Abstract

Abstract. Organic aerosol concentrations are simulated using the WRF-CHEM model in Mexico City during the period from 24 to 29 March in association with the MILAGRO-2006 campaign. Two approaches are employed to predict the variation and spatial distribution of the organic aerosol concentrations: (1) a traditional 2-product secondary organic aerosol (SOA) model with non-volatile primary organic aerosols (POA); (2) a non-traditional SOA model including the volatility basis-set modeling method in which primary organic components are assumed to be semi-volatile and photochemically reactive and are distributed in logarithmically spaced volatility bins. The MCMA (Mexico City Metropolitan Area) 2006 official emission inventory is used in simulations and the POA emissions are modified and distributed by volatility based on dilution experiments for the non-traditional SOA model. The model results are compared to the Aerosol Mass Spectrometry (AMS) observations analyzed using the Positive Matrix Factorization (PMF) technique at an urban background site (T0) and a suburban background site (T1) in Mexico City. The traditional SOA model frequently underestimates the observed POA concentrations during rush hours and overestimates the observations in the rest of the time in the city. The model also substantially underestimates the observed SOA concentrations, particularly during daytime, and only produces 21% and 25% of the observed SOA mass in the suburban and urban area, respectively. The non-traditional SOA model performs well in simulating the POA variation, but still overestimates during daytime in the urban area. The SOA simulations are significantly improved in the non-traditional SOA model compared to the traditional SOA model and the SOA production is increased by more than 100% in the city. However, the underestimation during daytime is still salient in the urban area and the non-traditional model also fails to reproduce the high level of SOA concentrations in the suburban area. In the non-traditional SOA model, the aging process of primary organic components considerably decreases the OH levels in simulations and further impacts the SOA formation. If the aging process in the non-traditional model does not have feedback on the OH in the gas-phase chemistry, the SOA production is enhanced by more than 10% compared to the simulations with the OH feedback during daytime, and the gap between the simulations and observations in the urban area is around 3 μg m−3 or 20% on average during late morning and early afternoon, within the uncertainty from the AMS measurements and PMF analysis. In addition, glyoxal and methylglyoxal can contribute up to approximately 10% of the observed SOA mass in the urban area and 4% in the suburban area. Including the non-OH feedback and the contribution of glyoxal and methylglyoxal, the non-traditional SOA model can explain up to 83% of the observed SOA in the urban area, and the underestimation during late morning and early afternoon is reduced to 0.9 μg m−3 or 6% on average. Considering the uncertainties from measurements, emissions, meteorological conditions, aging of semi-volatile and intermediate volatile organic compounds, and contributions from background transport, the non-traditional SOA model is capable of closing the gap in SOA mass between measurements and models.

Highlights

  • Atmospheric aerosols influence the radiative balance in Earth’s atmosphere and play a central role in climate, directly by scattering or absorbing a fraction of the incoming solar radiation to cool or warm the atmosphere, and indirectly via their roles as cloud condensation nuclei (CCN) and ice nuclei (IN), by modifying optical properties and lifetime of clouds (e.g., Penner et al, 2001; R. Zhang et al, 2007)

  • Organic aerosols (OA) is categorized into two types: primary OA (POA) that is directly emitted into the atmosphere in particulate form, and secondary OA (SOA) which is formed from chemically processed gaseous organic precursors

  • Since meteorological conditions play a key role in air pollution simulations principally through determining the dispersion or accumulation of pollutant emissions (Bei et al, 2008, 2010), in Fig. 2a and b, we present the spatial distributions of calculated and observed near-surface concentrations of O3 at 14:00 and 17:00 Local Time (LT) from 24 to 29 March 2006, along with the simulated wind fields

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Summary

Introduction

Atmospheric aerosols influence the radiative balance in Earth’s atmosphere and play a central role in climate, directly by scattering or absorbing a fraction of the incoming solar radiation to cool or warm the atmosphere, and indirectly via their roles as cloud condensation nuclei (CCN) and ice nuclei (IN), by modifying optical properties and lifetime of clouds (e.g., Penner et al, 2001; R. Zhang et al, 2007). Organic aerosols (OA) account for 20–90% of the total fine particulate mass in the atmosphere OA is categorized into two types: primary OA (POA) that is directly emitted into the atmosphere in particulate form, and secondary OA (SOA) which is formed from chemically processed gaseous organic precursors. Due to the involvement of multiple volatile organic compounds (VOCs) and the complexity of atmospheric degradation processes of each VOC, there are considerable uncertainties when simulating the atmospheric oxidation products of VOCs that undergo gas-particle transfer to produce SOA. The limited understanding on the formation mechanisms, composition and properties of SOA has constituted the greatest uncertainty in OA prediction in climate and air quality models (Hallquist et al, 2009)

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