Evaluating simulated primary anthropogenic and biomass burning organic aerosols during MILAGRO: Implications for assessing treatments of secondary organic aerosols

AMS Citation:
Fast, J., and Coauthors, 2009: Evaluating simulated primary anthropogenic and biomass burning organic aerosols during MILAGRO: Implications for assessing treatments of secondary organic aerosols. Atmospheric Chemistry and Physics, 9, 6191-6215, doi:10.5194/acp-9-6191-2009.
Date:2009-08-31
Resource Type:article
Title:Evaluating simulated primary anthropogenic and biomass burning organic aerosols during MILAGRO: Implications for assessing treatments of secondary organic aerosols
Abstract: Simulated primary organic aerosols (POA), as well as other particulates and trace gases, in the vicinity of Mexico City are evaluated using measurements collected during the 2006 Megacity Initiative: Local and Global Research Observations (MILAGRO) field campaigns. Since the emission inventories, transport, and turbulent mixing will directly affect predictions of total organic matter and consequently total particulate matter, our objective is to assess the uncertainties in predicted POA before testing and evaluating the performance of secondary organic aerosol (SOA) treatments. Carbon monoxide (CO) is well simulated on most days both over the city and downwind, indicating that transport and mixing processes were usually consistent with the meteorological conditions observed during MILAGRO. Predicted and observed elemental carbon (EC) in the city was similar, but larger errors occurred at remote locations since the overall CO/EC emission ratios in the national emission inventory were lower than in the metropolitan emission inventory. Components of organic aerosols derived from Positive Matrix Factorization of data from several Aerodyne Aerosol Mass Spectrometer instruments deployed both at ground sites and on research aircraft are used to evaluate the model. Modeled POA was consistently lower than the measured organic matter at the ground sites, which is consistent with the expectation that SOA should be a large fraction of the total organic matter mass. A much better agreement was found when modeled POA was compared with the sum of "primary anthropogenic" and "biomass burning" components derived from Positive Matrix Factorization (PMF) on most days, especially at the surface sites, suggesting that the overall magnitude of primary organic particulates released was reasonable. However, simulated POA from anthropogenic sources was often lower than "primary anthropogenic" components derived from PMF, consistent with two recent reports that these emissions are underestimated. The modeled POA was greater than the total observed organic matter when the aircraft flew directly downwind of large fires, suggesting that biomass burning emission estimates from some large fires may be too high.
Peer Review:Non-refereed
Copyright Information:Copyright Author(s) 2009. This work is distributed under the Creative Commons Attribution 3.0 License.
OpenSky citable URL: ark:/85065/d7b8594d
Publisher's Version: 10.5194/acp-9-6191-2009
Author(s):
  • J. Fast
  • C. Aiken
  • J. Allan
  • L. Alexander
  • Teresa Campos - NCAR/UCAR
  • M. Canagaratna
  • E. Chapman
  • P. DeCarlo
  • B. de Foy
  • J. Gaffney
  • J. de Gouw
  • J. Doran
  • Louisa Emmons - NCAR/UCAR
  • Alma Hodzic - NCAR/UCAR
  • C. Herndon
  • G. Huey
  • J. Jayne
  • J. Jimenez
  • L. Kleinman
  • W. Kuster
  • N. Marley
  • L. Russell
  • C. Ochoa
  • T. Onasch
  • M. Pekour
  • C. Song
  • I. Ulbrich
  • C. Warneke
  • D. Welsh-Bon
  • Christine Wiedinmyer - NCAR/UCAR
  • D. Worsnop
  • X-Y Yu
  • R. Zaveri
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