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Recent Antarctic Peninsula warming relative to Holocene climate and ice-shelf history

Abstract

Rapid warming over the past 50 years on the Antarctic Peninsula is associated with the collapse of a number of ice shelves and accelerating glacier mass loss1,2,3,4,5,6,7. In contrast, warming has been comparatively modest over West Antarctica and significant changes have not been observed over most of East Antarctica8,9, suggesting that the ice-core palaeoclimate records available from these areas may not be representative of the climate history of the Antarctic Peninsula. Here we show that the Antarctic Peninsula experienced an early-Holocene warm period followed by stable temperatures, from about 9,200 to 2,500 years ago, that were similar to modern-day levels. Our temperature estimates are based on an ice-core record of deuterium variations from James Ross Island, off the northeastern tip of the Antarctic Peninsula. We find that the late-Holocene development of ice shelves near James Ross Island was coincident with pronounced cooling from 2,500 to 600 years ago. This cooling was part of a millennial-scale climate excursion with opposing anomalies on the eastern and western sides of the Antarctic Peninsula. Although warming of the northeastern Antarctic Peninsula began around 600 years ago, the high rate of warming over the past century is unusual (but not unprecedented) in the context of natural climate variability over the past two millennia. The connection shown here between past temperature and ice-shelf stability suggests that warming for several centuries rendered ice shelves on the northeastern Antarctic Peninsula vulnerable to collapse. Continued warming to temperatures that now exceed the stable conditions of most of the Holocene epoch is likely to cause ice-shelf instability to encroach farther southward along the Antarctic Peninsula.

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Figure 1: Regional and climatic setting of the Antarctic Peninsula.
Figure 2: Isotope and depth–age profiles of the JRI ice core.
Figure 3: Holocene temperature history of the Antarctic Peninsula.
Figure 4: Two-thousand-year climate history of the Antarctic Peninsula.

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Acknowledgements

We thank our colleague in the field, S. Shelley, who took part in the ice-core drilling project; the captain and crew of HMS Endurance, who provided logistical support for the drilling field season; S. Kipfstuhl and the Alfred Wegner Institute at Bremerhaven for assistance in the processing of the ice core; J. Smellie and S. Roberts for discussions on Antarctic Peninsula tephras; D. Hodgson and E. Wolff for comments during preparation of the manuscript; and E. Capron, N. Lang, J. Levine and E. Ludlow for laboratory assistance. This study is part of the British Antarctic Survey Polar Science for Planet Earth Programme and was funded by the Natural Environment Research Council. Support from the Institut Polaire Français - Paul Emile Victor (IPEV), and from the Institut National des Sciences de l’Univers in France (INSU/PNEDC “AMANCAY” project), facilitated by J. Chappellaz and F. Vimeux, enabled the technical contribution of the French National Center for Drilling and Coring (INSU/C2FN).

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Authors and Affiliations

Authors

Contributions

R.M. designed the project. R.M., N.J.A. and R.C.A.H. constructed the age scale, and R.M., N.J.A., C.A., L.F. and J.T. performed the isotopic, chemical and physical measurements to characterize the ice. R.M., N.J.A., J.T., L.C.S., O.A. and S.F. were involved with the logistics and fieldwork that enabled the ice-core drilling. R.M. and N.J.A. co-wrote the manuscript.

Corresponding author

Correspondence to Robert Mulvaney.

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The authors declare no competing financial interests.

Supplementary information

Supplementary Information

This file contains Supplementary Table 1, Supplementary Figures 1-2 and Supplementary References. (PDF 412 kb)

Supplementary Data

This file contains Supplementary Data showing dD and temperature anomaly data for the James Ross Island ice core. (XLS 501 kb)

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Mulvaney, R., Abram, N., Hindmarsh, R. et al. Recent Antarctic Peninsula warming relative to Holocene climate and ice-shelf history. Nature 489, 141–144 (2012). https://doi.org/10.1038/nature11391

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