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A persistent and dynamic East Greenland Ice Sheet over the past 7.5 million years
File | Description | Size | Format | |
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Bierman_et_al_2016_Nature_accepted.pdf | Accepted version | 240.43 kB | Adobe PDF | View/Open |
Title: | A persistent and dynamic East Greenland Ice Sheet over the past 7.5 million years |
Authors: | Bierman, PR Shakun, JD Corbett, LB Zimmerman, SR Rood, DH |
Item Type: | Journal Article |
Abstract: | Climate models show that ice-sheet melt will dominate sea-level rise over the coming centuries, but our understanding of ice-sheet variations before the last interglacial 125,000 years ago remains fragmentary. This is because terrestrial deposits of ancient glacial and interglacial periods1, 2, 3 are overrun and eroded by more recent glacial advances, and are therefore usually rare, isolated and poorly dated4. In contrast, material shed almost continuously from continents is preserved as marine sediment that can be analysed to infer the time-varying state of major ice sheets. Here we show that the East Greenland Ice Sheet existed over the past 7.5 million years, as indicated by beryllium and aluminium isotopes (10Be and 26Al) in quartz sand removed by deep, ongoing glacial erosion on land and deposited offshore in the marine sedimentary record5, 6. During the early Pleistocene epoch, ice cover in East Greenland was dynamic; in contrast, East Greenland was mostly ice-covered during the mid-to-late Pleistocene. The isotope record we present is consistent with distinct signatures of changes in ice sheet behaviour coincident with major climate transitions. Although our data are continuous, they are from low-deposition-rate sites and sourced only from East Greenland. Consequently, the signal of extensive deglaciation during short, intense interglacials could be missed or blurred, and we cannot distinguish between a remnant ice sheet in the East Greenland highlands and a diminished continent-wide ice sheet. A clearer constraint on the behaviour of the ice sheet during past and, ultimately, future interglacial warmth could be produced by 10Be and 26Al records from a coring site with a higher deposition rate. Nonetheless, our analysis challenges the possibility of complete and extended deglaciation over the past several million years. |
Issue Date: | 8-Dec-2016 |
Date of Acceptance: | 6-Oct-2016 |
URI: | http://hdl.handle.net/10044/1/44477 |
DOI: | 10.1038/nature20147 |
ISSN: | 0028-0836 |
Publisher: | Nature Research |
Start Page: | 256 |
End Page: | 260 |
Journal / Book Title: | Nature |
Volume: | 540 |
Issue: | 7632 |
Copyright Statement: | © 2016 Nature Publishing Group |
Keywords: | Science & Technology Multidisciplinary Sciences Science & Technology - Other Topics NUCLIDE PRODUCTION-RATES LATE PLIOCENE GREENLAND SITU COSMOGENIC BE-10 DEEP-SEA-TEMPERATURE HALF-LIFE SOUTHERN GREENLAND RAFTED DETRITUS HEAT-FLUX GLACIATION CLIMATE General Science & Technology |
Publication Status: | Published |
Online Publication Date: | 2016-12-07 |
Appears in Collections: | Earth Science and Engineering Faculty of Engineering |