Neodymium isotopes, planktic and benthic stable carbon and oxygen isotopes, sortable silt and percentage CaCO3 from sediment core TT1811-34GGC, SE Indian Ocean

Neodymium isotope data measured on mixed species of uncleaned planktic foraminifera, planktic (G. bulloides) and benthic (C. kullenbergi) stable carbon and oxygen isotopes, mean sortable silt size fraction measurements and CaCO3 contents of sediments from giant gravity core TT1811-34GGC, located wit...

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Bibliographic Details
Main Authors: Williams, Thomas John, Sikes, Elisabeth L, Martin, Ellen E, Starr, Aidan, Umling, Natalie E, Glaubke, Ryan
Format: Dataset
Language:English
Published: PANGAEA 2021
Subjects:
AGE
Calcium carbonate
Cibicidoides kullenbergi
δ18O
Depth
bottom/max
sediment/rock
top/min
GGC
Giant gravity corer
Globigerina bulloides
Grain size
mean
Indian Ocean
Neodymium isotope
sortable silt
Southern Ocean
Stable isotope
Standard error
TT1811-34GGC
ε-Neodymium
error
Antarctic
Indian
Pacific
Antarc*
North Atlantic
Sea ice
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.932953
https://doi.org/10.1594/PANGAEA.932953
Description
Summary:Neodymium isotope data measured on mixed species of uncleaned planktic foraminifera, planktic (G. bulloides) and benthic (C. kullenbergi) stable carbon and oxygen isotopes, mean sortable silt size fraction measurements and CaCO3 contents of sediments from giant gravity core TT1811-34GGC, located within the SE Indian/Southern Ocean. Data span the last glacial cycle, from 118,000 years B.P. to the late Holocene. The chain of events surrounding the initiation and intensification of the last glacial cycle remain relatively poorly understood. In particular, the role of Southern Ocean paleocirculation changes is poorly constrained, in part, owing to a paucity of sedimentary records from this region. In this study we present multiproxy data – including neodymium isotope and sortable silt measurements – for paleocirculation changes within the deep (3167 m water depth) Indian sector of the Southern Ocean from a new sediment core, TT1811-34GGC (41.718°S, 80.163°E). We find a tight coupling between circulation changes, Antarctic climate, and atmospheric CO2 concentrations throughout the last 118,000 years, even during the initial stages of glacial inception of Marine Isotope Stage (MIS) 5.4 to 5.1. We find that periods of cooling correspond to reductions in the entrainment of North Atlantic-sourced waters within the deep Southern Ocean, as evidenced by more radiogenic neodymium isotope values of deep water bathing our core site. Cooling also corresponds to generally slower bottom water flow speeds, as indicated by finer sortable silt size fractions. A reduction in entrainment of North-Atlantic sourced waters occurred during MIS 5.4-5.1, when Atlantic circulation was strong, suggesting a Southern hemisphere control on paleocirculation changes at that time. We hypothesize that expanded Southern Ocean sea-ice during MIS 5.4 increased the density of the deep Southern Ocean, reducing the ability of Atlantic-sourced waters to mix into the deep Southern Ocean. This led to an expanded contribution of Pacific Deep Water within the ...

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