Estimated Effects of Temperature on Secondary Organic Aerosol Concentrations

Sheehan, Paul E.; Bowman, Frank M.

doi:10.1021/es001547g

Cited by 180 publications

(146 citation statements)

References 25 publications

(38 reference statements)

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“…3,32 In addition, the low temperature and frequent inversion were also likely favorable for the formation of secondary organic aerosol according to Sheehan and Bowman's study using an absorptive-partitioning model, in which variation of vapor pressures with temperature is assumed to be the main source of temperature effects. 33 Relationship between OC and EC As mentioned above, weekly OC and EC concentrations varied similarly at both CGZ and THU. As shown in Figure 3, additional statistical analysis indicated they were linearly correlated.…”

Section: Resultsmentioning

confidence: 74%

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China

Yang

et al. 2005

Journal of the Air & Waste Management Association

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One-week integrated fine particulate matter (i.e., particles Ͻ2.5 m in diameter; PM 2.5 ) samples were collected continuously with a low-flow rate sampler at a downtown site and 18%, respectively, higher than those at Chegongzhuang, which could be attributed to different local emissions of primary carbonaceous particles and gaseous precursors of SOC, as well as different summer photochemical intensities between the two locations.

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Section: Resultsmentioning

confidence: 74%

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China

Yang

et al. 2005

Journal of the Air & Waste Management Association

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“…Sulfate concentrations increase with temperature (Aw and Kleeman, 2003;Dawson et al, 2007b;Kleeman, 2007), due to faster SO 2 oxidation (higher rate constants and higher oxidant concentrations). In contrast, nitrate and organic semi-volatile components shift from the particle phase to the gas phase with increasing temperature (Sheehan and Bowman, 2001;Tsigaridis and Kanakidou, 2007). Model sensitivity studies indicate large decreases of nitrate PM with increasing temperature, dominating the overall effect on PM concentrations in regions where nitrate is a relatively large component (Dawson et al, 2007b;Kleeman, 2007).…”

Section: Particulate Mattermentioning

confidence: 97%

Effect of climate change on air quality

Jacob

Winner

2009

Atmospheric Environment

1,589

1,232

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a b s t r a c tAir quality is strongly dependent on weather and is therefore sensitive to climate change. Recent studies have provided estimates of this climate effect through correlations of air quality with meteorological variables, perturbation analyses in chemical transport models (CTMs), and CTM simulations driven by general circulation model (GCM) simulations of 21st-century climate change. We review these different approaches and their results. The future climate is expected to be more stagnant, due to a weaker global circulation and a decreasing frequency of mid-latitude cyclones. The observed correlation between surface ozone and temperature in polluted regions points to a detrimental effect of warming. Coupled GCM-CTM studies find that climate change alone will increase summertime surface ozone in polluted regions by 1-10 ppb over the coming decades, with the largest effects in urban areas and during pollution episodes. This climate penalty means that stronger emission controls will be needed to meet a given air quality standard. Higher water vapor in the future climate is expected to decrease the ozone background, so that pollution and background ozone have opposite sensitivities to climate change. The effect of climate change on particulate matter (PM) is more complicated and uncertain than for ozone. Precipitation frequency and mixing depth are important driving factors but projections for these variables are often unreliable. GCM-CTM studies find that climate change will affect PM concentrations in polluted environments by AE0.1-1 mg m À3 over the coming decades. Wildfires fueled by climate change could become an increasingly important PM source. Major issues that should be addressed in future research include the ability of GCMs to simulate regional air pollution meteorology and its sensitivity to climate change, the response of natural emissions to climate change, and the atmospheric chemistry of isoprene. Research needs to be undertaken on the effect of climate change on mercury, particularly in view of the potential for a large increase in mercury soil emissions driven by increased respiration in boreal ecosystems.

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“…This parameter governs the temperature dependence of atmospheric SOA concentrations (Sheehan and Bowman, 2001). Due to its substantial impact, this update has been plotted separately in Figs.…”

Section: Soa Model Enhancementsmentioning

confidence: 99%

Incremental testing of the Community Multiscale Air Quality (CMAQ) modeling system version 4.7

et al. 2010

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Abstract. This paper describes the scientific and structural updates to the latest release of the Community Multiscale Air Quality (CMAQ) modeling system version 4.7 (v4.7) and points the reader to additional resources for further details. The model updates were evaluated relative to observations and results from previous model versions in a series of simulations conducted to incrementally assess the effect of each change. The focus of this paper is on five major scientific upgrades: (a) updates to the heterogeneous N 2 O 5 parameterization, (b) improvement in the treatment of secondary organic aerosol (SOA), (c) inclusion of dynamic mass transfer for coarse-mode aerosol, (d) revisions to the cloud model, and (e) new options for the calculation of photolysis rates. Incremental test simulations over the eastern United States during January and August 2006 are evaluated to assess the model response to each scientific improvement, providing explanations of differences in results between v4.7 and previously released CMAQ model versions. Particulate sulfate predictions are improved across all monitoring networks during both seasons due to cloud module updates. Numerous updates to the SOA module improve the simulation of seasonal variability and decrease the bias in organic carbon predictions at urban sites in the winter. Bias in the total mass of fine particulate matter (PM 2.5 ) is dominated by overpredictions of unspeciated PM 2.5 (PM other ) in the winter and by underpredictions of carbon in the summer. The CMAQv4.7 model results show slightly worse performance for ozone predictions.Correspondence to: K. M. Foley (foley.kristen@epa.gov) However, changes to the meteorological inputs are found to have a much greater impact on ozone predictions compared to changes to the CMAQ modules described here. Model updates had little effect on existing biases in wet deposition predictions.

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Estimated Effects of Temperature on Secondary Organic Aerosol Concentrations

Cited by 180 publications

References 25 publications

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China

Effect of climate change on air quality

Incremental testing of the Community Multiscale Air Quality (CMAQ) modeling system version 4.7

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Estimated Effects of Temperature on Secondary Organic Aerosol Concentrations

Cited by 180 publications

References 25 publications

Characterization of Carbonaceous Species of Ambient PM2.5 in Beijing, China

Characterization of Carbonaceous Species of Ambient PM2.5 in Beijing, China

Effect of climate change on air quality

Incremental testing of the Community Multiscale Air Quality (CMAQ) modeling system version 4.7

Contact Info

Product

Resources

About

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China

Characterization of Carbonaceous Species of Ambient PM_2.5 in Beijing, China