Air pollution: Current challenges and future opportunities

Seigneur, Christian

doi:10.1002/aic.10458

Cited by 16 publications

(8 citation statements)

References 51 publications

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“…Although significant progress has been made in modeling climate, meteorology, air pollution in the past several decades (Seaman, 2000;Seinfeld, 2004;Seigneur, 2005), several major deficiencies exist in most current global climate-aerosol models (e.g., Johnson et al, 1999Johnson et al, , 2001Langner et al, 2005;Sanderson et al, 2006) that are developed either based on a general circulation model (GCM) or a global chemical transport model. First, the coarse spatial resolution (e.g., 4 • ×5 • ) used in those models cannot explicitly capture the fine-scale structure that characterizes climatic changes (e.g., clouds, precipitation, mesoscale circulation, sub-grid convective system, etc.).…”

Section: Introductionmentioning

confidence: 99%

Online-coupled meteorology and chemistry models: history, current status, and outlook

2008

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Abstract. The climate-chemistry-aerosol-cloud-radiation feedbacks are important processes occurring in the atmosphere. Accurately simulating those feedbacks requires fully-coupled meteorology, climate, and chemistry models and presents significant challenges in terms of both scientific understanding and computational demand. This paper reviews the history and current status of the development and application of online-coupled meteorology and chemistry models, with a focus on five representative models developed in the US including GATOR-GCMOM, WRF/Chem, CAM3, MIRAGE, and Caltech unified GCM. These models represent the current status and/or the state-of-the science treatments of online-coupled models worldwide. Their major model features, typical applications, and physical/chemical treatments are compared with a focus on model treatments of aerosol and cloud microphysics and aerosol-cloud interactions. Aerosol feedbacks to planetary boundary layer meteorology and aerosol indirect effects are illustrated with case studies for some of these models. Future research needs for model development, improvement, application, as well as major challenges for online-coupled models are discussed.

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Section: Introductionmentioning

confidence: 99%

Online-coupled meteorology and chemistry models: history, current status, and outlook

2008

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“…While significant progress has been made to reduce emissions of their precursors, and their concentrations have been declined steadily in recent years [ U.S. Environmental Protection Agency ( U.S. EPA ), 2005; Seinfeld , 2004; Seigneur , 2005], regional O 3 and PM 2.5 pollution as well as the impacts on climate on local to global scales continue to be a pervasive problem worldwide. They have been a central focus of three‐dimensional (3‐D) air quality and climate modeling efforts on urban to global scales worldwide in the past half century [ Seinfeld , 2004; Seigneur , 2005; Horowitz , 2006; Zhang , 2008] and will continue to be key pollutants for modeling future regional/global change into 2100 [ Hogrefe et al , 2004; IPCC , 2007; U.S. Climate Change Science Program , 2008; S. Wu et al , 2008; Zhang et al , 2008].…”

Section: Introductionmentioning

confidence: 99%

Probing into regional ozone and particulate matter pollution in the United States: 1. A 1 year CMAQ simulation and evaluation using surface and satellite data

et al. 2009

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[1] As part 1 in a series of papers describing long-term simulations using the Community Multiscale Air Quality (CMAQ) modeling system and subsequent process analyses and sensitivity simulations, this paper presents a comprehensive model evaluation for the full year of 2001 over the continental U.S. using both ground-based and satellite measurements. CMAQ is assessed for its ability to reproduce concentrations and long-term trends of major criteria pollutants such as surface ozone (O 3 ) and fine particulate matter (PM 2.5 ) and related variables such as indicator species, wet deposition fluxes, and column mass abundances of carbon monoxide (CO), nitrogen oxides (NO 2 ), tropospheric ozone residuals (TORs), and aerosol optical depths (AODs). The domain-wide and site-specific evaluation of surface predictions shows an overall satisfactory performance in terms of normalized mean biases for annual mean maximum 1 h and 8 h average O 3 mixing ratios (À11.6 to 0.1% and À4.6 to 3.0%, respectively), 24 h average concentrations of PM 2.5 (4.2-35.3%), sulfate (À13.0 to 43.5%), and organic carbon (OC) (À37.6 to 24.8%), and wet deposition fluxes (À13.3 to 31.6%). Larger biases, however, occur in the concentrations and wet deposition fluxes of ammonium and nitrate domain-wide and in the concentrations of PM 2.5 , sulfate, black carbon, and OC at some urban/suburban sites. The reasons for such model biases may be errors in emissions, chemistry, aerosol processes, or meteorology. The evaluation of column mass predictions shows a good model performance in capturing the seasonal variations and magnitudes of column CO and NO 2 , but relatively poor performance in reproducing observed spatial distributions and magnitudes of TORs for winter and spring and those of AODs in all seasons. Possible reasons for the poor column predictions include the underestimates of emissions, inaccurate upper layer boundary conditions, lack of model treatments of sea salt and dust, and limitations and uncertainties in satellite data.Citation: Zhang, Y., K. Vijayaraghavan, X.-Y. Wen, H. E. Snell, and M. Z. Jacobson (2009), Probing into regional ozone and particulate matter pollution in the United States: 1. A 1 year CMAQ simulation and evaluation using surface and satellite data,

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“…Although smoke particles can significantly alter regional chemistry and atmospheric radiative forcing, aerosol emissions from wildfires and their effects on air quality are rarely taken into account in air quality models (e.g. Seigneur 2005;Hodzic et al, 2005). Until recently, modeling efforts to include wildfire emission in chemistry-transport model (CTM) simulations and air quality forecasting were limited to regional climate models (e.g.…”

Section: Impact Of Fires On Atmospheric Propertiesmentioning

confidence: 99%

Wildfire particulate matter in Europe during summer 2003: meso-scale modeling of smoke emissions, transport and radiative effects

et al. 2007

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Abstract. The present study investigates effects of wildfire emissions on air quality in Europe during an intense fire season that occurred in summer 2003. A meso-scale chemistry transport model CHIMERE is used, together with ground based and satellite aerosol optical measurements, to assess the dispersion of fire emissions and to quantify the associated radiative effects. The model has been improved to take into account a MODIS-derived daily smoke emission inventory as well as the injection altitude of smoke particles. The simulated aerosol optical properties are put into a radiative transfer model to estimate (off-line) the effects of smoke particles on photolysis rates and atmospheric radiative forcing. We have found that the simulated wildfires generated comparable amounts of primary aerosol pollutants (130 kTons of PM 2.5 , fine particles) to anthropogenic sources during August 2003, and caused significant changes in aerosol optical properties not only close to the fire source regions, but also over a large part of Europe as a result of the long-range transport of the smoke. Including these emissions into the model significantly improved its performance in simulating observed aerosol concentrations and optical properties. Quantitative comparison with MODIS and POLDER data during the major fire event (3-8 August 2003) showed the ability of the model to reproduce high aerosol optical thickness (AOT) over Northern Europe caused by the advection of the smoke plume from the Portugal source region. Although there was a fairly good spatial agreement with satellite data (correlation coefficients ranging from 0.4 to 0.9), the temporal variability of AOT data at specific AERONET locations was not well captured by the model. Statistical analyses of modelsimulated AOT data at AERONET ground stations showed a significant decrease in the model biases suggesting that wildfire emissions are responsible for a 30% enhancement in mean AOT values during the heat-wave episode. The impliCorrespondence to: A. Hodzic (alma@ucar.edu) cations for air quality over a large part of Europe are significant during this episode. First, directly, the modeled wildfire emissions caused an increase in average PM 2.5 ground concentrations from 20 to 200%. The largest enhancement in PM 2.5 concentrations stayed, however, confined within a 200 km area around the fire source locations and reached up to 40 µg/m 3 . Second, indirectly, the presence of elevated smoke layers over Europe significantly altered atmospheric radiative properties: the model results imply a 10 to 30% decrease in photolysis rates and an increase in atmospheric radiative forcing of 10-35 W m −2 during the period of strong fire influence throughout a large part of Europe. These results suggest that sporadic wildfire events may have significant effects on regional photochemistry and atmospheric stability, and need to be considered in current chemistry-transport models.

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Air pollution: Current challenges and future opportunities

Cited by 16 publications

References 51 publications

Online-coupled meteorology and chemistry models: history, current status, and outlook

Online-coupled meteorology and chemistry models: history, current status, and outlook

Probing into regional ozone and particulate matter pollution in the United States: 1. A 1 year CMAQ simulation and evaluation using surface and satellite data

Wildfire particulate matter in Europe during summer 2003: meso-scale modeling of smoke emissions, transport and radiative effects

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