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Combustion Science and Technology Volume 59, 1988 - Issue 4-6
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Original Articles

The Coagulation of Soot Particles with van der Waals Forces

STEPHEN J. Harris Physical Chemistry Department, General Motors Research Labs, Warren, M148090-9055
&
IAN M. Kennedy Dept of Mechanical Engineering, University of California, Davis, CA 95616
Pages 443-454 | Received 20 Oct 1987, Published online: 06 Apr 2007

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Richard R. Dobbins, Jesse Tinjero, Joseph Squeo, Xinyu Zhao, Robert J. Hall, Meredith B. Colket, Marshall B. Long & Mitchell D. Smooke. (2023) A Combined Experimental and Computational Study of Soot Formation in Normal and Microgravity Conditions. Combustion Science and Technology 195:15, pages 3882-3907.
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Sung Hoon Park. (2023) Bi-modal moment model for predicting the formation and growth of soot aggregate particles. Particulate Science and Technology 41:1, pages 22-31.
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Yensil Park, Shinobu Tanimura & Barbara E. Wyslouzil. (2016) Enhanced growth rates of nanodroplets in the free molecular regime: The role of long-range interactions. Aerosol Science and Technology 50:8, pages 773-780.
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Sudip Adhikari, Alan Sayre & Abhilash J. Chandy. (2016) A Hybrid Newton/Time Integration Approach Coupled to Soot Moment Methods for Modeling Soot Formation and Growth in Perfectly-Stirred Reactors. Combustion Science and Technology 188:8, pages 1262-1282.
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Yu Wang & Suk Ho Chung. (2016) Formation of Soot in Counterflow Diffusion Flames with Carbon Dioxide Dilution. Combustion Science and Technology 188:4-5, pages 805-817.
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Bei-Jing Zhong, Shuai Dang, Ya-Na Song & Jing-Song Gong. (2012) 3-D simulation of soot formation in a direct-injection diesel engine based on a comprehensive chemical mechanism and method of moments. Combustion Theory and Modelling 16:1, pages 143-171.
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S.B. Dworkin, J.A. Cooke, B.A.V. Bennett, B.C. Connelly, M.B. Long, M.D. Smooke, R.J. Hall & M.B. Colket. (2009) Distributed-memory parallel computation of a forced, time-dependent, sooting, ethylene/air coflow diffusion flame. Combustion Theory and Modelling 13:5, pages 795-822.
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S.H. Park, S.N. Rogak, W.K. Bushe, J.Z. Wen & M.J. Thomson. (2005) An aerosol model to predict size and structure of soot particles. Combustion Theory and Modelling 9:3, pages 499-513.
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ChristopherJ. Pope & JackB. Howard. (1997) Simultaneous Particle and Molecule Modeling (SPAMM): An Approach for Combining Sectional Aerosol Equations and Elementary Gas-Phase Reactions. Aerosol Science and Technology 27:1, pages 73-94.
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