Meteorological detrending of primary and secondary pollutant concentrations: Method application and evaluation using long-term (2000–2012) data in Atlanta

Henneman, Lucas; Holmes, Heather A.; Mulholland, James A.; Russell, Armistead G.

doi:10.1016/j.atmosenv.2015.08.007

Cited by 61 publications

(33 citation statements)

References 19 publications

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“…From 2005 to 2014, S4 showed a decreasing trend, which may be attributed to long-term reductions in regional SO 2 emissions due to rules such as the Clean Air Nonroad Diesel Rule and the Acid Rain Program for utilities. Similar long-term decreasing trends of atmospheric sulfate in the U.S. have been reported in other studies and have been linked to the implementation of a number of regulations and associated controls on sulfur emissions in the U.S. (Hubbell et al, 2009;Henneman et al, 2015).…”

Section: S4: Sulfate/industrial (30% Of Pm25)supporting

confidence: 77%

Estimate Contribution of Prescribed Rangeland Burning in Kansas to Ambient PM2.5 through Source Apportionment with Unmix Receptor Model

Liu

Maghirang

et al. 2016

2016 ASABE International Meeting

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The Unmix receptor model was applied to the 2002-2014 speciated PM 2.5 data from the IMPROVE site at Tallgrass National Preserve near Strong City, Kansas, to investigate the contributions of prescribed rangeland burning on local air quality. This investigation found the following five source categories that contribute to annual local ambient PM 2.5 : nitrate/agricultural (22%), vegetative burning (5%), secondary organic aerosol (29%), sulfate/industrial (30%), and crustal/soil (14%). In the month of April, the contributions of vegetative burning and secondary organic aerosol increased to 11% and 49%, respectively, indicating the influence of the prescribed burning season. The contribution of smoke from prescribed burning was estimated to be 1.05 g m-3 as primary aerosols and 4.03 g m-3 as secondary aerosols, which in total accounted for 42% of the average PM 2.5 concentration in April.

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Section: S4: Sulfate/industrial (30% Of Pm25)supporting

confidence: 77%

Estimate Contribution of Prescribed Rangeland Burning in Kansas to Ambient PM2.5 through Source Apportionment with Unmix Receptor Model

Liu

Maghirang

et al. 2016

2016 ASABE International Meeting

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“…Meanwhile, part of Henneman, Shen, et al (2017) examined observed OPEs (ΔO 3 /ΔNO z ) in the southeast United States from 1996 to 2015 using data from the same SEARCH sites as Blanchard and Hidy (2018). At each SEARCH site, the authors applied a long-term meteorological detrending of observed [O 3 ] concentrations to approximate the upper 20th percentile for photochemical state or PS*, a parameter that the authors claim (1) describes daily photochemical activity and (2) is independent of emissions (Henneman et al, 2015;Henneman, Chang, et al, 2017;Henneman, Shen, et al, 2017). Then, Henneman, Shen, et al (2017) estimated observed OPEs over the 20-year period using daily 14:00-15:00 local time averages of NO x , NO y , and O 3 for days corresponding to the upper 20th percentile for PS*.…”

Section: Introductionmentioning

confidence: 99%

Ozone Production Efficiencies at Rural New York State Locations: Relationship to Oxides of Nitrogen Concentrations

2019

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This study examined the observed summertime ozone production efficiency (OPE) and background ozone ([O3]) concentration at two rural sites in New York State, Pinnacle State Park (PSP) in Addison, NY, and Whiteface Mountain Summit (WFMS) in Wilmington, NY. Observed summertime OPEs and their relationship to oxides of nitrogen concentrations ([NOx]) were assessed during photochemically active periods at PSP and WFMS from 2000 to 2017 and 2015–2017, respectively. The summertime OPE increased in response to [NOx] reductions at PSP, consistent with a NOx‐sensitive regime for O3 production. At PSP, the summertime OPE increased from approximately 5–7 parts per billion per parts per billion (ppb ppb−1) in 2000–2009 to approximately 13 ppb ppb−1 in 2012–2017, and the median [NOx] concentration during photochemically productive periods decreased from about 0.60 ppb in 2000–2005 to about 0.23 ppb in 2012–2017. At WFMS, the summertime OPE was approximately 18 ppb ppb−1 in 2015–2017, and the median [NOx] concentration during photochemically active periods from 2015 to 2017 was about 0.21 ppb. The higher WFMS summertime OPE is consistent for a site characterized by lower [NOx] concentrations. The summertime background [O3] concentration at PSP and WFMS was approximately 31–33 ppb for the analysis period, indicating that both sites were likely affected by similar regional emission sources.

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“…Statistical analysis of ambient air quality data is another commonly used method to decouple the meteorological effects on air quality (Henneman et al, 2017;Liang et al, 2015), including Kolmogorov-Zurbenko (KZ) filter model and deep neural network (Wise and Comrie, 2005;Comrie, 1997;Eskridge et al, 1997;Hogrefe et al, 2003;Gardner and Dorling, 2001). But they usually gave a poor fitting, suggesting a poor performance of the KZ filter model, or did not allow us to investigate the effect of input variables in neural network models (therefore it is referred as a "black-box" model) (Gardner and Dorling, 2001;Henneman et al, 2015). More recently, new approaches based on classification trees are being developed, which are suitable for air quality weather detrending, including the boosted regression trees (BRT) and random forest (RF) algorithms (Carslaw and Taylor, 2009;Grange et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Assessing the impact of Clean Air Action Plan on Air Quality Trends in Beijing Megacity using a machine learning technique

Shi

Cheng

et al. 2019

Preprint

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Abstract. A five-year Clean Air Action Plan was implemented in 2013 to reduce air pollutant emissions and improve ambient air quality in Beijing. Assessments of this Action Plan is an essential part of the decision-making process to review the efficacy of the Plan and to develop new policies. Both statistical and chemical transport modelling were applied to assess the efficacy of this Action Plan. However, inherent uncertainties in these methods mean that new and independent methods are required to support the assessment process. Here, we improved a novel machine learning-based random forest technique to quantify the effectiveness of Beijing's Acton Plan by decoupling the impact of meteorology on ambient air quality. Our results demonstrate that meteorological conditions have an important impact on the year to year variations in ambient air quality. Further analysis show that the favorable meteorological conditions in winter 2017 contributed to a lower PM2.5 mass concentration (58&#8201;&#956;g&#8201;m&#8722;3) than predicted from the random forest model (61&#8201;&#956;g&#8201;m&#8722;3), which is higher than the target of the Plan (2017 annual PM2.5&#8201;<&#8201;60&#8201;&#956;g&#8201;m&#8722;3). However, over the whole period (2013 to 2017), impact of meteorological conditions on the trend of ambient air quality are small. It is the primary emission control, because of the Action Plan, that has led to the significant reduction in PM2.5, PM10, NO2, SO2 and CO from 2013 to 2017, which are approximately 34&#8201;%, 24&#8201;%, 17&#8201;%, 68&#8201;%, and 33&#8201;% after meteorological correction. The marked decrease in PM2.5 and SO2 is largely attributable to a reduction in coal combustion. Our results indicate that the Action Plan is highly effective in reducing the primary pollution emissions and improving air quality in Beijing. The Action Plan offers a successful example for developing air quality policies in other regions of China and other developing countries.

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Meteorological detrending of primary and secondary pollutant concentrations: Method application and evaluation using long-term (2000–2012) data in Atlanta

Cited by 61 publications

References 19 publications

Estimate Contribution of Prescribed Rangeland Burning in Kansas to Ambient PM2.5 through Source Apportionment with Unmix Receptor Model

Estimate Contribution of Prescribed Rangeland Burning in Kansas to Ambient PM2.5 through Source Apportionment with Unmix Receptor Model

Ozone Production Efficiencies at Rural New York State Locations: Relationship to Oxides of Nitrogen Concentrations

Assessing the impact of Clean Air Action Plan on Air Quality Trends in Beijing Megacity using a machine learning technique

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