Fog event is possibly a source rather than a sink of atmospheric nitrate aerosols: Insights from isotopic measurements in Nanjing, China
暂无分享,去创建一个
[1] Yan-lin Zhang,et al. A diurnal story of Δ17O(NO3−\documentclass[12pt]{minimal} \usepackage{amsmath} \usepackage{wasysym} \usepackage{amsfonts} \usepackage{amssymb} \usepackage{amsbsy} \usepackage{mathrsfs} \usepackage{upgreek} \setlength{\oddsidemargin}{-69pt} \begin{document}$$\rm{NO}_{3}^{-}$$\end{document}) in urban , 2022, npj Climate and Atmospheric Science.
[2] Yuanhang Zhang,et al. Anthropogenic monoterpenes aggravating ozone pollution , 2022, National science review.
[3] Yan-lin Zhang,et al. Important Role of NO3 Radical to Nitrate Formation Aloft in Urban Beijing: Insights from Triple Oxygen Isotopes Measured at the Tower. , 2021, Environmental science & technology.
[4] Yan-lin Zhang,et al. Determination of 17O Anomaly in Atmospheric Aerosol Nitrate , 2021 .
[5] A. Ravishankara,et al. An unexpected large continental source of reactive bromine and chlorine with significant impact on wintertime air quality , 2020, National science review.
[6] J. Orlando,et al. Quantifying the nitrogen isotope effects during photochemical equilibrium between NO and NO2: implications for δ15N in tropospheric reactive nitrogen , 2020 .
[7] T. Gupta,et al. Scavenging efficiency of water soluble inorganic and organic aerosols by fog droplets in the Indo Gangetic Plain , 2020 .
[8] Xue‐Yan Liu,et al. Nitrogen Isotope Differences between Major Atmospheric NOy Species: Implications for Transformation and Deposition Processes , 2020 .
[9] Hua-bin Dong,et al. NO3 and N2O5 chemistry at a suburban site during the EXPLORE-YRD campaign in 2018 , 2020 .
[10] Yan-lin Zhang,et al. Introduction to the National Aerosol Chemical Composition Monitoring Network of China: Objectives, Current Status, and Outlook , 2019 .
[11] Yan-lin Zhang,et al. Isotopic constraints on the atmospheric sources and formation of nitrogenous species in clouds influenced by biomass burning , 2019, Atmospheric Chemistry and Physics.
[12] F. Cao,et al. Isotope-based source apportionment of nitrogen-containing aerosols: A case study in an industrial city in China , 2019, Atmospheric Environment.
[13] Leiming Zhang,et al. Increasing importance of nitrate formation for heavy aerosol pollution in two megacities in Sichuan Basin, southwest China. , 2019, Environmental pollution.
[14] P. Kasibhatla,et al. Global inorganic nitrate production mechanisms: comparison of a global model with nitrate isotope observations , 2019, Atmospheric Chemistry and Physics.
[15] Qiang Zhang,et al. Process analysis of PM2.5 pollution events in a coastal city of China using CMAQ. , 2019, Journal of environmental sciences.
[16] E. Elliott,et al. Isotopic advances in understanding reactive nitrogen deposition and atmospheric processing. , 2019, The Science of the total environment.
[17] P. Zieger,et al. Composition, isotopic fingerprint and source attribution of nitrate deposition from rain and fog at a Sub-Arctic Mountain site in Central Sweden (Mt Åreskutan) , 2019, Tellus B: Chemical and Physical Meteorology.
[18] Meng Li,et al. Trends in China's anthropogenic emissions since 2010 as the consequence of clean air actions , 2018, Atmospheric Chemistry and Physics.
[19] A. Hofzumahaus,et al. Experimental budgets of OH, HO2, and RO2 radicals and implications for ozone formation in the Pearl River Delta in China 2014 , 2018, Atmospheric Chemistry and Physics.
[20] M. Hallquist,et al. Efficient N2O5 uptake and NO3 oxidation in the outflow of urban Beijing , 2018, Atmospheric Chemistry and Physics.
[21] Ashutosh Kumar Singh,et al. Chemical composition and source-apportionment of sub-micron particles during wintertime over Northern India: New insights on influence of fog-processing. , 2018, Environmental pollution.
[22] S. Kimbrough,et al. NO to NO2 Conversion Rate Analysis and Implications for Dispersion Model Chemistry Methods using Las Vegas, Nevada Near-Road Field Measurements. , 2017, Atmospheric environment.
[23] M. Hallquist,et al. Characterization of organic nitrate constituents of secondary organic aerosol (SOA) from nitrate-radical-initiated oxidation of limonene using high-resolution chemical ionization mass spectrometry , 2017 .
[24] Atul Srivastava,et al. Winter fog experiment over the Indo-Gangetic plains of India , 2017 .
[25] T. Gupta,et al. Characterization of organic residues of size‐resolved fog droplets and their atmospheric implications , 2016 .
[26] Xiaoye Zhang,et al. Characterization of submicron aerosols and effect on visibility during a severe haze-fog episode in Yangtze River Delta, China , 2015 .
[27] M. Canagaratna,et al. Real‐time measurements of ambient aerosols in a polluted Indian city: Sources, characteristics, and processing of organic aerosols during foggy and nonfoggy periods , 2015 .
[28] J. Schneider,et al. Cloud water composition during HCCT-2010: Scavenging efficiencies, solute concentrations, and droplet size dependence of inorganic ions and dissolved organic carbon , 2015 .
[29] G. Michalski,et al. Theoretical calculation of nitrogen isotope equilibrium exchange fractionation factors for various NOy molecules , 2015 .
[30] J. Collett,et al. Trace metal characterization of aerosol particles and cloud water during HCCT 2010 , 2015 .
[31] M. Facchini,et al. Fog occurrence and chemical composition in the Po valley over the last twenty years , 2014 .
[32] M. Facchini,et al. Fog scavenging of organic and inorganic aerosol in the Po Valley , 2014 .
[33] J. Savarino,et al. Quantitative constraints on the 17O-excess (Δ17O) signature of surface ozone: Ambient measurements from 50°N to 50°S using the nitrite-coated filter technique , 2014 .
[34] Qifan Liu,et al. Characterization of submicron aerosols during a month of serious pollution in Beijing, 2013 , 2014 .
[35] J. Collett,et al. A review of observations of organic matter in fogs and clouds: Origin, processing and fate , 2013 .
[36] P. Herckes,et al. Dissolved organic carbon (DOC) and select aldehydes in cloud and fog water: the role of the aqueous phase in impacting trace gas budgets , 2012 .
[37] P. Herckes,et al. Processing of atmospheric polycyclic aromatic hydrocarbons by fog in an urban environment. , 2012, Journal of environmental monitoring : JEM.
[38] J. Savarino,et al. Measurement of the 17O-excess (Δ17O) of tropospheric ozone using a nitrite-coated filter. , 2012, Rapid communications in mass spectrometry : RCM.
[39] B. Turpin,et al. Secondary organic aerosol formation in cloud droplets and aqueous particles (aqSOA): a review of laboratory, field and model studies , 2011 .
[40] S. Tripathi,et al. Secondary organic aerosol: a comparison between foggy and nonfoggy days. , 2011, Environmental science & technology.
[41] P. Shepson,et al. Analysis of atmospheric inputs of nitrate to a temperate forest ecosystem from Δ17O isotope ratio measurements , 2011 .
[42] Gang Tian,et al. [Mass size distributions and existing forms of sulfate and nitrate and atmospheric environment in Beijing]. , 2011, Huan jing ke xue= Huanjing kexue.
[43] A. Ding,et al. Influence of regional pollution and sandstorms on the chemical composition of cloud/fog at the summit of Mt. Taishan in northern China , 2011 .
[44] G. Jia,et al. Monthly variations in nitrogen isotopes of ammonium and nitrate in wet deposition at Guangzhou, south China , 2010 .
[45] D. Allman,et al. Quantifying atmospheric nitrate formation pathways based on a global model of the oxygen isotopic composition (Δ 17 O) of atmospheric nitrate , 2009 .
[46] P. Fabian,et al. Sahara dust, ocean spray, volcanoes, biomass burning: pathways of nutrients into Andean rainforests , 2009 .
[47] M. Frey,et al. Tracing the Origin and Fate of NOx in the Arctic Atmosphere Using Stable Isotopes in Nitrate , 2008, Science.
[48] Jing Chen,et al. Fog chemistry in the Texas–Louisiana Gulf Coast corridor , 2008, Atmospheric Environment.
[49] J. Collett,et al. Air Pollution Processing by Radiation Fogs , 2007 .
[50] J. Collett,et al. Processing of atmospheric organic matter by California radiation fogs , 2005 .
[51] Gilles Mailhot,et al. Transition metals in atmospheric liquid phases: sources, reactivity, and sensitive parameters. , 2005, Chemical reviews.
[52] Y. Yung,et al. Extraordinary isotopic fractionation in ozone photolysis , 2005 .
[53] J. C. Cabada,et al. Mass size distributions and size resolved chemical composition of fine particulate matter at the Pittsburgh supersite , 2004 .
[54] M. Fenn,et al. Tracing atmospheric nitrate deposition in a complex semiarid ecosystem using delta17O. , 2004, Environmental science & technology.
[55] R. Prinn. The Cleansing Capacity of the Atmosphere , 2003 .
[56] J. Collett,et al. Organic matter in central California radiation fogs. , 2002, Environmental science & technology.
[57] Y. Gao,et al. Strange and Unconventional Isotope Effects in Ozone Formation , 2001, Science.
[58] M. Facchini,et al. Partitioning of the organic aerosol component between fog droplets and interstitial air , 1998 .
[59] J. Collett,et al. On the Caltech Active Strand Cloudwater Collectors , 1996 .
[60] M. Facchini,et al. Phase partitioning for different aerosol species in fog , 1992 .
[61] R. Charlson,et al. Measurements of the size‐dependence of solute concentrations in cloud droplets , 1989 .
[62] C Seigneur,et al. Computer Simulations of the Atmospheric Chemistry of Sulfate and Nitrate Formation , 1984, Science.
[63] D. Jacob,et al. A dynamic model for the production of H+ NO3 −, and SO4 2− in urban fog , 1983 .
[64] Liu Zihua. Chemical features and cause analysis of a strong acid fog event in Nanjing , 2013 .
[65] Liu Zihua,et al. Differences in Ion Compositions of Winter Fogwater between Radiation and Advection-Radiation Fog Episodes in Nanjing , 2009 .
[66] Li Zi-hua. The chemical composition of fog water in the winter of 2006 of Nanjing. , 2008 .
[67] H. Moore. The isotopic composition of ammonia, nitrogen dioxide and nitrate in the atmosphere , 1977 .