A comparison of diffusive transport in a moment method for nanoparticle coagulation

Nelson Settumba; Sean C Garrick

doi:10.1016/j.jaerosci.2003.08.001

A comparison of diffusive transport in a moment method for nanoparticle coagulation

Nelson Settumba, Sean C Garrick

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Abstract

Direct numerical simulations of nanoparticle coagulation in temporal mixing layers using two different formulations for particle diffusion are compared. In the first formulation, a diffusion coefficient based on the local mean volume is used while the second formulation utilizes diffusion coefficients which are based on each particle size. A moment method in conjunction with a lognormal particle size distribution is used to represent the particle field. Results indicate that simulations using diffusion coefficients based on the local mean volume predict slightly higher polydispersity. Furthermore, the simulations using diffusion coefficients based on the local mean volume can be performed at reduced spatial resolutions which allows for more affordable computations.

Original language	English (US)
Pages (from-to)	93-101
Number of pages	9
Journal	Journal of Aerosol Science
Volume	35
Issue number	1
DOIs	https://doi.org/10.1016/j.jaerosci.2003.08.001
State	Published - Jan 2004

Bibliographical note

Funding Information:
This research is supported through the DURINT program under grant DAAD 19-01-1-0503 by the Army Research Office. Computational resources are provided by the Minnesota Supercomputing Institute for Digital Simulation and Advanced Computation.

Keywords

Coagulation
Diffusion
Direct numerical simulation
Moment method
Nanoparticles
Turbulence

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title = "A comparison of diffusive transport in a moment method for nanoparticle coagulation",

abstract = "Direct numerical simulations of nanoparticle coagulation in temporal mixing layers using two different formulations for particle diffusion are compared. In the first formulation, a diffusion coefficient based on the local mean volume is used while the second formulation utilizes diffusion coefficients which are based on each particle size. A moment method in conjunction with a lognormal particle size distribution is used to represent the particle field. Results indicate that simulations using diffusion coefficients based on the local mean volume predict slightly higher polydispersity. Furthermore, the simulations using diffusion coefficients based on the local mean volume can be performed at reduced spatial resolutions which allows for more affordable computations.",

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N2 - Direct numerical simulations of nanoparticle coagulation in temporal mixing layers using two different formulations for particle diffusion are compared. In the first formulation, a diffusion coefficient based on the local mean volume is used while the second formulation utilizes diffusion coefficients which are based on each particle size. A moment method in conjunction with a lognormal particle size distribution is used to represent the particle field. Results indicate that simulations using diffusion coefficients based on the local mean volume predict slightly higher polydispersity. Furthermore, the simulations using diffusion coefficients based on the local mean volume can be performed at reduced spatial resolutions which allows for more affordable computations.

AB - Direct numerical simulations of nanoparticle coagulation in temporal mixing layers using two different formulations for particle diffusion are compared. In the first formulation, a diffusion coefficient based on the local mean volume is used while the second formulation utilizes diffusion coefficients which are based on each particle size. A moment method in conjunction with a lognormal particle size distribution is used to represent the particle field. Results indicate that simulations using diffusion coefficients based on the local mean volume predict slightly higher polydispersity. Furthermore, the simulations using diffusion coefficients based on the local mean volume can be performed at reduced spatial resolutions which allows for more affordable computations.

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KW - Nanoparticles

KW - Turbulence

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A comparison of diffusive transport in a moment method for nanoparticle coagulation

Abstract

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Keywords

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