The role of deep ocean circulation in setting glacial climates
The glacial cycles of the Pleistocene involve changes in the circulation of the deep ocean in important ways. This review seeks to establish what were the robust patterns of deep-sea water mass changes and how they might have influenced important parts of the last glacial cycle. After a brief review...
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American Geophysical Union
2013
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ftcaltechauth:oai:authors.library.caltech.edu:kyxhq-7wz91 2024-09-15T17:46:33+00:00 The role of deep ocean circulation in setting glacial climates Adkins, Jess F. 2013-09 https://doi.org/10.1002/palo.20046 unknown American Geophysical Union https://doi.org/10.1002/palo.20046 oai:authors.library.caltech.edu:kyxhq-7wz91 eprintid:42331 resolverid:CaltechAUTHORS:20131108-091133838 info:eu-repo/semantics/openAccess Other Paleoceanography, 28(3), 539-561, (2013-09) review deep circulation tracers info:eu-repo/semantics/article 2013 ftcaltechauth https://doi.org/10.1002/palo.20046 2024-08-06T15:35:05Z The glacial cycles of the Pleistocene involve changes in the circulation of the deep ocean in important ways. This review seeks to establish what were the robust patterns of deep-sea water mass changes and how they might have influenced important parts of the last glacial cycle. After a brief review of how tracers in the modern ocean can be used to understand the distribution of water masses, I examine the data for biogeochemical, circulation rate, and conservative tracers during glacial climates. Some of the robust results from the literature of the last 30 years include: a shoaled version of northern source deep water in the Atlantic, expanded southern source water in the abyss and deep ocean, salt (rather than heat) stratification of the last glacial maximum (LGM) deep-sea, and several lines of evidence for slower overturning circulation in the southern deep cell. We combine these observations into a new idea for how the ocean-atmosphere system moves from interglacial to glacial periods across a single cycle. By virtue of its influence on the melting of land-based ice around Antarctica, cooling North Atlantic Deep Water (NADW) leads to a cold and salty version of Antarctic Bottom Water (AABW). This previously underappreciated feedback can lead to a more stratified deep ocean that operates as a more effective carbon trap than the modern, helping to lower atmospheric CO_2 and providing a mechanism for the deep ocean to synchronize the hemispheres in a positive feedback that drives the system to further cooling. © 2013 American Geophysical Union. Received 2 January 2013; revised 1 August 2013; accepted 16 August 2013; published 19 September 2013. This work has greatly benefited from conversations with many people over the years. Ed Boyle and Danny Sigman have taught me much of what I know about the carbonate system, though any mistakes about CO_2 feedbacks in this paper are mine alone. A sabbatical in the CNRS lab at Gif-sur-Yvette provided the time and intellectual space for the initial idea about feedbacks ... Article in Journal/Newspaper Antarc* Antarctic Antarctica NADW North Atlantic Deep Water North Atlantic Caltech Authors (California Institute of Technology) Paleoceanography 28 3 539 561 |
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review deep circulation tracers |
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review deep circulation tracers Adkins, Jess F. The role of deep ocean circulation in setting glacial climates |
topic_facet |
review deep circulation tracers |
description |
The glacial cycles of the Pleistocene involve changes in the circulation of the deep ocean in important ways. This review seeks to establish what were the robust patterns of deep-sea water mass changes and how they might have influenced important parts of the last glacial cycle. After a brief review of how tracers in the modern ocean can be used to understand the distribution of water masses, I examine the data for biogeochemical, circulation rate, and conservative tracers during glacial climates. Some of the robust results from the literature of the last 30 years include: a shoaled version of northern source deep water in the Atlantic, expanded southern source water in the abyss and deep ocean, salt (rather than heat) stratification of the last glacial maximum (LGM) deep-sea, and several lines of evidence for slower overturning circulation in the southern deep cell. We combine these observations into a new idea for how the ocean-atmosphere system moves from interglacial to glacial periods across a single cycle. By virtue of its influence on the melting of land-based ice around Antarctica, cooling North Atlantic Deep Water (NADW) leads to a cold and salty version of Antarctic Bottom Water (AABW). This previously underappreciated feedback can lead to a more stratified deep ocean that operates as a more effective carbon trap than the modern, helping to lower atmospheric CO_2 and providing a mechanism for the deep ocean to synchronize the hemispheres in a positive feedback that drives the system to further cooling. © 2013 American Geophysical Union. Received 2 January 2013; revised 1 August 2013; accepted 16 August 2013; published 19 September 2013. This work has greatly benefited from conversations with many people over the years. Ed Boyle and Danny Sigman have taught me much of what I know about the carbonate system, though any mistakes about CO_2 feedbacks in this paper are mine alone. A sabbatical in the CNRS lab at Gif-sur-Yvette provided the time and intellectual space for the initial idea about feedbacks ... |
format |
Article in Journal/Newspaper |
author |
Adkins, Jess F. |
author_facet |
Adkins, Jess F. |
author_sort |
Adkins, Jess F. |
title |
The role of deep ocean circulation in setting glacial climates |
title_short |
The role of deep ocean circulation in setting glacial climates |
title_full |
The role of deep ocean circulation in setting glacial climates |
title_fullStr |
The role of deep ocean circulation in setting glacial climates |
title_full_unstemmed |
The role of deep ocean circulation in setting glacial climates |
title_sort |
role of deep ocean circulation in setting glacial climates |
publisher |
American Geophysical Union |
publishDate |
2013 |
url |
https://doi.org/10.1002/palo.20046 |
genre |
Antarc* Antarctic Antarctica NADW North Atlantic Deep Water North Atlantic |
genre_facet |
Antarc* Antarctic Antarctica NADW North Atlantic Deep Water North Atlantic |
op_source |
Paleoceanography, 28(3), 539-561, (2013-09) |
op_relation |
https://doi.org/10.1002/palo.20046 oai:authors.library.caltech.edu:kyxhq-7wz91 eprintid:42331 resolverid:CaltechAUTHORS:20131108-091133838 |
op_rights |
info:eu-repo/semantics/openAccess Other |
op_doi |
https://doi.org/10.1002/palo.20046 |
container_title |
Paleoceanography |
container_volume |
28 |
container_issue |
3 |
container_start_page |
539 |
op_container_end_page |
561 |
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1810494808060329984 |