Ice dynamics; SAR interferometry; Coherence tracking
Abstract :
[en] The surface velocity field of Shirase Glacier, a fast-flowing East Antarctic outlet glacier, is determined from ERS synthetic aperture radar (SAR) images by means of speckle tracking using phase correlation, a technique which matches small image kernels of two complex SAR images by maximization of the local coherence. Velocity estimates are used to calculate surface strain rates, which are then used to calculate the large-scale, vertically integrated force balance and to determine the major stress components resisting the driving stress. For the whole glacier system, the driving stress is largely balanced by the basal drag, but with contributions from lateral drag up to 15% of the driving stress at the grounding line. Longitudinal stress gradients have only local importance to the balance of forces, limited to an area of a few square kilometers near the grounding line, where they resist the driving stress. In the grounded part of the glacier, >90% of the total ice velocity is due to basal sliding. Comparison with a balance-flux distribution of the Antarctic ice sheet suggests that the glacier in the downstream part of the Shirase drainage basin is close to equilibrium, showing a slight negative imbalance.
Research Center/Unit :
Vrij Universiteit Brussels CSL - Centre Spatial de Liège - ULiège
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Bibliography
Aoki, S., T. Ozawa, K. Doi and K. Shibuya. 2000. GPS observations of the sea level variation in Lützow-Holm Bay, Antarctica. Geophys. Res. Lett., 27(2), 2285-2288.
Bamber, J. L. and R. A. Bindschadler. 1997. An improved elevation dataset for climate and ice-sheet modelling: validation with satellite imagery. Ann. Glaciol., 25, 439-444.
Derauw, D. 1999. Phasimétrie par radar à synthèse douverture. (Ph.D. thesis, Université de Liège.)
Fujii, Y. 1981. Aerophotographic interpretation of surface features and estimation of ice discharge at the outlet of the Shirase drainage basin, Antarctica. Antarct. Res., 72, 1-15.
Giovinetto, M. B. and C. R. Bentley. 1985. Surface balance in ice drainage systems of Antarctica. Antarct. J. U.S., 20(4), 6-13.
Gray, A. L., K. E. Mattar and P. W. Vachon. 1998. InSAR results from the RADARSAT Antarctic mapping mission data: estimation of data using a simple registration procedure. In Stein, T., ed. IGARSS '98 18th International Geoscience and Remote Sensing Symposium, 6-10 July 1998. Seattle, Washington. Proceedings, Piscataway, NJ, Institute of Electrical and Electronics Engineers, 1638-1640.
Hooke, R. LeB. 1981. Flow law for polycrystalline ice in glaciers: comparison of theoretical predictions, laboratory data, and field measurements. Rev. Geophys. Space Phys., 19(4), 664-672.
Høydal, Ø. A. 1996. A force-balance study of ice flow and basal conditions of Jutulstraumen, Antarctica. J. Glaciol., 42(142), 413-425.
Huybrechts, P., D. Steinhage, F. Wilhelms and J. Bamber. 2000. Balance velocities and measured properties of the Antarctic ice sheet from a new compilation of gridded data for modelling. Ann. Glaciol., 30, 52-60.
Joughin, I. R., M. A. Fahnestock and J. L. Bamber. 2000. Ice flow in the northeast Greenland ice stream. Ann. Glaciol., 31, 141-146.
Just, D. and R. Bamler. 1994. Phase statistics of interferograms with application to synthetic aperture radar. Appl. Opt., 33(20), 4361-4368.
Kim, K. T., K. C. Jezek and H. G. Sohn. 2001. Ice-shelf advance and retreat rates along the coast of Queen Maud Land, Antarctica. J. Geophys. Res., 106(C4), 7097-7106.
Lythe, M. B., D. G. Vaughan and BEDMAP consortium. 2000. BEDMAP- bed topography of the Antarctic. (Scale 1:10,000,000.) British Antarctic Survey. (BAS (Misc) 9; http://www.antarctica.ac.uk/aedc/bedmap/.)
Mae, S. 1979. The basal sliding of a thinning ice sheet, Mizuho Plateau, East Antarctica. J. Glaciol., 24(90), 53-61.
Mae, S. and R. Naruse. 1978. Possible causes of ice sheet thinning in the Mizuho Plateau. Nature, 273 (5660), 291-293.
Mae, S. and M. Yoshida. 1987. Airborne radio echo-sounding in Shirase Glacier drainage basin, Antarctica. Ann. Glaciol., 9, 160-165.
Mayer, C. and P. Huybrechts. 1999. Ice-dynamic conditions across the grounding zone, Ekströmisen, East Antarctica. J. Glaciol., 45(150), 384-393.
Michel, R. and E. Rignot. 1999. Flow of Glaciar Moreno, Argentina, from repeat-pass Shuttle Imaging Radar images: comparison of the phase correlation method with radar interferometry. J. Glaciol., 45(149), 93-100.
Moriwaki, K. and Y. Yoshida. 1983. Submarine topography of Lützow-Holm Bay, Antarctica. Natl. Inst. Polar Res. Mem., Special Issue 28, 247-258.
Nakawo, M., Y. Ageta and A. Yoshimura. 1978. Discharge of ice across Sôya Coast. Natl. Inst. Polar Res. Mem., Special Issue 7, 235-244.
Nishio, F. and S. Uratsuka. 1991. Subglacial water layer and grounding line derived from backscattering coefficients of radio echo sounding in the Shirase Glacier and Roi Baudouin Ice Shelf, East Antarctica. Proc. NIPR Symp. Polar Meteorol. Glaciol. 4, 93-102.
Nishio, F., S. Mae, H. Ohmae, S. Takahashi, M. Nakawo and K. Kawada. 1989. Dynamical behaviour of the ice sheet in Mizuho Plateau, East Antarctica. Proc. NIPR Symp. Polar Meteorol. Glaciol. 2, 97-104.
Rodriguez, E. and J. M. Martin. 1992. Theory and design of interferometric synthetic aperture radars. IEEE Proc., Ser. F, 139(2), 147-159.
Rolstad, C., I. M. Whillans, J. O. Hagen and F. Isaksson. 2000. Large-scale force budget of an outlet glacier: Jutulstraumen, Dronning Maud Land, East Antarctica. Ann. Glaciol., 30, 35-41.
Satow, K. and T. Kikuchi. 1995. The 10 m snow temperature in the ice sheet. In Higashi, A., ed. Antarctica, east Queen Maud Land, Enderby Land: glaciological folio. Tokyo, National Institute of Polar Research, map.
Toh, H. and K. Shibuya. 1992. Thinning rate of ice sheet on Mizuho Plateau, East Antarctica, determined by GPS differential positioning. In Yoshida, Y., K. Kaminuma and K. Shiraishi, eds. Recent progress in Antarctic earth sciences. Tokyo, Terra Scientific Publishing Co., 579-583.
Van der Veen, C. J. and I. M. Whillans. 1989. Force budget: I. Theory and numerical methods. J. Glaciol., 35(119), 53-60.
Wada, M. and S. Mae. 1981. Airborne radio echo sounding on the Shirase Glacier and its drainage basin. Antarct. Rec., 72, 16-25.
Wingham, D. J., A. L. Ridout, R. Scharroo, R. J. Arthern and C. K. Shum. 1998. Antarctic elevation change 1992 to 1996. Science, 282 (5388), 456-458.
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