study is the theoretical development of the collision efficiency, enabling a more accurate prediction of soot oxidation where OH is the principle oxidizer. In addition to the traditional parameters, such as OH concentration and temperature, this approach aims to improve the prediction of soot oxidation by considering the fraction of the active area as well as the size of the soot particle and aggregate. The fraction of the active area was correlated with the type of C-H bond on the surface of particles and the concentration of H radicals that causes hydrogen abstraction from C-H bonds to create radical sites. The model was validated using experimental data for various fuels and two burner configurations.

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Soot Oxidation by OH: Theory Development, Model, and Experimental Validation

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