Conclusions, summary and outlook

doi:10.1017/CBO9780511535659.019

17 - Conclusions, summary and outlook

Published online by Cambridge University Press: 16 October 2009

Antony J. Payne and

Jonathan L. Bamber

Edited by

Jonathan L. Bamber and

Antony J. Payne

Foreword by

John Houghton

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Antony J. Payne: Affiliation:
School of Geographical Sciences, University of Bristol
Jonathan L. Bamber: Affiliation:
School of Geographical Sciences, University of Bristol
Jonathan L. Bamber: Affiliation:
University of Bristol
Antony J. Payne: Affiliation:
University of Bristol

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Summary

Summary of findings

Sea ice

A variety of indicators suggest that during the latter half of the twentieth century the Arctic has undergone substantial climate change (Serreze et al., 2000). One of the key indicators is sea-ice extent and thickness, both of which have shown a measurable and disturbing decrease during the last half of the twentieth century (see Chapter 8). Interestingly, the rate of decrease appears to be at a maximum during summer (see Figure 12.8). The pre-satellite time series (before 1972) has a larger error bar on it, but nonetheless paints a consistent and compelling picture. Extrapolation forward in time suggests that there could, potentially, be no summer sea ice in the Arctic within 50 years. This will have major impacts on energy and moisture exchange, and consequently on the climate of the northern hemisphere. The consequences of such dramatic changes in sea-ice cover are the subject of a number of general circulation model (GCM) studies, and it is currently too early to say what the implications of these changes might be.

The sea-ice record for the Southern Ocean is less temporally extensive and, essentially, limited to the satellite era. Additionally, the seasonal variation in extent is much greater than in the Arctic, increasing the noise on any long-term signal that may be present. In contrast to the Arctic, there is no measurable trend in sea-ice mass balance, although some regional variations have been noted from passive microwave data covering the last 20 years (1979 to 1999; see Parkinson (2002)).

Information

Type: Chapter
Information: Mass Balance of the Cryosphere
Observations and Modelling of Contemporary and Future Changes
, pp. 623 - 640

DOI: https://doi.org/10.1017/CBO9780511535659.019 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2004

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References

Abdalati, W.et al. 2001. Outlet gplacier and margin elevation changes: near-coastal thinning of the Greenland ice sheet. J. Geophys. Res.-Atmos. 106 (D24), 33 729–41CrossRef Google Scholar

Bindschadler, R. and Vornberger, P. 1998. Changes in the West Antarctic ice sheet since 1963 from declassified satellite photography. Science 279 (5351), 689–92CrossRef Google Scholar PubMed

Blatter, H., Clarke, G. K. C. and Colinge, J. 1998. Stress and velocity fields in glaciers: Part II. Sliding and basal stress distribution. J. Glaciol. 44 (148), 457–66CrossRef Google Scholar

Church, J. A. et al. 2001. In Houghton, J. T. et al., eds., Changes in Sea-level. IPCC Third Scientific Assesment of Climate Change. Cambridge University Press, pp. 640–93

Claussen, M.et al. 2002. Earth system models of intermediate complexity: closing the gap in the spectrum of climate system models. Climate Dyn. 18 (7), 579–86Google Scholar

Conway, H., Hall, B. L., Denton, G. H., Gades, A. M. and Waddington, E. D. 1999. Past and future grounding-line retreat of the West Antarctic ice sheet. Science 286 (5438), 280–3CrossRef Google Scholar PubMed

Conway, H., Catania, G., and Raymond, C. F. 2002. Switch of flow direction in an Antarctic ice stream. Nature 419, 465–7CrossRef Google Scholar

Dyurgerov, M. B. and Meier, M. F. 1997. Mass balance of mountain and subpolar glaciers: a new global assessment for 1961–1990. Arctic & Alpine Res. 29 (4), 379–91CrossRef Google Scholar

Gregory, J. M. and Oerlemans, J. 1998. Simulated future sea-level rise due to glacier melt based on regionally and seasonally resolved temperature changes. Nature 391 (6666), 474–6CrossRef Google Scholar

Gudmundsson, G. H., Raymond, C. F. and Bindschadler, R. 1998. The origin and longevity of flow stripes on Antarctic ice streams. Ann. Glaciol. 27, 145–52CrossRef Google Scholar

Hindmarsh, R. C. A. 1993. Modeling the dynamics of ice sheets. Prog. Phys. Geog. 17 (4), 391–412CrossRef Google Scholar

Hindmarsh, R. C. A. and Meur, E. 2001. Dynamical processes involved in the retreat of marine ice sheets. J. Glaciol. 47 (157), 271–82CrossRef Google Scholar

Hulbe, C. L. and MacAyeal, D. R. 1999. A new numerical model of coupled inland ice sheet, ice stream, and ice shelf flow and its application to the West Antarctic ice sheet. J. Geophys. Res. Solid Earth 104 (B11), 25 349–66CrossRef Google Scholar

Huybrechts, P. 2002. Sea-level changes at the LGM from ice-dynamic reconstructions of the Greenland and Antarctic ice sheets during the glacial cycles. Quat. Sci. Rev. 21 (1–3), 203–31CrossRef Google Scholar

Huybrechts, P. and Wolde, J. 1999. The dynamic response of the Greenland and Antarctic ice sheets to multiple-century climatic warming. J. Climate 12 (8), 2169–882.0.CO;2>CrossRef Google Scholar

Janssens, I. and Huybrechts, P. 2000. The treatment of meltwater retention in mass-balance parameterizations of the Greenland ice sheet. Ann. Glaciol. 31, 133–40CrossRef Google Scholar

Jóannesson, T., Raymond, C. and Waddington, E. 1989. Time-scale for adjustment of glaciers to changes in mass balance. J. Glaciol. 35 (121), 355–69CrossRef Google Scholar

Joughin, I. and Tulaczyk, S. 2002. Positive mass balance of the Ross ice streams, West Antarctica. Science 295 (5554), 476–80CrossRef Google Scholar PubMed

Kanagaratnam, P., Gogineni, S. P., Gundestrup, N. and Larsen, L. 2001. High-resolution radar mapping of internal layers at the North Greenland ice core project. J. Geophys. Res. Atmos. 106 (D24), 33 799–811CrossRef Google Scholar

Lythe, M. B. and Vaughan, D. G. 2001. BEDMAP: a new ice thickness and subglacial topographic model of Antarctica. J. Geophys. Res. Solid Earth 106 (B6), 11 335–51CrossRef Google Scholar

MacAyeal, D. R., Bindschadler, R. A. and Scambos, T. A. 1995. Basal friction of ice-stream-E, West Antarctica. J. Glaciol. 41 (138), 247–62CrossRef Google Scholar

McConnell, J. R.et al. 2000. Changes in Greenland ice sheet elevation attributed primarily to snow accumulation variability. Nature 406 (6798), 877–9CrossRef Google Scholar PubMed

Meier, M. F. 1984. Contribution of small glaciers to global sea-level. Science 226 (4681), 1418–21CrossRef Google Scholar PubMed

Oerlemans, J. 1997. Climate sensitivity of Franz Josef Glacier, New Zealand, as revealed by numerical modeling. Arctic & Alpine Res. 29 (2), 233–9CrossRef Google Scholar

Oerlemans, J.et al. 1998. Modelling the response of glaciers to climate warming. Climate Dyn. 14 (4), 267–74CrossRef Google Scholar

Parkinson, C. L. 2002. Trends in the length of the Southern Ocean sea-ice season, 1979–99. Ann. Glaciol. 34, 435–40CrossRef Google Scholar

Payne, A. J. 1998. Dynamics of the Siple Coast ice streams, West Antarctica: results from a thermomechanical ice sheet model. Geophys. Res. Lett. 25 (16), 3173–6CrossRef Google Scholar

Retzlaff, R. and Bentley, C. R. 1993. Timing of stagnation of ice stream-C, West Antarctica, from short-pulse radar studies of buried surface crevasses. J. Glaciol. 39 (133), 553–61CrossRef Google Scholar

Rignot, E. J. 1998. Fast recession of a West Antarctic glacier. Science 281 (5376), 549–51CrossRef Google Scholar

Rignot, E. J., Vaughan, D. G., Schmeltz, M., Dupont, T. and MacAyeal, D. 2002. Acceleration of Pine Island and Thwaites glaciers, West Antarctica. Ann. Glaciol. 34, 189–94CrossRef Google Scholar

Ritz, C., Fabre, A. and Letreguilly, A. 1996. Sensitivity of a Greenland ice sheet model to ice flow and ablation parameters: consequences for the evolution through the last climatic cycle, Climate Dyn. 13 (1), 11–24CrossRef Google Scholar

Ritz, C., Rommelaere, V. and Dumas, C. 2001. Modeling the evolution of Antarctic ice sheet over the last 420 000 years: implications for altitude changes in the Vostok region. J. Geophys. Res. Atmos. 106 (D23), 31 943–64CrossRef Google Scholar

Scambos, T. A., Hulbe, C., Fahnestock, M. and Bohlander, J. 2000. The link between climate warming and break-up of ice shelves in the Antarctic peninsula. J. Glaciol. 46 (154), 516–30CrossRef Google Scholar

Serreze, M. C.et al. 2000. Observational evidence of recent change in the northern high-latitude environment. Climatic Change 46 (1–2), 159–207CrossRef Google Scholar

Shepherd, A., Wingham, D. J., Mansley, J. A. D. and Corr, H. F. J. 2001. Inland thinning of Pine Island glacier, West Antarctica. Science 291 (5505), 862–4CrossRef Google Scholar PubMed

Thomas, R. H.et al. 2001. Mass balance of higher-elevation parts of the Greenland ice sheet. J. Geophys. Res.-Atmos. 106 (D24), 33 707–16CrossRef Google Scholar

Thomas, R. H. and Bentley, C. R. 1978. A model for Holocene retreat of the West Antarctic ice sheet. Quat. Res. 10, 150–70CrossRef Google Scholar

Tulaczyk, S., Kamb, W. B. and Engelhardt, H. F. 2000. Basal mechanics of ice stream B, West Antarctica 1. Till mechanics. J. Geophys. Res. Solid Earth 105 (B1), 463–81CrossRef Google Scholar

Veen, C. J. 2002. Calving glaciers, Prog. Phys. Geog. 26 (1), 96–122CrossRef Google Scholar

Tatenhove, F. G. M., Meer, J. J. M. and Huybrechts, P. 1995. Glacial-geological geomorphological research in West Greenland used to test an ice-sheet. Quat. Res. 44 (3), 317–27CrossRef Google Scholar

Vaughan, D. G. and Doake, C. S. M. 1996. Recent atmospheric warming and retreat of ice shelves on the Antarctic peninsula. Nature 379 (6563), 328–31CrossRef Google Scholar

Vavrus, S. J. 1999. The response of the coupled arctic sea ice-atomospheric system to orbital forcing and ice motion at 6 kyr and 115kyr BP. J. Climate 12 (3), 873–62.0.CO;2>CrossRef Google Scholar

Vinnikov, K. Y.et al. 1999. Global warming and northern hemisphere sea ice extent. Science 286 (5446), 1934–7CrossRef Google Scholar PubMed

Whillans, I. M. and Veen, C. J. 1997. The role of lateral drag in the dynamics of ice stream B, Antarctica. J. Glaciol 43 (144), 231–7CrossRef Google Scholar

Winebrenner, D. P., Arthern, R. J. and Shuman, C. A. 2001. Mapping Greenland accumulation rates using observations of thermal emission at 4.5-cm wavelength. J. Geophys. Res. Atmos. 106 (D24), 33 919–34CrossRef Google Scholar

Wingham, D. J., Ridout, A. J., Scharroo, R., Arthern, R. J. and Shum, C. K. 1998. Antarctic elevation change from 1992 to 1996. Science 282 (5388), 456–8CrossRef Google Scholar PubMed

Zuo, Z. and Oerlemans, J. 1997. Contribution of glacier melt to sea-level rise since AD 1865: a regionally differentiated calculation. Climate Dyn. 13 (12), 835–45CrossRef Google Scholar

Zwally, H. J., Abdalati, W., Herring, T., Larson, K., Saba, J. and Steffen, K. 2002. Surface melt-induced acceleration of Greenland ice-sheet flow. Science 297, 218–20CrossRef Google Scholar PubMed

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