Export of nutrient rich Northern Component Water preceded early Oligocene Antarctic glaciation

The onset of the North Atlantic Deep Water formation is thought to have coincided with Antarctic ice-sheet growth about 34 million years ago (Ma). However, this timing is debated, in part due to questions over the geochemical signature of the ancient Northern Component Water (NCW) formed in the deep...

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Bibliographic Details
Published in:Nature Geoscience
Main Authors: Coxall, HK, Huck, CE, Huber, M, Lear, CH, Legarda-Lisarri, A, O’Regan, M, Sliwinska, KK, Van de Flierdt, T, De Boer, AM, Zachos, JC, Backman, J
Other Authors: Natural Environment Research Council (NERC)
Format: Article in Journal/Newspaper
Language:unknown
Published: Nature Publishing Group 2018
Subjects:
Science & Technology
Physical Sciences
Geosciences
Multidisciplinary
Geology
MERIDIONAL OVERTURNING CIRCULATION
FORAMINIFERAL MG/CA PALEOTHERMOMETRY
SOUTHERN LABRADOR SEA
THERMOHALINE CIRCULATION
SECULAR VARIATION
DRAKE PASSAGE
ARCTIC-OCEAN
ATLANTIC
EOCENE
EVOLUTION
MD Multidisciplinary
Meteorology & Atmospheric Sciences
Antarctic
Arctic
Arctic Ocean
Drake Passage
Greenland
Antarc*
Antarctica
Foraminifera*
Greenland-Scotland Ridge
Ice Sheet
Labrador Sea
North Atlantic Deep Water
North Atlantic
Subarctic
Online Access:http://hdl.handle.net/10044/1/57836
https://doi.org/10.1038/s41561-018-0069-9
Description
Summary:The onset of the North Atlantic Deep Water formation is thought to have coincided with Antarctic ice-sheet growth about 34 million years ago (Ma). However, this timing is debated, in part due to questions over the geochemical signature of the ancient Northern Component Water (NCW) formed in the deep North Atlantic. Here we present detailed geochemical records from North Atlantic sediment cores located close to sites of deep-water formation. We find that prior to 36 Ma, the northwestern Atlantic was stratified, with nutrient-rich, low-salinity bottom waters. This restricted basin transitioned into a conduit for NCW that began flowing southwards approximately one million years before the initial Antarctic glaciation. The probable trigger was tectonic adjustments in subarctic seas that enabled an increased exchange across the Greenland–Scotland Ridge. The increasing surface salinity and density strengthened the production of NCW. The late Eocene deep-water mass differed in its carbon isotopic signature from modern values as a result of the leakage of fossil carbon from the Arctic Ocean. Export of this nutrient-laden water provided a transient pulse of CO2 to the Earth system, which perhaps caused short-term warming, whereas the long-term effect of enhanced NCW formation was a greater northward heat transport that cooled Antarctica.

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