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Retreat of the East Antarctic ice sheet during the last glacial termination

Nature Geoscience volume 4, pages 195202 (2011) | Download Citation

Abstract

The retreat of the East Antarctic ice sheet at the end of the last glacial period has been attributed to both sea-level rise and warming of the ocean at the margin of the ice sheet, but it has been challenging to test these hypotheses. Given the lack of constraints on the timing of retreat, it has been difficult to evaluate whether the East Antarctic ice sheet contributed to meltwater pulse 1a, an abrupt sea-level rise of approximately 20 m that occurred about 14,700 years ago. Here we use terrestrial exposure ages and marine sedimentological analyses to show that ice retreat in Mac. Robertson Land, East Antarctica, initiated about 14,000 years ago, became widespread about 12,000 years ago, and was completed by about 7,000 years ago. We use two models of different complexities to assess the forcing of the retreat. Our simulations suggest that, although the initial stage of retreat may have been forced by sea-level rise, the majority of the ice loss resulted from ocean warming at the onset of the Holocene epoch. In light of our age model we conclude that the East Antarctic ice sheet is unlikely to have been the source of meltwater pulse 1a, and, on the basis of our simulations, suggest that Antarctic ice sheets made an insignificant contribution to eustatic sea-level rise at this time.

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Acknowledgements

The New Zealand team acknowledges financial support from VUW Foundation grants ARCCIM, ARCMORG and New Zealand FRST ANDRILL and ANZICE grants CO5X1001 and VICX0704. The US team thanks the scientific staff, Captain J. Borkowski and his ECO crew, and the Raytheon Polar Services staff who participated on cruise NBP0101. The marine work was supported by National Science Foundation grants OPP-9909367 to A.L., OPP-9909837 to R.D. and NSF-OPP grant 0732467 to E.D. The Australian team thanks the Australian Antarctic Division (AAS1071, 1332), Australian Institute of Nuclear Science and Engineering (03/048), Australian Research Council (DP0556728) and Macquarie University for logistic and financial support. We also thank staff at the Antarctic Marine Geology Research Facility at Florida State University, and T. Fanning, J. Pickard and T. Labrum for field assistance. K. Fleming provided modelled eustatic sea-level data. R. Peltier and R. Drummond provided both eustatic and relative sea-level data for the Mac. Robertson Land coast. B. Hall calibrated and interpreted 14C ages from Taylor Valley.

Author information

Affiliations

  1. Antarctic Research Centre, Victoria University of Wellington, Wellington 6012, New Zealand

    • Andrew Mackintosh
    • , Nicholas Golledge
    •  & Dan Zwartz
  2. Department of Geosciences, Hamilton College, Clinton, New York 13323, USA

    • Eugene Domack
    •  & Caroline Lavoie
  3. Environmental Earth System Science, Stanford University, Stanford, California 94305, USA

    • Robert Dunbar
  4. Department of Geology, Colgate University, Hamilton, New York 13346, USA

    • Amy Leventer
  5. Department of Environment and Geography, Macquarie University, New South Wales 2109, Australia

    • Duanne White
    •  & Damian Gore
  6. Earth and Environmental Systems Institute, Pennsylvania State University, University Park, Pennsylvania 16802, USA

    • David Pollard
  7. Department of Geosciences, University of Massachusetts, Amherst, Massachusetts 01003, USA

    • Robert DeConto
  8. Institute for Environmental Research, ANSTO, Menai, New South Wales 2234, Australia

    • David Fink

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Contributions

A.M. contributed to all aspects of the work, wrote the manuscript and led the field project in Framnes Mountains. N.G. carried out the balance profile experiment, interpretation of swath bathymetry, drafted Figs 14 and contributed to writing. E.D. developed the idea with A.M., contributed to interpretation, writing and discussion of Antarctic-wide marine chronologies. R.D. carried out the marine radiocarbon dating/age modelling and contributed to the discussion of Antarctic-wide chronologies as well as to writing. A.L. led the NBP0101 cruise to Iceberg Alley and Nielsen Basin, helped draft Fig. 2, and contributed to the writing. D.W. carried out exposure dating chemistry, terrestrial radiocarbon dating and contributed to methodology. D.P. and R.D.C. provided ice-sheet model results and contributed to discussions concerning model interpretation. D.F. facilitated and modelled cosmogenic exposure age data and commented on the manuscript. D.Z. calculated modelled ice volume changes, drafted Fig. 5 and commented on the manuscript. D.G. led the AAS, AINSE and ARC projects, and commented on the manuscript. C.L. processed and interpreted swath bathymetry and contributed to the methodology.

Competing interests

The authors declare no competing financial interests.

Corresponding author

Correspondence to Andrew Mackintosh.

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DOI

https://doi.org/10.1038/ngeo1061

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