Characterization of the light scattering by ensembles of randomly distributed soot aggregates

Soot particles formed in combustion processes commonly exist in the form of ensembles of randomly distributed aggregates of small, nearly spherical monomers. In this paper, these randomly distributed aggregates are numerically generated using a combination of the cluster–cluster aggregation algorith...

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Bibliographic Details
Published in:Journal of quantitative spectroscopy & radiative transfer 2011-11, Vol.112 (17), p.2722-2732
Main Authors: Cui, Z.W., Han, Y.P., Li, C.Y.
Format: Article
Language:English
Subjects:
Boundary integral method
Domain decomposition method
Finite element method
Light scattering
Soot aggregates
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Summary:Soot particles formed in combustion processes commonly exist in the form of ensembles of randomly distributed aggregates of small, nearly spherical monomers. In this paper, these randomly distributed aggregates are numerically generated using a combination of the cluster–cluster aggregation algorithm with the Monte Carlo method. Moreover, an efficient and accurate numerical method is presented for characterizing the light scattering by these complex soot particles illuminated by plane wave and Gaussian beam. This method exploits the unique features of the hybrid finite element-boundary integral method and, more importantly, the unique features of soot aggregates. It is designed in such a manner that it first decomposes the original problem into many sub-regions, where each primary particle is regarded as a sub-region, and then it employs the edge-based finite element method to deal with each sub-region. The sub-regions communicate through the near-field Green’s function. To reduce computational burdens, an iterative domain decomposition method in combination with parallel conjugate gradient method is adopted to solve the coupling system of equations. As an illustration, we present some of our preliminary numerical results. The results are expected to provide useful insights into the optical properties of soot particles formed in combustion processes. ► A hybrid method is proposed to simulate the ensembles of randomly distributed soot aggregates. ► A FE-BI-DDM method is presented for characterizing the light scattering by soot aggregates. ► Scattering of plane wave and Gaussian beam by soot aggregates is investigated. ► Results provide useful insights into the optical properties of soot particles.
ISSN:0022-4073
1879-1352
DOI:10.1016/j.jqsrt.2011.07.011