Intensified bottom water formation in the southwest Pacific during the early Eocene greenhouse-Insights from neodymium isotopes

I. Penalver-Clavel; S. J. Batenburg; R. Sutherland; E. Dallanave; G. R. Dickens; T. Westerhold; C. Agnini; L. Alegret

doi:10.1130/G52974.1

Intensified bottom water formation in the southwest Pacific during the early Eocene greenhouse-Insights from neodymium isotopes

I. Penalver-Clavel, S. J. Batenburg, R. Sutherland, E. Dallanave, G. R. Dickens, T. Westerhold, C. Agnini, L. Alegret

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The Early Eocene Climatic Optimum (EECO; 53–49 Ma), when Earth experienced peak Cenozoic surface temperatures, provides a test case for how ocean circulation might operate under enhanced greenhouse climate conditions. The topic lies at the forefront of current geoscience, but evolution of ocean circulation during this climatic extreme remains unresolved, critically at high southern latitudes. We present the first highly resolved record of neodymium isotope values at high southern latitudes (International Ocean Discovery Program Site U1510), a proxy that tracks ocean bottom water. A prominent negative shift in seawater ε_Nd(t) in the Tasman Sea in the middle of the EECO was likely driven by a new bottom water mass, with the Antarctic sector of the Pacific Ocean being the obvious source. Comparison with low-resolution studies from other sites in the Tasman Sea suggests that a new intermediate water source flowed farther away from the Tasman Sea and into the Pacific during the EECO. Intensification of dense water formation at high southern latitudes during peak greenhouse warmth is surprising but consistent with recent findings that highlight the complexity of global thermohaline circulation.

Original language	English
Pages (from-to)	524-528
Number of pages	5
Journal	Geology
Volume	53
Issue number	6
Early online date	27 Mar 2025
DOIs	https://doi.org/10.1130/G52974.1
Publication status	Published - 2025

Bibliographical note

Publisher Copyright:
© (2025), (Geological Society of America). All rights reserved.

Funding

Funders	Funder number
MCIN/AEI
ERDF A way of making Europe
Fondo Europeo de Desarrollo Regional [FEDER]
Union Europea [UE]
Spanish Ministry of Science and Innovation	PRE2020-092638
Deutsche Forschungsgemeinschaft	465492305
National Recovery and Resilience Plan
Not added	PID2019-105537RB-I00
Not added	PID2023-149894OB-I00

Keywords

Climate
Ma
Nd
Ocean circulation
Paleocene
Temperature-gradients
Thermal maximum

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

Access to Document

10.1130/G52974.1Licence: CC BY

g52974.1Final published version, 1.06 MBLicence: CC BY

Cite this

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abstract = "The Early Eocene Climatic Optimum (EECO; 53–49 Ma), when Earth experienced peak Cenozoic surface temperatures, provides a test case for how ocean circulation might operate under enhanced greenhouse climate conditions. The topic lies at the forefront of current geoscience, but evolution of ocean circulation during this climatic extreme remains unresolved, critically at high southern latitudes. We present the first highly resolved record of neodymium isotope values at high southern latitudes (International Ocean Discovery Program Site U1510), a proxy that tracks ocean bottom water. A prominent negative shift in seawater εNd(t) in the Tasman Sea in the middle of the EECO was likely driven by a new bottom water mass, with the Antarctic sector of the Pacific Ocean being the obvious source. Comparison with low-resolution studies from other sites in the Tasman Sea suggests that a new intermediate water source flowed farther away from the Tasman Sea and into the Pacific during the EECO. Intensification of dense water formation at high southern latitudes during peak greenhouse warmth is surprising but consistent with recent findings that highlight the complexity of global thermohaline circulation.",

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AU - Dallanave, E.

AU - Dickens, G. R.

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AU - Agnini, C.

AU - Alegret, L.

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AB - The Early Eocene Climatic Optimum (EECO; 53–49 Ma), when Earth experienced peak Cenozoic surface temperatures, provides a test case for how ocean circulation might operate under enhanced greenhouse climate conditions. The topic lies at the forefront of current geoscience, but evolution of ocean circulation during this climatic extreme remains unresolved, critically at high southern latitudes. We present the first highly resolved record of neodymium isotope values at high southern latitudes (International Ocean Discovery Program Site U1510), a proxy that tracks ocean bottom water. A prominent negative shift in seawater εNd(t) in the Tasman Sea in the middle of the EECO was likely driven by a new bottom water mass, with the Antarctic sector of the Pacific Ocean being the obvious source. Comparison with low-resolution studies from other sites in the Tasman Sea suggests that a new intermediate water source flowed farther away from the Tasman Sea and into the Pacific during the EECO. Intensification of dense water formation at high southern latitudes during peak greenhouse warmth is surprising but consistent with recent findings that highlight the complexity of global thermohaline circulation.

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Intensified bottom water formation in the southwest Pacific during the early Eocene greenhouse-Insights from neodymium isotopes

Abstract

Bibliographical note

Funding

Keywords

UN SDGs

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