Thanks to visit codestin.com
Credit goes to b.tellusjournals.se

Skip to main content
  • Home
  • About
    • Submissions
    • Content
      • Research Integrity
      • Home
      • About
        • About The Journal
        • Editorial Team
        • Editorial Policies
        • Contact
      • Submissions
      • Content
        • Articles
        • Issue Archive
        • Collections
      • Research Integrity
      • Account
      Journal Name Logo

      Tellus B: Chemical and Physical Meteorology

      Become a Reviewer
      Press Logo
      Reading: Assessing the relative contributions of transport efficiency and scavenging to seasonal variability in Arctic aerosol
      • PDF (US English)XML (US English)

      Assessing the relative contributions of transport efficiency and scavenging to seasonal variability in Arctic aerosol

      Original Research Papers

      Authors
      • Timothy J. Garrett
      • Chuanfeng Zhao
      • Paul C. Novelli

      Abstract

      Regional aerosol concentrations are governed by an evolving balance between aerosol sources and sinks. Here, a simple technique is described for making estimates of the extent to which seasonal aerosol variability is controlled by wet scavenging rather than the efficiency of transport from pollution source regions. Carbon monoxide (CO) is employed as an assumed passive tracer of pollution transport efficiency, to which the magnitude of aerosol light scattering is compared. Because aerosols, unlike CO, are affected by wet scavenging as well as transport efficiency, the ratio of short-term perturbations in these two quantities provides a measure of the relative roles of these two processes. This technique is applied to surface measurements in the Arctic at Barrow, Alaska (71◦N) for the decade between 2000 and 2009. What is found is that a well-known seasonal cycle in ‘Arctic Haze’ is dominated by variability in wet scavenging. Crossing the freezing threshold for warm rain production appears particularly critical for efficiently cleaning the air.

      Year: 2010
      Volume: 62 Issue: 3
      Page/Article: 190-196
      DOI: 10.1111/j.1600-0889.2010.00453.x
      Submitted on Sep 1, 2009
      Accepted on Mar 6, 2010
      Published on Jan 1, 2010
      Peer Reviewed
      CC BY 4.0

      References

      • Anderson , T. L. and Ogren , J. A . 1998 . Determining aerosol radiative properties using the TSI 3563 integrating nephelometer . Aerosol Sci. TechnoL 29 , 57 – 69 .  

      • Avey , L. , Garrett , T. J. and Stohl , A . 2007. Evaluation of the aerosol indirect effect using satellite, tracer transport model and aircraft data from ICARTT. J. Geophys. Res . 112. https://doi.org/10.1029/2006JDO07581 .  

      • Crutzen , P. J. and Lawrence , M. G . 2000 . The impact of precipitation scavenging on the transport of trace gases: a 3-dimensional model sensitivity study . J. Atmos. Chem . 37 , 81 – 112 .  

      • Curry , J. A. , Rossow , W. B. , Randall , D. and Schramm , J. L . 1996 . Overview of Arctic cloud and radiation characteristics . J. Climate 9 , 1731 – 1764 .  

      • Davidson , C. I. , Honrath , R. E. , Kadane , J. B. , Tsay , R. S. , Mayewski , P. A. and co-authors. 1987. The scavenging of atmospheric sulfate by arctic snow. Atmos. Environ. 21 , 871 – 882. https://doi.org/10.1016/0004-6981(87)90083-7 .  

      • Delene , D. J. and Ogren , J. A . 2002 . Variability of aerosol optical prop-erties at four North American surface monitoring sites . J. Atmos. Sci . 59 , 1135 – 1150 . https://doi.org/10.1175/1520-0469(2002)059 .  

      • Duncan , B. N. , Logan , J. A. , Bey , I. , Megretskaia , I. A. , Yantosca , R. M. and co-authors. 2007. Global budget of CO, 1988-1997: source estimates and validation with a global model. J. Geophys. Res . 112 , D22301. https://doi.org/10.1029/2007JD008459 .  

      • Dusek , U. , Frank , G. R , Hildebrandt , L. , Curtius , J. , Schneidr , J. and co-authors. 2006. Size matters more than chemistry for cloud-nucleating ability of aerosol particles. Science 312 , 1375 – 1378. https://doi.org/10.1126/science.1125261 .  

      • Garrett , T. J. , Avey , L. , Palmer , P. I. , Stohl , A. , Neuman , J. A. and co-authors. 2006. Quantifying wet scavenging processes in aircraft observations of nitric acid and cloud condensation nuclei. J. Geophys. Res . 111 , D23551, https://doi.org/10.1029/2006JD007416 .  

      • Garrett , T. J. , Radke , L. E and Hobbs , P. V . 2002 . Aerosol effects on the cloud emissivity and surface longwave heating in the Arctic. J. Atmos. Sc i . 59 , 769 – 778 .  

      • Garrett , T. J. and Verzella , L. L . 2007 . An evolving history of Arctic aerosols . Bull. Am. Meteor Soc . 89 , 299 – 302 .  

      • Garrett , T. J. and Zhao , C . 2006 . Increased Arctic cloud longwave emissivity associated with pollution from mid-latitudes . Nature 440 , 787 – 789 . https://doi.org/10.1038/nature04636 .  

      • Garrett , T. J. , Zhao , C. , Dong , X. , Mace , G. G. and Hobbs , P. V . 2004 . Ef-fects of varying aerosol regimes on low-level Arctic stratus . Geophys. Res. Lett . 31 , 17105 – 17109 .  

      • Hansen , J. and Nazarenko , L . 2004 . Soot climate forcing via snow and ice albedos . Proc. Natl. Acad. Sci. U.S.A . 101 , 423 – 428 . https://doi.org/10.1073/pnas.2237157100 .  

      • Heintzenberg , J. and Larssen , S . 1983 . SO2 and SO i- in the arctic-interpretation of observations at three Norwegian arctic-subarctic sta-tions . Tellus B 35 , 255 – 265 .  

      • Herbert , G. A. , Green , E. R. , Harris , J. M. , L., K. G. , Roughton , S. J. and co-authors. 1986. Control and monitoring instrumentation for the continuous measurement for atmospheric CO2 and meteorological variables. J. Atmos. Ocean. TechnoL 3, 414 – 421.  

      • Law , K. S. and Stohl , A . 2007 . Arctic air pollution: origins and impacts . Science 315 , 1537 – 1540 . https://doi.org/10.1126/science.1137695 .  

      • Leaitch , W. R. , Hoff , R. and Macpherson , J . 1989 . Airborne and lidar measurments of aerosol and cloud particles in the troposphere over Alert, Canada in April, 1986 . J. Atmos. Chem . 9 , 187 – 212 .  

      • Longley , I. D. , Inglis , D. W. G. , Gallagher , M. W. , Williams , P. I. , Allan , J. D. and co-authors. 2005. Using NO, and CO monitoring data to indicate fine aerosol number concentrations and emission factors in three UK conurbations. Atmos. Environ. 39 , 5157 – 5169. https://doi.org/10.1016/j.atmosenv.2005.05.017 .  

      • Lubin , D. and Vogelmann , A. M . 2006 . A climatologically significant aerosol longwave indirect effect in the Arctic . Nature 439 , 453 – 456 . https://doi.org/10.1038/nature04449 .  

      • McConnell , J. R. , Edwards , R. , Kok , G. L. , Flanner , M. G. , Zender , C. S. and co-authors. 2007. 20th-century industrial black carbon emissions altered Arctic climate forcing. Science 317 , 1381 – 1384. https://doi.org/10.1126/science.1144856 .  

      • Menon , S. , Unger , N. , Koch , D. , Francis , J. , Garrett , T. and co-authors. 2008. Aerosol climate effects and air quality impacts from 1980 to 2030. Environ. Res. Lett. 3, 024004. https://doi.org/10.1088/1748-9326/3/2/024004 .  

      • Novelli , P. C. , Masarie , K. A. , Lang , P. M. , Hall , B. D. , Myers , R. C. and co-authors. 2003. Reanalysis of tropospheric CO trends: effects of the 1997-1998 wildfires. J. Geophys. Res . 108 , D4464. https://doi.org/10.1029/2002JD003031 .  

      • Novelli , P. C. , Steele , P. and Tans , P. P. 1992. Mixing ratios of carbon monoxide in the troposphere. J. Geophys. Res . 97 ( D18 ), 20731 – 20750.  

      • Polissar , A. V. , Hopke , P. K. , Paatero , R , Kaufmann , Y. J. , Hall , D. J. and co-authors. 1999. The aerosol at Barrow, Alaska: long-term trends and source locations. Atmos. Environ. 33, 2441 – 2458.  

      • Quinn , P. K. , Bates , T. S. , Baum , E. , Doubleday , N. , Fiore , A. M. and co-authors. 2008. Short-lived pollutants in the arctic: their climate impact and possible mitigation strategies . Atmos. Chem. Phys . 8 , 1723– 1735 .  

      • Quinn , P. K. , Shaw , G. , Andrews , E. , Dutton , E. G. , Ruoho-Airola , T. and co-authors. 2007. Arctic haze: current trends and knowledge gaps. Tellus 59 , 99 – 114. https://doi.org/10.1111/j.1600-0889.2006.00238.x .  

      • Raatz , W. E. and Shaw , G. E . 1984 . Long-range tropospheric transport of pollution aerosols into the Alaskan Arctic . J. Appl. Meteor 23 , 1052 – 1064 .  

      • Rahn , K. A. , Borys , R. D. and Shaw , G. E . 1977 . The Asian source of Arctic haze bands . Nature 268 , 713 – 715 .  

      • Rasch , P. J. , Feichter , J. , Law , K. , Mahowald , N. , Penner , J. and co-authors. 2000. A comparison of scavenging and deposition processes in global models: results from the WCRP Cambridge Workshop of 1995. Tellus B 52 , 1025 – 1056. https://doi.org/10.1034/j.1600-0889.2000.00980.x .  

      • Schwartz , S. E. and Freiberg , J. E . 1981 . Mass-transport limitation to the rate of reaction of gases in liquid droplets: application to oxidation of SO2 in aqueous solutions . Atmos. Environ . 7 , 1129 – 1144 .  

      • Seinfeld , J. H. and Pandis , S. N . 1998 . Atmospheric Chemistry and Physics . John Wiley and Sons , Inc ., New York .  

      • Shaw , G. E . 1982 . Evidence for a central Eurasian source area of Arctic haze in Alaska . Nature 299 , 815 – 818 .  

      • Shaw , G. E . 1995 . The Arctic haze phenomenon . Bull. Am. MeteoroL Soc . 76 , 2403 – 2413 .  

      • Shaw , G. E. , Stamnes , K. and Hu , Y. X . 1993 . Arctic haze: perturbation to the radiation field . Meteor. Atmos. Phys . 51 , 227 – 235 .  

      • Shindell , D . 2007. Local and remote contributions to Arctic warming. Geophys. Res. Lett. 34. https://doi.org/10.1029/2007GL030221 .  

      • Shindell , D. T. , Chin , M. , Dentener , F. , Doherty , R. M. , Faluvegi , G. and co-authors. 2008. A multi-model assessment of pollution transport to the Arctic. Atmos. Chem. Phys. 8, 5353 – 5372.  

      • Simpson , G . 1906 . Atmospheric electricity in high latitudes . Phil. Trans. Roy. Soc. Lond., A 205 , 61 – 97 .  

      • Slinn , W. G. N . 1977 . Some approximations for the wet and dry removal of particles and gases from the atmosphere . Water Air Soil Pollut . 7 , 513 – 543 .  

      • Stohl , A . 2006. Characteristics of atmospheric transport into the Arctic troposphere. J. Geophys. Res . 111. https://doi.org/10.1029/2005JDO06888.  

      • Vinogradova , A. A. 2000. Anthropogenic pollutants in the Russian Arc-tic atmosphere: sources and sinks in spring and summer. Atmos. Env-iron. 34 , 5151 – 5160.  

      • Warneke , C. and co-authors. 2010. An important contribution to spring-time Arctic aerosol from biomass burning in Russia. Geophys. Res. Lett. 37, L01801. https://doi.org/10.1029/2009GL041816 .  

      • Warren , S. G. and Wiscombe , W. J . 1980 . A model for the spectral albedo of snow. II: snow containing atmospheric aerosols . J. Atmos. Sci . 37 , 2734 – 2745 .  

      • Zhao , C. and Garrett , T. J . 2008 . Ground-based remote-sensing of pre-cipitation in the Arctic . J. Geophys. Res . 113 , D14204 .  

      1. Abstract
      2. References
      • E-ISSN: 1600-0889
      • Print ISSN: 0280-6509
      • Published by Stockholm University Press
      • Terms and Conditions
      • Privacy Policy
      • Accessibility
      Powered by Ubiquity
      v.2.4.2
        Codestin Search App