4.8 Article

Radiocarbon evidence for the stability of polar ocean overturning during the Holocene

Journal

NATURE GEOSCIENCE
Volume 16, Issue 7, Pages 631-+

Publisher

NATURE PORTFOLIO
DOI: 10.1038/s41561-023-01214-2

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Proxy-based studies have linked the pre-industrial atmospheric p(CO2) rise to changes in Southern Ocean overturning. However, the history of polar ocean overturning and ventilation through the Holocene remains poorly constrained. This study suggests that long-term polar ocean overturning is not responsible for millennial atmospheric pCO(2) evolution, instead, changes in carbon redistribution and land organic carbon stock might regulate CO2 budget during this period.
Proxy-based studies have linked the pre-industrial atmospheric p(CO2) rise of similar to 20 ppmv in the mid- to late Holocene to an inferred increase in the Southern Ocean overturning and associated biogeochemical changes. However, the history of polar ocean overturning and ventilation through the Holocene remains poorly constrained, leaving important gaps in the assessment of the feedbacks between changes in ocean circulation and the carbon cycle in a warm climate state. The deep-ocean radiocarbon content, which provides a measure of ventilation, responds to circulation changes on centennial to millennial time scales. Here we present absolutely dated deep-sea coral radiocarbon records from the Drake Passage, between South America and Antarctica, and Reykjanes Ridge, south of Iceland, over the Holocene. Our data suggest that ventilation in the Antarctic circumpolar waters and North Atlantic Deep Water is surprisingly invariant within proxy uncertainties at our sampling resolution. Our findings indicate that long-term, large-scale polar ocean overturning has not been disturbed to a level resolvable by radiocarbon and is probably not responsible for the millennial atmosphere pCO(2) evolution through the Holocene. Instead, continuous nutrient and carbon redistribution within the water column following deglaciation, as well as changes in land organic carbon stock, might have regulated atmospheric CO2 budget during this period.

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