Millennial and centennial CO 2 release from the Southern Ocean during the last deglaciation

For its greenhouse effects, atmospheric CO 2 can critically influence the global climate on millennial and centennial timescales. Pleistocene atmospheric CO 2 variations must involve changes in ocean storage of carbon, but the mechanisms and pathways of carbon transfer between the oceanic and atmosp...

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Bibliographic Details
Published in:Nature Geoscience
Main Authors: Yu, Jimin, Oppo, Delia W., Jin, Zhangdong, Lacerra, Matthew, Ji, Xuan, Umling, Natalie E., Lund, David C., McCave, Nick, Menviel, Laurie, Shao, Jun, Xu, Chen
Format: Article in Journal/Newspaper
Language:English
Published: 2022
Subjects:
Antarctic
Southern Ocean
Antarc*
Online Access:https://research-portal.st-andrews.ac.uk/en/researchoutput/millennial-and-centennial-co2-release-from-the-southern-ocean-during-the-last-deglaciation(f126d5cd-7b1f-473e-a5ea-b023f4bb7e2a).html
https://doi.org/10.1038/s41561-022-00910-9
Description
Summary:For its greenhouse effects, atmospheric CO 2 can critically influence the global climate on millennial and centennial timescales. Pleistocene atmospheric CO 2 variations must involve changes in ocean storage of carbon, but the mechanisms and pathways of carbon transfer between the oceanic and atmospheric reservoirs are poorly understood due, in part, to complications associated with interpretation of carbonate system proxy data. Here we employ a recently developed approach to reconstruct upper Atlantic air–sea CO 2 exchange signatures through the last deglaciation. Using this approach, proxy and model data each suggest that there was a net release of CO 2 via the Atlantic sector of the Southern Ocean during the early deglaciation, which probably contributed to the millennial-scale atmospheric CO 2 rise during Heinrich Stadial 1 at ~18.0–14.7 kyr ago. Moreover, our data reveal a previously unrecognized mechanism for the centennial-scale atmospheric CO 2 rise at the onset of the Bølling warming event around 14.7 kyr ago, namely, the expansion of Antarctic Intermediate Water, a water mass that is especially inefficient at sequestering atmospheric CO 2 . Our findings highlight the role of the Southern Ocean outgassing and intermediate water-mass production and volume variations in governing millennial- and centennial-timescale atmospheric CO 2 rises during the last deglaciation.

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