Abstract
During a ship voyage from Tasmania to Antarctica in summer 2000/01, radiative and meteorological measurements were continuously made, from which the surface energy budget was calculated. Sea conditions throughout the voyage ranged from open water to broken pack and finally to snow-covered unbroken sea ice in McMurdo Sound. The global radiation increased on average during the trip (to higher latitudes) as we travelled poleward. The net radiation, which was positive (toward the surface) on average, decreased however, mostly due to the increase in surface albedo. For open water, most of the net radiation is used for evapouration (61%), while for broken sea-ice conditions, nearly all energy is used for melting of the sea ice or heating of the ocean (96%). For unbroken snow-covered sea ice, the net radiation lies close to zero, due to the high surface albedo, which reached a mean value of 0.81. The sensible heat flux becomes the largest heat source and nearly all the energy is used for warming of the surface. Finally, a Radarsat image, on which the ship track was visible, was used to compare the ship observations with satellite derived ice types.
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References
Allison I., Brandt R., Warren S. (1993) ‘East Antarctic Sea Ice: Albedo, Thickness Distribution, and Snow Cover’. J. Geophys. Res. 98(C7), 12,417–12:429
W. Ambach (1974) ArticleTitle‘The Influence of Fractional Cloud Cover on the Net Radiation Balance of a Snow Surface with High Albedo’ J. Glaciol. 13 IssueID67 73–84
J.J. Carroll B. Fitch (1981) ArticleTitle‘Effects of Solar Elevation and Cloudiness of Snow Albedo at the South Pole’ J. Geophys. Res. 86 IssueIDC6 521–576
J.R. Garatt (1994) The Atmospheric Boundary Layer Cambridge University Press Cambridge 316
A.L. Gordon (1981) ArticleTitle‘Seasonality of Southern Ocean Ice’ J. Geophys. Res. 86 IssueIDC5 4193–4197
H. Hauser G. Wendler U. Adolphs M.O. Jeffries (1999) ArticleTitle‘Energy Exchange in Early Spring Over Sea Ice in the Pacific Sector of the Southern Ocean’ J. Geophys. Res. 104 IssueIDD4 3925–3935 Occurrence Handle10.1029/1998JD200069
H. Lettau (1939) Atmosphärische Turbulenz Akademische Verlagsgesellschaft Leipzig 283
A. Lopes E. Nerzy R. Touz H. Laur (1993) ArticleTitle‘Structure Detection and Statistical Adaptive Speckle Filtering in SAR Images’ Int. J. Remote Sens. 14 1735–1758
J.C. King J. Turner (1997) Antarctic Meteorology and Climatology, Cambridge Atmospheric and Space Science Series Cambridge University Press U.K. 409
M. Lythe A. Hauser G. Wendler (1999) ArticleTitle‘Classification of Sea Ice Types in the Ross Sea Antarctica from SAR and AVHRR Imagery’ Int. J. Remote Sens. 20 3073–3085 Occurrence Handle10.1080/014311699211624
A.P. Makshtas (1991) The Heat Budget of Arctic Ice in the Winter International Glaciological Society Cambridge U.K. 78
D.M. Smith (1996) ArticleTitle‘Speckle Reduction and Segmentation of Synthetic Aperture Radar images’ Int. J. Remote Sens. 12 2043–2057
C. Stearns G. Wendler (1988) ArticleTitle‘Research Results from Antarctic Automatic Weather Station’ Rev. Geophys. 26 IssueID1 45–61
N. Untersteiner (1961) ArticleTitle‘On the Mass and Heat Balance of Arctic Sea Ice’ Arch. Meteorol. Geophys. Bioklimatol. 12 1151–1182
Vihma, T., Uotila, J., Cheng, B., and Launiainen, J.: (2002), ‘Surface Heat Budget over the Weddell Sea: Buy Results and Model Comparison’, J. Geophys. Res. 107(C2), 10.1029/2000JC000372.
S. Warren (1982) ArticleTitle‘Optical Properties of Snow’ Rev. Geophys. 20 67–89
G. Wendler (1986) ArticleTitle‘The Radiation Paradox on the Slopes of the Antarctic Continent’ Polarforschung 56 IssueID1/2 33–41
G. Wendler U. Adolphs A. Hauser B. Moore (1997) ArticleTitleOn the Surface Energy Budget of Sea Ice J. Glaciol. 43 IssueID143 122–130
Wendler, G., Moore, B., Hartmann, B., Stuefer M., and Flint, R.: (2004), ‘The Effects of Multiple Reflection and Albedo on the Net Radiation in the Pack Ice Zones of Antarctica’, J. Geophys. Res. 109, DO6113.10.1029/2003JD003927.
A.P. Worby A. Allison (1991) ArticleTitle‘Ocean-atmosphere Exchange over thin, Variable Concentration Antarctic Pack Ice’ Ann. Glaciol. 15 184–190
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Wendler, G., Hartmann, B., Wyatt, C. et al. Midsummer Energy Balance for the Southern Seas. Boundary-Layer Meteorol 117, 131–148 (2005). https://doi.org/10.1007/s10546-004-7090-9
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DOI: https://doi.org/10.1007/s10546-004-7090-9