Control of particulate nitrate air pollution in China
暂无分享,去创建一个
D. Jacob | Yuzhong Zhang | T. Zhao | Qiang Zhang | K. Gui | Yuesi Wang | Yele Sun | F. Yu | G. Luo | Litao Wang | V. Shah | Lu Shen | K. Bates | Xuan Wang | H. Liao | Zirui Liu | Hong-hui Xu | T. Wen | Ke Li | Hyoungwoo Choi | J. Tao | Hyun Chul Lee | J. Moch | M. Qi | Shaojie Song | S. Zhai | Viral Shah
[1] H. Bai,et al. Assessment of health benefit of PM2.5 reduction during COVID-19 lockdown in China and separating contributions from anthropogenic emissions and meteorology , 2021, Journal of Environmental Sciences.
[2] Shuxiao Wang,et al. Sources of gaseous NH3 in urban Beijing from parallel sampling of NH3 and NH4+, their nitrogen isotope measurement and modeling. , 2020, The Science of the total environment.
[3] Shuxiao Wang,et al. Wintertime Particulate Matter Decrease Buffered by Unfavorable Chemical Processes Despite Emissions Reductions in China , 2020, Geophysical Research Letters.
[4] F. Yu,et al. Further improvement of wet process treatments in GEOS-Chem v12.6.0: impact on global distributions of aerosols and aerosol precursors , 2020 .
[5] A. Russell,et al. Aerosol acidity and liquid water content regulate the dry deposition of inorganic reactive nitrogen , 2020, Atmospheric Chemistry and Physics.
[6] K. Yung,et al. China’s emission control strategies have suppressed unfavorable influences of climate on wintertime PM2.5 concentrations in Beijing since 2002 , 2020 .
[7] Bin Zhao,et al. Persistent heavy winter nitrate pollution driven by increased photochemical oxidants in northern China. , 2020, Environmental science & technology.
[8] G. Carmichael,et al. China's emission control strategies have suppressed unfavorable influences of climate on wintertime PM2.5 concentrations in Beijing since 2002 , 2020 .
[9] D. Worsnop,et al. Response of aerosol chemistry to clean air action in Beijing, China: Insights from two-year ACSM measurements and model simulations. , 2019, Environmental pollution.
[10] Jiming Hao,et al. Drivers of improved PM2.5 air quality in China from 2013 to 2017 , 2019, Proceedings of the National Academy of Sciences.
[11] Yuzhong Zhang,et al. Thermodynamic Modeling Suggests Declines in Water Uptake and Acidity of Inorganic Aerosols in Beijing Winter Haze Events during 2014/2015–2018/2019 , 2019, Environmental Science & Technology Letters.
[12] D. Jacob,et al. A two-pollutant strategy for improving ozone and particulate air quality in China , 2019, Nature Geoscience.
[13] Shuxiao Wang,et al. Nitrate dominates the chemical composition of PM2.5 during haze event in Beijing, China. , 2019, The Science of the total environment.
[14] C. O'Dowd,et al. Summertime and wintertime atmospheric processes of secondary aerosol in Beijing , 2019, Atmospheric Chemistry and Physics.
[15] A. Ding,et al. Significant reduction of PM2.5 in eastern China due to regional-scale emission control: evidence from SORPES in 2011–2018 , 2019, Atmospheric Chemistry and Physics.
[16] Lu Shen,et al. Fine particulate matter (PM2.5) trends in China, 2013–2018: separating contributions from anthropogenic emissions and meteorology , 2019, Atmospheric Chemistry and Physics.
[17] H. Liao,et al. Severe winter haze days in the Beijing–Tianjin–Hebei region from 1985 to 2017 and the roles of anthropogenic emissions and meteorology , 2019, Atmospheric Chemistry and Physics.
[18] Ke Li,et al. Effect of changing NOx lifetime on the seasonality and long-term trends of satellite-observed tropospheric NO2 columns over China , 2019, Atmospheric Chemistry and Physics.
[19] A. Hofzumahaus,et al. Fast photochemistry in wintertime haze: Consequences for pollution mitigation strategies. , 2019, Environmental science & technology.
[20] Q. Xiao,et al. Impact of China’s Air Pollution Prevention and Control Action Plan on PM2.5 chemical composition over eastern China , 2019, Science China Earth Sciences.
[21] F. Yu,et al. Revised treatment of wet scavenging processes dramatically improves GEOS-Chem 12.0.0 simulations of surface nitric acid, nitrate, and ammonium over the United States , 2019, Geoscientific Model Development.
[22] Jing-chun Duan,et al. Changes of chemical composition and source apportionment of PM2.5 during 2013–2017 in urban Handan, China , 2019, Atmospheric Environment.
[23] Qiang Zhang,et al. Rapid transition in winter aerosol composition in Beijing from 2014 to 2017: response to clean air actions , 2019, Atmospheric Chemistry and Physics.
[24] Qiang Zhang,et al. Dominant role of emission reduction in PM2.5 air quality improvement in Beijing during 2013–2017: a model-based decomposition analysis , 2019, Atmospheric Chemistry and Physics.
[25] Xuejun Liu,et al. A database of atmospheric nitrogen concentration and deposition from the nationwide monitoring network in China , 2019, Scientific Data.
[26] R. Martin,et al. Heterogeneous sulfate aerosol formation mechanisms during wintertime Chinese haze events: air quality model assessment using observations of sulfate oxygen isotopes in Beijing , 2019, Atmospheric Chemistry and Physics.
[27] Shuxiao Wang,et al. High efficiency of livestock ammonia emission controls in alleviating particulate nitrate during a severe winter haze episode in northern China , 2019, Atmospheric Chemistry and Physics.
[28] Yuesi Wang,et al. Characteristics of chemical composition and seasonal variations of PM2.5 in Shijiazhuang, China: Impact of primary emissions and secondary formation. , 2019, The Science of the total environment.
[29] anonymous. Ji et al., Impact of air pollution control measures and regional transport on carbonaceous aerosols in fine particulate matter in urban Beijing, China: Insights gained from long-term measurement , 2019 .
[30] Tong Zhu,et al. Ammonia emission control in China would mitigate haze pollution and nitrogen deposition, but worsen acid rain , 2019, Proceedings of the National Academy of Sciences.
[31] Qiang Zhang,et al. Exploring 2016–2017 surface ozone pollution over China: source contributions and meteorological influences , 2019, Atmospheric Chemistry and Physics.
[32] F. Yu,et al. Revised treatment of wet scavenging processes dramatically improves GEOS-Chem 12.0.0 simulations of nitric acid, nitrate, and ammonium over the United States , 2019 .
[33] Yuesi Wang,et al. Impact of air pollution control measures and regional transport on carbonaceous aerosols in fine particulate matter in urban Beijing, China: insights gained from long-term measurement , 2019, Atmospheric Chemistry and Physics.
[34] D. Worsnop,et al. Changes in Aerosol Chemistry From 2014 to 2016 in Winter in Beijing: Insights From High‐Resolution Aerosol Mass Spectrometry , 2019, Journal of Geophysical Research: Atmospheres.
[35] Xuejun Liu,et al. Rapid SO2 emission reductions significantly increase tropospheric ammonia concentrations over the North China Plain , 2018, Atmospheric Chemistry and Physics.
[36] Andrew R. Whitehill,et al. An Odd Oxygen Framework for Wintertime Ammonium Nitrate Aerosol Pollution in Urban Areas: NOx and VOC Control as Mitigation Strategies , 2019, Geophysical Research Letters.
[37] C. Clerbaux,et al. The unintended consequence of SO2 and NO2 regulations over China: increase of ammonia levels and impact on PM2.5 concentrations , 2018, Atmospheric Chemistry and Physics.
[38] D. A. Day,et al. Nitrogen Oxides Emissions, Chemistry, Deposition, and Export Over the Northeast United States During the WINTER Aircraft Campaign , 2018, Journal of Geophysical Research: Atmospheres.
[39] Meng Li,et al. Trends in China's anthropogenic emissions since 2010 as the consequence of clean air actions , 2018, Atmospheric Chemistry and Physics.
[40] Yong Wang,et al. Characterizing remarkable changes of severe haze events and chemical compositions in multi-size airborne particles (PM1, PM2.5 and PM10) from January 2013 to 2016–2017 winter in Beijing, China , 2018, Atmospheric Environment.
[41] A. Hofzumahaus,et al. Wintertime photochemistry in Beijing: observations of ROx radical concentrations in the North China Plain during the BEST-ONE campaign , 2018, Atmospheric Chemistry and Physics.
[42] R. Otjes,et al. Effectiveness of ammonia reduction on control of fine particle nitrate , 2018, Atmospheric Chemistry and Physics.
[43] K. Sun,et al. Fast particulate nitrate formation via N2O5 uptake aloft in winter in Beijing , 2018, Atmospheric Chemistry and Physics.
[44] Bo Hu,et al. Characteristics of PM2.5 mass concentrations and chemical species in urban and background areas of China: emerging results from the CARE-China network , 2018, Atmospheric Chemistry and Physics.
[45] Qiang Zhang,et al. Nitrate-driven urban haze pollution during summertime over the North China Plain , 2018 .
[46] J. Randerson,et al. Global fire emissions estimates during 1997–2016 , 2017 .
[47] Jun Yu Li,et al. Assessment of carbonaceous aerosols in Shanghai, China - Part 1: long-term evolution, seasonal variations, and meteorological effects , 2017 .
[48] T. Zhu,et al. High N2O5 Concentrations Observed in Urban Beijing: Implications of a Large Nitrate Formation Pathway , 2017 .
[49] Qiang Zhang,et al. Chemical composition of ambient PM 2. 5 over China and relationship to precursor emissions during 2005–2012 , 2017 .
[50] Shuxiao Wang,et al. Increasing Ammonia Concentrations Reduce the Effectiveness of Particle Pollution Control Achieved via SO2 and NOX Emissions Reduction in East China , 2017 .
[51] M. Brauer,et al. Anthropogenic fugitive, combustion and industrial dust is a significant, underrepresented fine particulate matter source in global atmospheric models , 2017 .
[52] Tong Zhu,et al. Vehicle Emissions as an Important Urban Ammonia Source in the United States and China. , 2017, Environmental science & technology.
[53] G. Carmichael,et al. MIX: a mosaic Asian anthropogenic emission inventory under the international collaboration framework of the MICS-Asia and HTAP , 2017 .
[54] Fang Zhang,et al. Persistent sulfate formation from London Fog to Chinese haze , 2016, Proceedings of the National Academy of Sciences.
[55] D. Jacob,et al. Global impacts of tropospheric halogens (Cl, Br, I) on oxidants and composition in GEOS-Chem , 2016 .
[56] Qiang Zhang,et al. Fossil Fuel Combustion-Related Emissions Dominate Atmospheric Ammonia Sources during Severe Haze Episodes: Evidence from (15)N-Stable Isotope in Size-Resolved Aerosol Ammonium. , 2016, Environmental science & technology.
[57] Sean M. Davis,et al. A missing source of aerosols in Antarctica - beyond long-range transport, phytoplankton, and photochemistry , 2016 .
[58] Kan Huang,et al. The importance of vehicle emissions as a source of atmospheric ammonia in the megacity of Shanghai , 2015 .
[59] D. Jacob,et al. Sources, seasonality, and trends of southeast US aerosol: an integrated analysis of surface, aircraft, and satellite observations with the GEOS-Chem chemical transport model , 2015 .
[60] Tao Song,et al. The Campaign on Atmospheric Aerosol Research Network of China: CARE-China , 2015 .
[61] R. Martin,et al. Spatially and seasonally resolved estimate of the ratio of organic mass to organic carbon , 2014 .
[62] Qiaoqiao Wang,et al. Global budget and radiative forcing of black carbon aerosol: Constraints from pole‐to‐pole (HIPPO) observations across the Pacific , 2014 .
[63] L. Horowitz,et al. Ozone and organic nitrates over the eastern United States: Sensitivity to isoprene chemistry , 2013 .
[64] William J. Koshak,et al. Optimized regional and interannual variability of lightning in a global chemical transport model constrained by LIS/OTD satellite data , 2012 .
[65] R. C. Hudman,et al. Steps towards a mechanistic model of global soil nitric oxide emissions: implementation and space based-constraints , 2012 .
[66] Naresh Kumar,et al. Nitrogen Deposition to the United States: Distribution, Sources, and Processes , 2012 .
[67] Qiaoqiao Wang,et al. Sources of carbonaceous aerosols and deposited black carbon in the Arctic in winter-spring: implications for radiative forcing , 2011 .
[68] Elisabeth Galarneau,et al. Gas-particle partitioning of atmospheric Hg(II) and its effect on global mercury deposition , 2011 .
[69] Becky Alexander,et al. Global distribution of sea salt aerosols: new constraints from in situ and remote sensing observations , 2010 .
[70] John H. Seinfeld,et al. Effect of changes in climate and emissions on future sulfate-nitrate-ammonium aerosol levels in the United States: FUTURE INORGANIC AEROSOLS IN THE U.S. , 2009 .
[71] A. Nenes,et al. ISORROPIA II: a computationally efficient thermodynamic equilibrium model for K + –Ca 2+ –Mg 2+ –NH 4 + –Na + –SO 4 2− –NO 3 − –Cl − –H 2 O aerosols , 2007 .
[72] Daniel J. Jacob,et al. The impact of transpacific transport of mineral dust in the United States , 2007 .
[73] D. Jacob,et al. Constraints from 210Pb and 7Be on wet deposition and transport in a global three‐dimensional chemical tracer model driven by assimilated meteorological fields , 2001 .
[74] J. Seinfeld,et al. Analysis of aerosol ammonium nitrate: Departures from equilibrium during SCAQS , 1992 .
[75] PREVENTION AND CONTROL OF AIR POLLUTION , 2017 .
[76] Qiang Zhang,et al. Reply to Comment on "Fossil Fuel Combustion-Related Emissions Dominate Atmospheric Ammonia Sources during Severe Haze Episodes: Evidence from 15N-Stable Isotope in Size-Resolved Aerosol Ammonium". , 2016, Environmental science & technology.
[77] S. Solberg,et al. Atmospheric Chemistry and Physics , 2002 .
[78] M. Wesely. Parameterization of surface resistances to gaseous dry deposition in regional-scale numerical models , 1989 .