Source apportionment of fine particulate matter over the Eastern U.S. Part I: source sensitivity simulations using CMAQ with the Brute Force method

Source apportionment of fine particulate matter over the Eastern U.S. Part I: source sensitivity simulations using CMAQ with the Brute Force method

Exposure to elevated levels of fine particulate matter (PM2.5) is found to be associated with adverse effects on human health, climate change, and visibility. Identification of major sources contributing to PM2.5 is an important step in the formulation of effective reduction strategies. This study u...

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Veröffentlicht in:Atmospheric pollution research 2011-07, Vol.2 (3), p.300-317
Hauptverfasser: Burr, Michael J., Zhang, Yang
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Sprache:eng
Schlagworte:
Air quality
Atmospheric pollution
Atmospheric pollution models
Atmospheric pollution research
Biomass
Brute Force Sensitivity Analysis
burning
Climate change
CMAQ
Coal
Coal combustion
Combustion
Combustion products
Emissions
Numerical simulations
Particle size
Particulate matter in urban air
Particulates
PM2.5
Source apportionment
Southeastern U.S
Urban atmospheric pollution
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description Exposure to elevated levels of fine particulate matter (PM2.5) is found to be associated with adverse effects on human health, climate change, and visibility. Identification of major sources contributing to PM2.5 is an important step in the formulation of effective reduction strategies. This study uses the U.S. EPA’s Community Multiscale Air Quality (CMAQ) modeling system with the brute–force method (BFM) to conduct source apportionment of PM2.5 for 10 source categories over the eastern U.S. at a 12 km horizontal grid resolution for both January and July of 2002. Biomass burning is found to be the greatest contributor to domainwide PM2.5 with a monthly–mean domainwide contribution of ~14% (1.1 µg m–3). The next two largest contributors in January are miscellaneous area sources and coal combustion with contributions of ~12% (0.9 µg m–3) and ~11% (0.9 µg m–3), respectively. In July, coal combustion, miscellaneous area sources, and industrial processes are the top three contributors (by ~31% (2.3 µg m–3), ~9% (0.7 µg m–3), and ~7% (0.5 µg m–3), respectively). Site–specific source contributions indicate that industrial processes and biomass burning are the most important sources of PM2.5 at urban and rural sites, respectively, in January, while coal combustion dominates at both sites in July. While the BFM is theoretically simple and can capture indirect effects resulting from the interactions among precursor and secondary pollutants in the real atmosphere, it is computationally expensive and assumes that the source contributions to each emission category are additive. This assumption does not hold for secondary PM components because of the highly non–linear relationships between precursor emissions and all secondary PM components and, therefore, source apportionment provides no useful information whatsoever on the possible effect of emission reductions on secondary PM.
doi_str_mv 10.5094/APR.2011.036
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source EZB-FREE-00999 freely available EZB journals; Alma/SFX Local Collection
subjects Air quality
Atmospheric pollution
Atmospheric pollution models
Atmospheric pollution research
Biomass
Brute Force Sensitivity Analysis
burning
Climate change
CMAQ
Coal
Coal combustion
Combustion
Combustion products
Emissions
Numerical simulations
Particle size
Particulate matter in urban air
Particulates
PM2.5
Source apportionment
Southeastern U.S
Urban atmospheric pollution
title Source apportionment of fine particulate matter over the Eastern U.S. Part I: source sensitivity simulations using CMAQ with the Brute Force method
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