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Improved sizing of soot primary particles using mass-mobility measurements Dastanpour, Ramin; Rogak, Steven; Graves, Brian; Olfert, Jason; Eggersdorfer, Maximilian L.; Boies, Adam M.

Abstract

The properties and impacts of aggregated aerosol particles (i.e. soot, metal oxide fumes) depend on their morphology, as characterized by fractal dimension, prefactor and primary particle diameter. The morphology may be measured directly by time consuming ex situ microscopy or rapid but indirect in situ methods. Previously it was found that particle mass and mobility measurements could be used for the estimation of the primary particle diameter of zirconia aggregates, using plausible assumptions related to the fractal structure (specifically, prefactor π‘˜a and exponent 𝐷α). Since the formation and growth of zirconia aggregates are different from carbon soot, here we compare primary particle diameters measured directly from transmission electron microscopy analysis of soot particles with the diameters estimated from mass-mobility measurements. Performing extensive measurements on soot emissions from two reciprocating engines over a range of operating conditions, we found that there are no universal values of π‘˜a and 𝐷α that can be used for all conditions. However, new optimized values of π‘˜a and 𝐷α are estimated here for soot particles. The variation of the primary particle diameter with particle size is also taken into consideration and is shown to be essential to obtain physically realistic results. Using optimized values of π‘˜a and 𝐷α, the average primary particle sizing error is reduced for all soot types. This suggests that with some calibration, in situ sizing of the primary particle diameter, using mass and mobility measurements, can provide useful accuracy.

Item Metadata

Title
Improved sizing of soot primary particles using mass-mobility measurements
Creator
Dastanpour, Ramin; Rogak, Steven; Graves, Brian; Olfert, Jason; Eggersdorfer, Maximilian L.; Boies, Adam M.
Date Issued
2016-02-01
Description
The properties and impacts of aggregated aerosol particles (i.e. soot, metal oxide fumes) depend on their morphology, as characterized by fractal dimension, prefactor and primary particle diameter. The morphology may be measured directly by time consuming ex situ microscopy or rapid but indirect in situ methods. Previously it was found that particle mass and mobility measurements could be used for the estimation of the primary particle diameter of zirconia aggregates, using plausible assumptions related to the fractal structure (specifically, prefactor π‘˜a and exponent 𝐷α). Since the formation and growth of zirconia aggregates are different from carbon soot, here we compare primary particle diameters measured directly from transmission electron microscopy analysis of soot particles with the diameters estimated from mass-mobility measurements. Performing extensive measurements on soot emissions from two reciprocating engines over a range of operating conditions, we found that there are no universal values of π‘˜a and 𝐷α that can be used for all conditions. However, new optimized values of π‘˜a and 𝐷α are estimated here for soot particles. The variation of the primary particle diameter with particle size is also taken into consideration and is shown to be essential to obtain physically realistic results. Using optimized values of π‘˜a and 𝐷α, the average primary particle sizing error is reduced for all soot types. This suggests that with some calibration, in situ sizing of the primary particle diameter, using mass and mobility measurements, can provide useful accuracy.
Genre
Article; Postprint
Type
Text
Language
eng
Date Available
2017-02-01
Provider
Vancouver : University of British Columbia Library
Rights
Attribution-NonCommercial-NoDerivatives 4.0 International
DOI
10.14288/1.0314574
URI
http://hdl.handle.net/2429/59257
Affiliation
Applied Science, Faculty of; Non UBC; Mechanical Engineering, Department of
Citation
Dastanpour R, Rogak SN, Graves B, Olfert J, Eggersdorfer ML, Boies AM. Improved sizing of soot primary particles using mass-mobility measurements. Aerosol Sci Technol. 2016;50(2):101-109.
Publisher DOI
10.1080/02786826.2015.1130796
Peer Review Status
Reviewed
Scholarly Level
Faculty; Postdoctoral; Graduate
Rights URI
http://creativecommons.org/licenses/by-nc-nd/4.0/
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Attribution-NonCommercial-NoDerivatives 4.0 International