(Appendix) Th, U and Pa chemistry of North Atlantic deep-sea sediments

The Atlantic Meridional Overturning Circulation (AMOC) is a key feature of the climate system. However, its role during climate change is still poorly constrained particularly during an Interglacial to Glacial climate transition and the associated global cooling. We present here the first reconstruc...

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Bibliographic Details
Main Authors: Guihou, Abel, Pichat, Sylvain, Govin, Aline, Nave, Silvia Osorio, Michel, Elisabeth, Duplessy, Jean-Claude, Telouk, Philippe, Labeyrie, Laurent D
Format: Dataset
Language:English
Published: PANGAEA 2011
Subjects:
AGE
Azores
CALYPSO
Calypso Corer
DEPTH
sediment/rock
Elevation of event
Event label
IMAGES I
Latitude of event
Le SuroƮt
Longitude of event
Marion Dufresne (1995)
MD101
MD952037
MD95-2037
Multi-collector inductively coupled plasma mass spectrometer (MC-ICP-MS)
North Atlantic
Opal
biogenic silica
standard deviation
PALEOCINAT
PC
Piston corer
Protactinium-231
Protactinium-231/Thorium-230 excess
decay-corrected
SU90-03
SU90-08
Thorium-230
Thorium-232
Uranium-238
Ice Sheet
north atlantic current
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.816053
https://doi.org/10.1594/PANGAEA.816053
Description
Summary:The Atlantic Meridional Overturning Circulation (AMOC) is a key feature of the climate system. However, its role during climate change is still poorly constrained particularly during an Interglacial to Glacial climate transition and the associated global cooling. We present here the first reconstruction of the evolution of the vertical structure of the rate of the AMOC from the Last Interglaciation to the subsequent glaciation (128,000-60,000 years ago) based on sedimentary (231Pa/230Th) records. We show a deep AMOC during the interglacial warmth Marine Isotope Stage (MIS) 5.5 and a shallower glacial one during glacial MIS 4. The change between these two patterns occurred mostly during the glacial inception, i.e. the transition from MIS 5.5 to MIS 5.4. Our data show that AMOC was enhanced during this latter transition as a consequence of a large increase of the overturning rate of the Intermediate Waters, above 2500 m. We suggest that this AMOC pattern required a reinforced Gulf Stream-North Atlantic Current system that ultimately supported ice-sheet growth by providing heat and moisture to the Northern high latitudes. From MIS 5.4 to MIS 5.1, the AMOC was broadly continuous below 2000 m and supported periods of ice-sheet growth. As a result, a glacial AMOC is triggered at the beginning of MIS 4 due to the extension of ice-sheet and the subsequent reorganization of deep-water formation. This study highlights the role of intermediate waters as a major player during climate change.

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