Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age

Ocean ventilation is the process that transports water and climatically important trace gases such as carbon dioxide from the surface mixed layer into the ocean interior. Quantifying the dominant source regions and time scales remains a major challenge in oceanography. A mathematically rigorous appr...

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Bibliographic Details
Main Authors: Khatiwala, S, Primeau, F, Holzer, M
Format: Article in Journal/Newspaper
Language:unknown
Published: eScholarship, University of California 2012
Subjects:
Geochemistry & Geophysics
Physical Sciences
Earth Sciences
Southern Ocean
Pacific
North Atlantic
Online Access:https://escholarship.org/uc/item/8jq8c83r
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spelling ftcdlib:oai:escholarship.org/ark:/13030/qt8jq8c83r 2023-05-15T17:32:39+02:00 Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age Khatiwala, S Primeau, F Holzer, M 116 - 125 2012-04-01 application/pdf https://escholarship.org/uc/item/8jq8c83r unknown eScholarship, University of California qt8jq8c83r https://escholarship.org/uc/item/8jq8c83r CC-BY CC-BY Earth and Planetary Science Letters, vol 325-326 Geochemistry & Geophysics Physical Sciences Earth Sciences article 2012 ftcdlib 2020-01-24T23:54:08Z Ocean ventilation is the process that transports water and climatically important trace gases such as carbon dioxide from the surface mixed layer into the ocean interior. Quantifying the dominant source regions and time scales remains a major challenge in oceanography. A mathematically rigorous approach, that accounts for the multiplicity of transport pathways and transit times characteristic of an eddy-diffusive flow such as the ocean, is to quantify ventilation in terms of a probability distribution that partitions fluid parcels according to the time and location of their last surface contact. Here, we use globally gridded radiocarbon data in combination with other transient (CFCs) and hydrographic (temperature, salinity, phosphate, and oxygen) tracer data to estimate the joint distribution of age and surface origin of deep ocean waters. Our results show that ~. 40% and 26% of the global ocean was last in contact with the Southern Ocean and North Atlantic, respectively. Some 80% of the global deep ocean below 1500. m is ventilated from these high latitude regions. However, contrary to the classical description of the deep ocean as a roughly equal mixture of "northern" and "southern" source waters, we find a significantly higher contribution from the Southern Ocean relative to the North Atlantic. We estimate the mean transit time from the surface to the deep North Pacific at 1360±350. y, intermediate between two widely used radiocarbon-based estimates. To reconcile our estimate of the ideal mean age with ventilation age estimates based on radiocarbon, we apply the estimated distribution function to construct a 3-dimensional distribution of the water mass fraction-weighted surface "initial" radiocarbon concentration that can serve as an accurate reservoir age. Radiocarbon ages corrected for this initial reservoir age are found to be in good agreement (within 5%) with our ideal age estimate, demonstrating that it is essential to take into account the spatially variable surface radiocarbon field when computing ventilation ages using radiocarbon. A wide spectrum of ages contributes to the mean age, providing evidence for the fundamentally eddy-diffusive nature of the large-scale general circulation of the ocean. © 2012 Elsevier B.V. Article in Journal/Newspaper North Atlantic Southern Ocean University of California: eScholarship Southern Ocean Pacific
institution Open Polar
collection University of California: eScholarship
op_collection_id ftcdlib
language unknown
topic Geochemistry & Geophysics
Physical Sciences
Earth Sciences
spellingShingle Geochemistry & Geophysics
Physical Sciences
Earth Sciences
Khatiwala, S
Primeau, F
Holzer, M
Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
topic_facet Geochemistry & Geophysics
Physical Sciences
Earth Sciences
description Ocean ventilation is the process that transports water and climatically important trace gases such as carbon dioxide from the surface mixed layer into the ocean interior. Quantifying the dominant source regions and time scales remains a major challenge in oceanography. A mathematically rigorous approach, that accounts for the multiplicity of transport pathways and transit times characteristic of an eddy-diffusive flow such as the ocean, is to quantify ventilation in terms of a probability distribution that partitions fluid parcels according to the time and location of their last surface contact. Here, we use globally gridded radiocarbon data in combination with other transient (CFCs) and hydrographic (temperature, salinity, phosphate, and oxygen) tracer data to estimate the joint distribution of age and surface origin of deep ocean waters. Our results show that ~. 40% and 26% of the global ocean was last in contact with the Southern Ocean and North Atlantic, respectively. Some 80% of the global deep ocean below 1500. m is ventilated from these high latitude regions. However, contrary to the classical description of the deep ocean as a roughly equal mixture of "northern" and "southern" source waters, we find a significantly higher contribution from the Southern Ocean relative to the North Atlantic. We estimate the mean transit time from the surface to the deep North Pacific at 1360±350. y, intermediate between two widely used radiocarbon-based estimates. To reconcile our estimate of the ideal mean age with ventilation age estimates based on radiocarbon, we apply the estimated distribution function to construct a 3-dimensional distribution of the water mass fraction-weighted surface "initial" radiocarbon concentration that can serve as an accurate reservoir age. Radiocarbon ages corrected for this initial reservoir age are found to be in good agreement (within 5%) with our ideal age estimate, demonstrating that it is essential to take into account the spatially variable surface radiocarbon field when computing ventilation ages using radiocarbon. A wide spectrum of ages contributes to the mean age, providing evidence for the fundamentally eddy-diffusive nature of the large-scale general circulation of the ocean. © 2012 Elsevier B.V.
format Article in Journal/Newspaper
author Khatiwala, S
Primeau, F
Holzer, M
author_facet Khatiwala, S
Primeau, F
Holzer, M
author_sort Khatiwala, S
title Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
title_short Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
title_full Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
title_fullStr Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
title_full_unstemmed Ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
title_sort ventilation of the deep ocean constrained with tracer observations and implications for radiocarbon estimates of ideal mean age
publisher eScholarship, University of California
publishDate 2012
url https://escholarship.org/uc/item/8jq8c83r
op_coverage 116 - 125
geographic Southern Ocean
Pacific
geographic_facet Southern Ocean
Pacific
genre North Atlantic
Southern Ocean
genre_facet North Atlantic
Southern Ocean
op_source Earth and Planetary Science Letters, vol 325-326
op_relation qt8jq8c83r
https://escholarship.org/uc/item/8jq8c83r
op_rights CC-BY
op_rightsnorm CC-BY
_version_ 1766130857462988800

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