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Soot Optical Property StudyRecent past studies of soot reaction processes in laminar premixed and nonpremixed flames generally have used the intrusive technique of thermophoretic sampling and analysis by transmission electron microscopy (TEM) to observe soot structure and obtain important fundamental information about soot particle properties, such as soot primary particle diameters, the rate of change of soot primary particle diameter as a function of time (or rate of soot surface growth or oxidation), the amount of soot particle reactive surface area per unit volume, the number of primary soot particles per unit volume, and the rate of formation of primary soot particles (or the rate of soot primary particle nucleation). Given the soot volume per unit volume of the flame (or the soot volume fraction), all these properties are readily found from a measurement of the soot primary particle diameter (which usually is nearly a constant for each location within a laminar flame). This approach is not possible within freely propagating flames, however, because soot properties at given positions in such flames vary relatively rapidly as a function of time in the soot formation and oxidation regions compared to the relatively lengthy sampling times needed to accumulate adequate soot samples and to minimize effects of soot collected on the sampling grid as it moves to and from the sampling position through other portions of the flame. Thus, nonintrusive optical methods must be used to find the soot primary particle diameters needed to define the soot surface reaction properties mentioned earlier. Unfortunately, approximate nonintrusive methods used during early studies of soot reaction properties in flames, found from laser scattering and absorption measurements analyzed assuming either Rayleigh scattering or Mie scattering from polydisperse effective soot particles having the same mass of soot as individual soot aggregates, have not been found to be an effective way to estimate the soot surface reaction area per unit volume. Thus, alternative nonintrusive optical methods of finding these properties must be sought, which was the objective of this phase of the investigation. The alternative method used here involves use of the Rayleigh-Debye-Gans-Polydisperse-Fractal-Aggregate (RDG-PFA) scattering approximation for soot aggregates in flames. Thus, the development of this method will be discussed next before describing its evaluation as a means of nonintrusively measuring soot primary particle diameters in soot-containing flames.
Document ID
20020087827
Acquisition Source
Glenn Research Center
Document Type
Other
Authors
Aung, K. T. (Michigan Univ. Ann Arbor, MI United States)
Hassan, M. I. (Michigan Univ. Ann Arbor, MI United States)
Krishnan, S. S. (Michigan Univ. Ann Arbor, MI United States)
Lin, K.-C. (Michigan Univ. Ann Arbor, MI United States)
Xu, F. (Michigan Univ. Ann Arbor, MI United States)
Faeth, G. M. (Michigan Univ. Ann Arbor, MI United States)
Urban, D. L.
Yuan, Z.-G.
Date Acquired
September 7, 2013
Publication Date
December 15, 2001
Publication Information
Publication: Soot Formation in Freely-Propagating Laminar Premixed Flames
Subject Category
Inorganic, Organic And Physical Chemistry
Funding Number(s)
CONTRACT_GRANT: NAG3-1878
Distribution Limits
Public
Copyright
Work of the US Gov. Public Use Permitted.

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