Improving simulations of sulfate aerosols during winter haze over Northern China: the impacts of heterogeneous oxidation by NO2 (original) (raw)

References

  1. Gao M, Guttikunda S K, Carmichael G R, Wang Y, Liu Z, Stanier C O, Saide P E, Yu M. Health impacts and economic losses assessment of the 2013 severe haze event in Beijing area. Science of the Total Environment, 2015, 511: 553–561
    Article CAS Google Scholar
  2. Gao M, Carmichael G R, Wang Y, Saide P E, Yu M, Xin J, Liu Z, Wang Z. Modeling study of the 2010 regional haze event in the North China Plain. Atmospheric Chemistry and Physics, 2016, 16(3): 1673–1691
    Article CAS Google Scholar
  3. Zheng B, Zhang Q, Zhang Y, He K B, Wang K, Zheng G J, Duan F K, Ma Y L, Kimoto T. Heterogeneous chemistry: a mechanism missing in current models to explain secondary inorganic aerosol formation during the January 2013 haze episode in North China. Atmospheric Chemistry and Physics, 2015, 15(4): 2031–2049
    Article CAS Google Scholar
  4. Wang L, Zhang Y, Wang K, Zheng B, Zhang Q, Wei W. Application of Weather Research and Forecasting Model with Chemistry (WRF/Chem) over northern China: sensitivity study, comparative evaluation, and policy implications. Atmospheric Environment, 2014
    Google Scholar
  5. Wang Y, Yao L, Wang L, Liu Z, Ji D, Tang G, Zhang J, Sun Y, Hu B, Xin J. Mechanism for the formation of the January 2013 heavy haze pollution episode over central and eastern China. Science China-Earth Sciences, 2014, 57(1): 14–25
    Article CAS Google Scholar
  6. Sun Y, Jiang Q, Wang Z, Fu P, Li J, Yang T, Yin Y. Investigation of the sources and evolution processes of severe haze pollution in Beijing in January 2013. Journal of Geophysical Research, D, Atmospheres, 2014, 119(7): 4380–4398
    Article Google Scholar
  7. Wang Y, Zhang Q, Jiang J, Zhou W, Wang B, He K, Duan F, Zhang Q, Philip S, Xie Y. Enhanced sulfate formation during China’s severe winter haze episode in January 2013 missing from current models. Journal of Geophysical Research: Atmospheres, 2014, 119(17): 425–440
    Google Scholar
  8. Zhang J K, Sun Y, Liu Z R, Ji D S, Hu B, Liu Q, Wang Y S. Characterization of submicron aerosols during a month of serious pollution in Beijing, 2013. Atmospheric Chemistry and Physics, 2014, 14(6): 2887–2903
    Article CAS Google Scholar
  9. Zheng G J, Duan F K, Su H, Ma Y L, Cheng Y, Zheng B, Zhang Q, Huang T, Kimoto T, Chang D, Pöschl U, Cheng Y F, He K B. Exploring the severe winter haze in Beijing: the impact of synoptic weather, regional transport and heterogeneous reactions. Atmospheric Chemistry and Physics, 2015, 15(6): 2969–2983
    Article CAS Google Scholar
  10. Zhang R, Li Q, Zhang R. Meteorological conditions for the persistent severe fog and haze event over eastern China in January 2013. Science China-Earth Sciences, 2014, 57(1): 26–35
    Article Google Scholar
  11. Quan J, Tie X, Zhang Q, Liu Q, Li X, Gao Y, Zhao D. Characteristics of heavy aerosol pollution during the 2012–2013 winter in Beijing, China. Atmospheric Environment, 2014, 88: 83–89
    Article CAS Google Scholar
  12. Tuccella P, Curci G, Visconti G, Bessagnet B, Menut L, Park R J. Modeling of gas and aerosol with WRF/Chem over Europe: evaluation and sensitivity study. Journal of Geophysical Research, 2012, 117(D3): D03303
    Article Google Scholar
  13. Seinfeld J H, Pandis S N. Atmospheric Chemistry and Physics: from Air Pollution to Climate Change. New York: John Wiley & Sons, 2012
    Google Scholar
  14. Pandis S N, Seinfeld H J. Mathematical modeling of acid deposition due to radiation fog. Journal of Geophysical Research, 1989, 94 (D10): 911–923
    Google Scholar
  15. Zhang L, Liu L, Zhao Y, Gong S, Zhang X, Henze D K, Capps S L, Fu T M, Zhang Q, Wang Y. Source attribution of particulate matter pollution over North China with the adjoint method. Environmental Research Letters, 2015, 10(8): 084011
    Article Google Scholar
  16. He H, Wang Y, Ma Q, Ma J, Chu B, Ji D, Tang G, Liu C, Zhang H, Hao J. Mineral dust and NOx promote the conversion of SO2 to sulfate in heavy pollution days. Scientific Reports, 2014, 4: 4172
    Google Scholar
  17. Sarwar G, Fahey K, Kwok R, Gilliam R C, Roselle S J, Mathur R, Xue J, Yu J, Carter W P L. Potential impacts of two SO2 oxidation pathways on regional sulfate concentrations: Aqueous-phase oxidation by NO2 and gas-phase oxidation by Stabilized Criegee Intermediates. Atmospheric Environment, 2013, 68: 186–197
    Article CAS Google Scholar
  18. Mlawer E J, Taubman S J, Brown P D, Iacono M J, Clough S A. Radiative transfer for inhomogeneous atmospheres: RRTM, a validated correlated-k model for the longwave. Journal of Geophysical Research, 1997, 102(D14): 16663–16682
    Article CAS Google Scholar
  19. Chou M D, Suarez M J, Ho C H, Yan M M H, Lee K T. Parameterizations for cloud overlapping and shortwave singlescattering properties for use in general circulation and cloud ensemble models. Journal of Climate, 1998, 11(2): 202–214
    Article Google Scholar
  20. Lin Y L, Farley R D, Orville H D. Bulk parameterization of the snow field in a cloud model. Journal of Climate and Applied Meteorology, 1983, 22(6): 1065–1092
    Article Google Scholar
  21. Grell G A. Prognostic evaluation of assumptions used by cumulus parameterizations. Monthly Weather Review, 1993, 121(3): 764–787
    Article Google Scholar
  22. Hong S Y, Noh Y, Dudhia J. A new vertical diffusion package withan explicit treatment of entrainment processes. Monthly Weather Review, 2006, 134(9): 2318–2341
    Article Google Scholar
  23. Zaveri R A, Easter R C, Fast J D, Peters L K. Model for Simulating Aerosol Interactions and Chemistry (MOSAIC). Journal of Geophysical Research, 2008, 113(D13): D13204
    Article Google Scholar
  24. Emmons L K, Walters S, Hess P G, Lamarque J F, Pfister G G, Fillmore D, Granier C, Guenther A, Kinnison D, Laepple T, Orlando J, Tie X, Tyndall G, Wiedinmyer C, Baughcum S L, Kloster S. Description and evaluation of the Model for Ozone and Related chemical Tracers, version 4 (MOZART-4). Geosci Model Dev, 2010, 3(1): 43–67
    Article Google Scholar
  25. Li M, Zhang Q, Kurokawa J, Woo J H, He K B, Lu Z, Ohara T, Song Y, Streets D G, Carmichael G R, Cheng Y F, Hong C P, Huo H, Jiang X J, Kang S C, Liu F, Su H, Zheng B. MIX: a mosaic Asian anthropogenic emission inventory for the MICS-Asia and the HTAP projects. Atmospheric Chemistry and Physics Discussion, 2015, 15(23): 34813–34869
    Article Google Scholar
  26. Guenther A, Karl T, Harley P, Wiedinmyer C, Palmer P I, Geron C. Estimates of global terrestrial isoprene emissions using MEGAN (Model of Emissions of Gases and Aerosols from Nature). Atmospheric Chemistry and Physics, 2006, 6(11): 107–173
    Article Google Scholar
  27. Misenis C, Zhang Y. An examination of sensitivity of WRF/Chem predictions to physical parameterizations, horizontal grid spacing, and nesting options. Atmospheric Research, 2010, 97(3): 315–334
    Article CAS Google Scholar
  28. Zhang Y, Wen X Y, Jang C J. Simulating chemistry–aerosol–cloud–radiation–climate feedbacks over the continental U.S. using the online-coupled Weather Research Forecasting Model with chemistry (WRF/Chem). Atmospheric Environment, 2010, 44(29): 3568–3582
    CAS Google Scholar
  29. Boylan J W, Russell A G. PM and light extinction model performance metrics, goals, and criteria for three-dimensional air quality models. Atmospheric Environment, 2006, 40(26): 4946–4959
    Article CAS Google Scholar
  30. Damian V, Sandu A, Damian M, Potra F, Carmichael G R. The kinetic preprocessor KPP-a software environment for solving chemical kinetics. Computers & Chemistry, 2002, 26(11): 1567–1579
    Article CAS Google Scholar
  31. Littlejohn D, Wang Y, Chang S G. Oxidation of aqueous sulfite ion by nitrogen dioxide. Environmental Science & Technology, 1993, 27(10): 2162–2167
    Article CAS Google Scholar
  32. Clifton C L, Altstein N, Huie R E. Rate constant for the reaction of nitrogen dioxide with sulfur(IV) over the pH range 5.3-13. Environmental Science & Technology, 1988, 22(5): 586–589
    Article CAS Google Scholar
  33. Lee Y, Schwartz S E. Kinetics of oxidation of aqueous sulfur(IV) by nitrogen dioxide. Precipiation Scavenging Dry Deposition and Resuspension, 1993
    Google Scholar
  34. Xue J, Yuan Z, Yu J Z, Lau A K H. An observation-based model for secondary inorganic aerosols. Aerosol and Air Quality Research, 2014, 14: 862–878
    CAS Google Scholar
  35. Bian Y X, Zhao C S, Ma N, Chen J, Xu W Y. A study of aerosol liquid water content based on hygroscopicity measurements at high relative humidity in the North China Plain. Atmospheric Chemistry and Physics, 2014, 14(12): 6417–6426
    Article CAS Google Scholar
  36. Khlystov A, Stanier C O, Takahama S, Pandis S N. Water content of ambient aerosol during the Pittsburgh air quality study. Journal of Geophysical Research, D, Atmospheres, 2005, 110(D7): 1–10
    Article Google Scholar
  37. Sander R. Compilation of Henry’s Law Constants for Inorganic and Organic Species of Potential Importance in Environmental Chemistry, Version 3, 1999
    Google Scholar
  38. Gao M, Carmichael G R, Saide P E, Lu Z, Yu M, Streets D G, Wang Z. Response of winter fine particulate matter concentrations to emission and meteorology changes in North China. Atmospheric Chemistry and Physics Discussion, 2016: 1–38
    Google Scholar

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