Environmental change in the subtropics during the late middle Eocene greenhouse and global implications

[1] Oxygen isotope records from ODP Site 1052 (Blake Nose, subtropical North Atlantic Ocean) indicate significant short-term, high-amplitude variability (up to 1.4‰ in about 2500 to 4000 years) during the late middle Eocene (37.9–37.5 Ma). These variations reflect a combination of changes in sea sur...

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Bibliographic Details
Main Authors: Okafor, CU, Thomas, DJ, Wade, BS, Firth, J
Format: Article in Journal/Newspaper
Language:English
Published: AMER GEOPHYSICAL UNION 2009
Subjects:
Science & Technology
Physical Sciences
Geochemistry & Geophysics
Ocean Drilling Program
middle Eocene
paleoceanograpy
PALAEOCENE/EOCENE THERMAL MAXIMUM
SEA-SURFACE TEMPERATURES
WESTERN NORTH-ATLANTIC
PLANKTONIC-FORAMINIFERA
BLAKE NOSE
OCEAN CIRCULATION
STABLE-ISOTOPES
ARCTIC-OCEAN
ICE VOLUME
CLIMATE
Arctic
Arctic Ocean
Foraminifera*
North Atlantic
Planktonic foraminifera
Online Access:https://discovery.ucl.ac.uk/id/eprint/1400885/1/Wade_Okafor%20et%20al%202009.pdf
https://discovery.ucl.ac.uk/id/eprint/1400885/
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Summary:[1] Oxygen isotope records from ODP Site 1052 (Blake Nose, subtropical North Atlantic Ocean) indicate significant short-term, high-amplitude variability (up to 1.4‰ in about 2500 to 4000 years) during the late middle Eocene (37.9–37.5 Ma). These variations reflect a combination of changes in sea surface temperature and the oxygen isotope composition of the regional seawater. In order to independently evaluate the magnitude of SST changes at Blake Nose and better understand the nature of environmental change during the late middle Eocene, we present planktonic foraminiferal Mg/Ca data combined with δ18O data from the same samples. The calculated Mg/Ca paleotemperatures indicate a decrease in SSTs over the study interval from ∼33 to 28°C at the same time that previously published foraminiferal δ18Ocalcite values from the same samples also decrease. Thus, the δ18Ocalcite values must reflect a significant component of seawater δ18O change in order to reconcile the opposite paleotemperature trends reflected by both proxies. Calculated δ18Oseawater values decreased from ∼3‰ at 37.83 Ma to ∼2‰ at 37.6 Ma. The combined trends of the SST and δ18Oseawater cannot be explained by an increase of continental ice over this time interval. Instead, the data favor an overall weakening of the hydrological cycle as global climate transitioned from the greenhouse to icehouse.

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