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Main Authors: Abbott, April N, Haley, Brian A, McManus, James
Format: Dataset Open Access
Language:en
Published: PANGAEA 2016
Subjects:
Online Access:https://doi.org/10.1594/PANGAEA.877377
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author Abbott, April N
Haley, Brian A
McManus, James
author_facet Abbott, April N
Haley, Brian A
McManus, James
collection Datos científicos de ciencias marinas y ambientales
contents The ability to reconstruct past ocean currents is essential for determining ocean circulation's role in global heat transport and climate change. Our understanding of the relationship between circulation and climate in the past allows us to predict the impact of future climate-driven circulation changes. One proposed tracer of past ocean circulation is the neodymium isotope composition (epsilon-Nd) of ancient water masses. However, ambiguities in what governs the epsilon-Nd distribution in the modern ocean hamper interpretations of this tracer. Here we present epsilon-Nd values for marine pore fluids, sediments, and the overlying water column for three sites in the North Pacific. We find that ocean bottom water epsilon-Nd (epsilon-NdBW) in the northeast Pacific lies between the value expected for the water mass (-3.3) and the measured epsilon-Nd of sediment pore fluid (epsilon-NdPW; -1.8). Moreover, epsilon-NdPW resembles the epsilon-Nd of the sediment. Combined, these findings are consistent with recent assessments that sediment pore fluids may be a major source of rare earth elements to the ocean and suggest that the benthic flux of Nd from pore fluids exerts the primary control over the deep ocean distribution of epsilon-Nd.
format Dataset Open Access
id pangaea_https___doi_org_10_1594_PANGAEA_877377
institution PANGAEA
language en
publishDate 2016
publisher PANGAEA
record_format pangaea
spellingShingle Neodymium elemental and isotopic composition of Oregon, USA margin sediments
Abbott, April N
Haley, Brian A
McManus, James

The ability to reconstruct past ocean currents is essential for determining ocean circulation's role in global heat transport and climate change. Our understanding of the relationship between circulation and climate in the past allows us to predict the impact of future climate-driven circulation changes. One proposed tracer of past ocean circulation is the neodymium isotope composition (epsilon-Nd) of ancient water masses. However, ambiguities in what governs the epsilon-Nd distribution in the modern ocean hamper interpretations of this tracer. Here we present epsilon-Nd values for marine pore fluids, sediments, and the overlying water column for three sites in the North Pacific. We find that ocean bottom water epsilon-Nd (epsilon-NdBW) in the northeast Pacific lies between the value expected for the water mass (-3.3) and the measured epsilon-Nd of sediment pore fluid (epsilon-NdPW; -1.8). Moreover, epsilon-NdPW resembles the epsilon-Nd of the sediment. Combined, these findings are consistent with recent assessments that sediment pore fluids may be a major source of rare earth elements to the ocean and suggest that the benthic flux of Nd from pore fluids exerts the primary control over the deep ocean distribution of epsilon-Nd.
title Neodymium elemental and isotopic composition of Oregon, USA margin sediments
topic
url https://doi.org/10.1594/PANGAEA.877377