ACP Atmospheric Chemistry and Physics ACP 1680-7324 Copernicus GmbH Göttingen, Germany 10.5194/acp-10-5565-2010 Quantifying the clear-sky temperature inversion frequency and strength over the Arctic Ocean during summer and winter seasons from AIRS profiles Devasthale A. 1 Willén U. 2 Karlsson K.-G. 1 Jones C. G. 2 Remote Sensing Division, Swedish Meteorological and Hydrological Institute, Norrköping, Sweden Rossby Center, Swedish Meteorological and Hydrological Institute, Norrköping, Sweden 22 06 2010 10 12 5565 5572 This is an open-access article ditributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. This article is available from http://www.atmos-chem-phys.net/10/5565/2010/acp-10-5565-2010.html The full text article is available as a PDF file from http://www.atmos-chem-phys.net/10/5565/2010/acp-10-5565-2010.pdf

Temperature inversions are one of the dominant features of the Arctic atmosphere and play a crucial role in various processes by controlling the transfer of mass and moisture fluxes through the lower troposphere. It is therefore essential that they are accurately quantified, monitored and simulated as realistically as possible over the Arctic regions. In the present study, the characteristics of inversions in terms of frequency and strength are quantified for the entire Arctic Ocean for summer and winter seasons of 2003 to 2008 using the AIRS data for the clear-sky conditions. The probability density functions (PDFs) of the inversion strength are also presented for every summer and winter month. <br><br> Our analysis shows that although the inversion frequency along the coastal regions of Arctic decreases from June to August, inversions are still seen in almost each profile retrieved over the inner Arctic region. In winter, inversions are ubiquitous and are also present in every profile analysed over the inner Arctic region. When averaged over the entire study area (70° N–90° N), the inversion frequency in summer ranges from 69 to 86% for the ascending passes and 72–86% for the descending passes. For winter, the frequency values are 88–91% for the ascending passes and 89–92% for the descending passes of AIRS/AQUA. The PDFs of inversion strength for the summer months are narrow and right-skewed (or positively skewed), while in winter, they are much broader. In summer months, the mean values of inversion strength for the entire study area range from 2.5 to 3.9 K, while in winter, they range from 7.8 to 8.9 K. The standard deviation of the inversion strength is double in winter compared to summer. The inversions in the summer months of 2007 were very strong compared to other years. The warming in the troposphere of about 1.5–3.0 K vertically extending up to 400 hPa was observed in the summer months of 2007.

 References ACIA: Impacts of a~Warming Arctic: Arctic Climate Impact Assessment, Cambridge University Press, New York, 2004. Boé,~J., Hall,~A D., and Qu,~X.: Current GCMs' unrealistic negative feedback in the Arctic, J Climate, 22, 4682–4695, \doi10.1175/2009JCLI2885.1, 2009. Bradley,~R S., Keimig,~F T., and Diaz,~H F.: Climatology of surface based inversions in the North American Arctic, J Geophys. Res., 94, 15699–15712, 1992. Deser,~C. and Teng,~H.: Evolution of Arctic sea ice concentration trends and the role of atmospheric circulation forcing, 1979–2007, Geophys. Res. Lett., 35, L02504, \doi10.1029/2007GL032023, 2008. Divakarla,~M G., Barnet,~C D., Goldberg,~M D., McMillin,~L M., Maddy,~E., Wolf,~W., Zhou,~L., and Liu,~X.: Validation of Atmospheric Infrared Sounder temperature and water vapor retrievals with matched radiosonde measurements and forecasts, J Geophys. Res., 111, D09S15, \doi10.1029/2005JD006116, 2006. Drobot,~S., Stroeve,~J., Maslanik,~J., Emery,~W., Fowler,~C., and Kay,~J.: Evolution of the 2007–2008 Arctic sea ice cover and prospects for a~new record in 2008, Geophys. Res. Lett., 35, L19501, \doi10.1029/2008GL035316, 2008. Fetzer,~E J.: Preface to special section: validation of Atmospheric Infrared Sounder observations, J Geophys. Res., 111, D09S01, \doi10.1029/2005JD007020, 2006. Gao,~W., Zhao,~F., and Gai,~C.: Validation of AIRS retrieval temperature and moisture products and their application in numerical models, Acta Metorol. Sin., 64, 271–280, 2006. Giles,~K A., Laxon,~S W., and Ridout,~A L.: Circumpolar thinning of Arctic sea ice following the 2007 record ice extent minimum, Geophys. Res. Lett., 35, L22502, \doi10.1029/2008GL035710, 2008. Jones,~C G., Willén,~U., Ullerstig,~A., and Hansson,~U.: The Rossby Centre regional atmospheric climate model, Part~I: Model climatology and performance for the present climate over Europe, Ambio, 33(4–5), 199–210, 2004a. Jones,~C G., Wyser,~K., Ullerstig,~A., and Willén,~U.: The Rossby Centre regional atmospheric climate model, Part~II: Application to the Arctic climate, Ambio, 33(4–5), 211–220, 2004b. Kahl,~J D W., Martinez,~D A., and Zaitseva,~N A.: Long-term variability in the low-level inversion layer over the Arctic Ocean, Int J. Climatol., 16, 1297–1313, 1996. Kahn,~B H. and Teixeira,~J.: A~global climatology of temperature and water vapour variance scaling from the Atmospheric Infrared Sounder, J Climate, 22, 5558–5576, 2009. Karlsson,~K.-G. and Dybbroe,~A.: Evaluation of Arctic cloud products from the EUMETSAT Climate Monitoring Satellite Application Facility based on CALIPSO-CALIOP observations, Atmos. Chem. Phys., 10, 1789–1807, \doi10.5194/acp-10-1789-2010, 2010. Kauker,~F., Kaminski,~T., Karcher,~M., Giering,~R., Gerdes,~R., and Voßbeck,~M.: Adjoint analysis of the 2007 all time Arctic sea-ice minimum, Geophys. Res. Lett., 36, L03707, \doi10.1029/2008GL036323, 2009. Kay,~J E. and Gettelman,~A.: Cloud influence on and response to seasonal Arctic sea ice loss, J Geophys. Res.-Atmos., 114, D18204, doi:10.1029/2009JD011773, 2009. Kay,~J E., L'Ecuyer,~T., Gettelman,~A., Stephens,~G., and O'Dell,~C.: The contribution of cloud and radiation anomalies to the 2007 Arctic sea ice extent minimum, Geophys. Res. Lett., 35, L08503, \doi10.1029/2008GL033451, 2008. L'Heureux,~M L., Kumar,~A., Bell,~G D., Halpert,~M S., and Higgins,~R W.: Role of the Pacific-North American (PNA) pattern in the 2007 Arctic sea ice decline, Geophys. Res. Lett., 35, L20701, \doi10.1029/2008GL035205, 2008. Lindsay,~L W., Zhang,~J., Schweiger,~A., Steele,~M., and Stern,~H.: Arctic sea ice retreat in 2007 follows thinning trend, J Climate, 22, 165–176, 2009. Liu,~Y. and Key,~J R.: Detection and analysis of clear-sky, low-level atmospheric temperature inversions with MODIS, J. Atmos. Ocean. Tech., 20, 1727–1737, 2003. Liu,~Y., Key,~J R., Schweiger,~A., and Francis,~J.: Characteristics of satellite-derived clear-sky atmospheric temperature inversion strength in the Arctic, 1980–96, J Climate, 19, 4902–4913, 2006. Mernild, S. H. and Liston, G. E.: The influence of air temperature inversions on snowmelt and glacier mass-balance simulations, Ammassalik Island, SE Greenland, J. Appl. Meteorol. Clim., 49, 47–67, 2010. Olsen,~E T., Susskind,~J., Blaisdell,~J., and Rosenkranz,~P.: AIRS/AMSU/HSB version~5 level~2 quality control and error estimation, JPL/NASA, California Institute of Technology, Pasadena, USA, 15~pp., 2007a. Olsen,~E T., Granger,~S., Manning,~E., and Blaisdell,~J.: AIRS/AMSU/HSB version~5 level~3 quick start, JPL/NASA, California Institute of Technology, Pasadena, USA, 25~pp., 2007b. Pavelsky,~T., Boé J., Hall,~A., and Fetzer,~E.: Atmospheric inversion strength over Polar Oceans in winter regulated by sea ice, Clim. Dynam., \doi10.10007/s00382-010-0756-8, available at: http://www.springerlink.com/content/8731208kn3058174/, 2010. Perovich,~D K., Richter-Menge,~J A., Jones,~K F., and Light,~B.: Sunlight, water, and ice: extreme Arctic sea ice melt during the summer of 2007, Geophys. Res. Lett., 35, L11501, \doi10.1029/2008GL034007, 2008. Schweiger,~A J., Zhang,~J., Lindsay,~R W., and Steele,~M.: Did unusually sunny skies help drive the record sea ice minimum of 2007?, Geophys. Res. Lett., 35, L10503, \doi10.1029/2008GL033463, 2008. Sedlar,~J. and Tjernström,~M.: Stratiform cloud-inversion characterization during the Arctic melt season, Bound-Lay. Meteorol., 132, 455–474, \doi10.1007/s10546-009-9407-1, 2009. Serreze,~M C., Kahl,~J D., and Schnell,~R C.: Low-level temperature inversions of the Eurasian Arctic and comparisons with Soviet drifting stations, J Climate, 5, 615–630, 1992. Susskind,~J., Barnet,~C., Blaisdell,~J., Iredell,~L., Keita,~F., Kouvaris,~L., Molnar,~G., and Chahine,~M.: Accuracy of geophysical parameters derived from Atmospheric Infrared Sounder/Advanced Microwave Sounding Unit as a~function of fractional cloud cover, J Geophys. Res., 111, D09S17, \doi10.1029/2005JD006272, 2006. Tjernström,~M. and Graversen,~R G.: The vertical structure of the lower Arctic troposphere analysed from observations and ERA-40 reanalysis, Q J. Roy. Meteor. Soc., 135, 431–443, 2008. Vihma,~T., Jaagus,~J., Jakobson,~E., and Palo,~T.: Meteorological conditions in the Arctic Ocean in spring and summer 2007 as recorded on the drifting ice station Tara, Geophys. Res. Lett., 35, L18706, \doi10.1029/2008GL034681, 2008. Zhang,~J., Lindsay,~R., Steele,~M., and Schweiger,~A.: What drove the dramatic retreat of Arctic sea ice during summer 2007?, Geophys. Res. Lett., 35, L11505, \doi10.1029/2008GL034005, 2008.