Southern Ocean carbon sink enhanced by sea-ice feedbacks at the Antarctic Cold Reversal
The Southern Ocean occupies 14% of the Earth’s surface and plays a fundamental role in the global carbon cycle and climate. It provides a direct connection to the deep ocean carbon reservoir through biogeochemical processes that include surface primary productivity, remineralization at depth and the...
Published in: | Nature Geoscience |
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Main Authors: | , , , , , , , , , , , , , , , , , , , |
Format: | Article in Journal/Newspaper |
Language: | English |
Published: |
Springer Nature
2020
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Subjects: | |
Online Access: | http://hdl.handle.net/2440/126992 https://doi.org/10.1038/s41561-020-0587-0 |
Summary: | The Southern Ocean occupies 14% of the Earth’s surface and plays a fundamental role in the global carbon cycle and climate. It provides a direct connection to the deep ocean carbon reservoir through biogeochemical processes that include surface primary productivity, remineralization at depth and the upwelling of carbon-rich water masses. However, the role of these different processes in modulating past and future air–sea carbon flux remains poorly understood. A key period in this regard is the Antarctic Cold Reversal (ACR, 14.6–12.7 kyr bp), when mid- to high-latitude Southern Hemisphere cooling coincided with a sustained plateau in the global deglacial increase in atmospheric CO₂. Here we reconstruct high-latitude Southern Ocean surface productivity from marine-derived aerosols captured in a highly resolved horizontal ice core. Our multiproxy reconstruction reveals a sustained signal of enhanced marine productivity across the ACR. Transient climate modelling indicates this period coincided with maximum seasonal variability in sea-ice extent, implying that sea-ice biological feedbacks enhanced CO₂ sequestration and created a substantial regional marine carbon sink, which contributed to the plateau in CO₂ during the ACR. Our results highlight the role Antarctic sea ice plays in controlling global CO₂, and demonstrate the need to incorporate such feedbacks into climate–carbon models. C.J. Fogwill, C.S.M. Turney, L. Menviel, A. Baker, M.E. Weber, B. Ellis, Z.A. Thomas, N.R. Golledge, D. Etheridge, M. Rubino, D.P. Thornton, T.D. van Ommen, A.D. Moy, M.A.J. Curran, S. Davies, M.I. Bird, N.C. Munksgaard, C.M. Rootes, H. Millman, J. Vohra, A. Rivera, A. Mackintosh, J. Pike, I.R. Hall, E.A. Bagshaw, E. Rainsley, C. Bronk-Ramsey, M. Montenari, A.G. Cage, M.R.P. Harris, R. Jones, A. Power, J. Love, J. Young, L.S. Weyrich, and A. Cooper |
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