Drake passage cold-water coral Ba/Ca and boron isotopes during NBP cruises NBP11-03 and NBP08-05

The Antarctic Cold Reversal (ACR; 14.7 to 13 ka) phase of the last deglaciation saw a pause in the rise of atmospheric pCO2 and Antarctic temperature, contrasted with warming in the North. Mechanisms associated with interhemispheric heat transfer have been proposed to explain features of this event,...

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Bibliographic Details
Main Authors: Stewart, Joseph A, Li, Tao, Spooner, Peter T, Burke, Andrea, Chen, Tianyu, Roberts, Jenny, Rae, James W B, Peck, Victoria L, Kender, Sev, Liu, Qian, Robinson, Laura F
Format: Dataset
Language:English
Published: PANGAEA 2020
Subjects:
AGE
uncertainty
Barium/Calcium ratio
Benthic foraminifera
circulation
cold-water corals
Comment
Depth
bathymetric
DH117
DH74
DH75
DR27
DR34
DR35
DR38
DR40
Drake Passage
Dredge
DRG
Elevation of event
Event label
Genus
Latitude of event
Longitude of event
Nathaniel B. Palmer
NBP08-05
NBP08-05-DR27
NBP08-05-DR34
NBP08-05-DR35
NBP08-05-DR36
NBP08-05-DR38
NBP08-05-DR40
NBP08-05-TB04
NBP11-03
NBP11-03-DH07
NBP11-03-DH11
NBP11-03-DH112
NBP11-03-DH113
NBP11-03-DH117
NBP11-03-DH120
NBP11-03-DH14
NBP11-03-DH15
NBP11-03-DH16
NBP11-03-DH19
NBP11-03-DH74
NBP11-03-DH75
pH
productivity
Antarctic
Southern Ocean
The Antarctic
Antarc*
Sea ice
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.924088
https://doi.org/10.1594/PANGAEA.924088
Description
Summary:The Antarctic Cold Reversal (ACR; 14.7 to 13 ka) phase of the last deglaciation saw a pause in the rise of atmospheric pCO2 and Antarctic temperature, contrasted with warming in the North. Mechanisms associated with interhemispheric heat transfer have been proposed to explain features of this event, but the response of marine biota and the carbon cycle are debated. The Southern Ocean is a key site of deep-water exchange with the atmosphere, hence deglacial changes in nutrient cycling, circulation, and productivity in this region may have global impact. Here we present a new perspective on the sequence of events in the deglacial Southern Ocean, that includes multi-faunal benthic assemblage (foraminifera and cold-water corals) and geochemical data (Ba/Ca, 14C, δ11B) from the Drake Passage. Our records feature anomalies during peak ACR conditions indicative of circulation, biogeochemistry, and regional ecosystem perturbations. Within this cold episode, peak abundances of thick-walled benthic foraminifera and cold-water corals are observed at shallow depths in the sub-Antarctic (~300 m), while coral populations at greater depths and further south diminished. Geochemical data indicate that habitat shifts were associated with enhanced primary productivity in the sub-Antarctic, a more stratified water column, and poorly oxygenated bottom water. These results are consistent with northward migration of primary production in response to Antarctic cooling and widespread biotic turnover across the Southern Ocean. We suggest that expanding sea ice, suppressed ventilation, and shifting centres of upwelling drove changes in planktic and benthic ecology, and were collectively instrumental in halting CO2 rise in the mid-deglaciation.

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