The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific

The Southern Ocean is widely recognized as a potential cause of the lower atmospheric concentration of CO 2 during ice ages, but the mechanism is debated. Focusing on the Southern Ocean surface, we review biogeochemical paleoproxy data and carbon cycle concepts that together favor the view that both...

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Main Authors: Sigman, D.M., Fripiat, F., Studer, A.S., Martínez-Garcia, A., Hain, M.P., Ai, X., Wang, X., Ren, H., Haug, G.H.
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Antarctic
Southern Ocean
The Antarctic
Pacific
Antarc*
North Atlantic
Subarctic
Online Access:https://www.vliz.be/imisdocs/publications/361225.pdf
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record_format openpolar
spelling ftvliz:oai:oma.vliz.be:337328 2023-05-15T13:53:33+02:00 The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific Sigman, D.M. Fripiat, F. Studer, A.S. Martínez-Garcia, A. Hain, M.P. Ai, X. Wang, X. Ren, H. Haug, G.H. 2021 application/pdf https://www.vliz.be/imisdocs/publications/361225.pdf en eng info:eu-repo/semantics/altIdentifier/wos/000616643800001 https://www.vliz.be/imisdocs/publications/361225.pdf info:eu-repo/semantics/openAccess %3Ci%3EQuat.+Sci.+Rev.+254%3C%2Fi%3E%3A+106732.+%3Ca+href%3D%22https%3A%2F%2Fhdl.handle.net%2F10.1016%2Fj.quascirev.2020.106732%22+target%3D%22_blank%22%3Ehttps%3A%2F%2Fhdl.handle.net%2F10.1016%2Fj.quascirev.2020.106732%3C%2Fa%3E info:eu-repo/semantics/article info:eu-repo/semantics/publishedVersion 2021 ftvliz 2022-05-01T11:54:07Z The Southern Ocean is widely recognized as a potential cause of the lower atmospheric concentration of CO 2 during ice ages, but the mechanism is debated. Focusing on the Southern Ocean surface, we review biogeochemical paleoproxy data and carbon cycle concepts that together favor the view that both the Antarctic and Subantarctic Zones (AZ and SAZ) of the Southern Ocean played roles in lowering ice age CO 2 levels. In the SAZ, the data indicate dust-driven iron fertilization of phytoplankton growth during peak ice age conditions. In the ice age AZ, the area-normalized exchange of water between the surface and subsurface appears to have been reduced, a state that we summarize as “isolation” of the AZ surface. Under most scenarios, this change would have stemmed the leak of biologically stored CO 2 that occurs in the AZ today. SAZ iron fertilization during the last ice age fits with our understanding of ocean processes as gleaned from modern field studies and experiments; indeed, this hypothesis was proposed prior to evidentiary support. In contrast, AZ surface isolation is neither intuitive nor spontaneously generated in climate model simulations of the last ice age. In a more prospective component of this review, the suggested causes for AZ surface isolation are considered in light of the subarctic North Pacific (SNP), where the paleoproxies of productivity and nutrient consumption indicate similar upper ocean biogeochemical changes over glacial cycles, although with different timings at deglaciation. Among the proposed initiators of glacial AZ surface isolation, a single mechanism is sought that can explain the changes in both the AZ and the SNP. The analysis favors a weakening and/or equatorward shift in the upwelling associated with the westerly winds, occurring in both hemispheres. This view is controversial, especially for the SNP, where there is evidence of enhanced upper water column ventilation during the last ice age. We offer an interpretation that may explain key aspects of the AZ and SNP observations. In both regions, with a weakening in westerly wind-driven upwelling, nutrients may have been “mined out” of the upper water column, possibly accompanied by a poleward “slumping” of isopycnals. In the AZ, this would have encouraged declines in both the nutrient content and the formation rate of new deep water, each of which would have contributed to the lowering of atmospheric CO 2 . Through several effects, the reduction in AZ upwelling may have invigorated the upwelling of deep water into the low latitude pycnocline, roughly maintaining the pycnocline’s supply of water and nutrients so as to (1) support the high productivity of the glacial SAZ and (2) balance the removal of water from the pycnocline by the formation of Glacial North Atlantic Intermediate Water. The proposed return route from the deep ocean to the surface resembles that of Broecker’s (1991) “global ocean conveyor,” but applying to the ice age as opposed to the modern ocean. Article in Journal/Newspaper Antarc* Antarctic North Atlantic Southern Ocean Subarctic Flanders Marine Institute (VLIZ): Open Marine Archive (OMA) Antarctic Southern Ocean The Antarctic Pacific
institution Open Polar
collection Flanders Marine Institute (VLIZ): Open Marine Archive (OMA)
op_collection_id ftvliz
language English
description The Southern Ocean is widely recognized as a potential cause of the lower atmospheric concentration of CO 2 during ice ages, but the mechanism is debated. Focusing on the Southern Ocean surface, we review biogeochemical paleoproxy data and carbon cycle concepts that together favor the view that both the Antarctic and Subantarctic Zones (AZ and SAZ) of the Southern Ocean played roles in lowering ice age CO 2 levels. In the SAZ, the data indicate dust-driven iron fertilization of phytoplankton growth during peak ice age conditions. In the ice age AZ, the area-normalized exchange of water between the surface and subsurface appears to have been reduced, a state that we summarize as “isolation” of the AZ surface. Under most scenarios, this change would have stemmed the leak of biologically stored CO 2 that occurs in the AZ today. SAZ iron fertilization during the last ice age fits with our understanding of ocean processes as gleaned from modern field studies and experiments; indeed, this hypothesis was proposed prior to evidentiary support. In contrast, AZ surface isolation is neither intuitive nor spontaneously generated in climate model simulations of the last ice age. In a more prospective component of this review, the suggested causes for AZ surface isolation are considered in light of the subarctic North Pacific (SNP), where the paleoproxies of productivity and nutrient consumption indicate similar upper ocean biogeochemical changes over glacial cycles, although with different timings at deglaciation. Among the proposed initiators of glacial AZ surface isolation, a single mechanism is sought that can explain the changes in both the AZ and the SNP. The analysis favors a weakening and/or equatorward shift in the upwelling associated with the westerly winds, occurring in both hemispheres. This view is controversial, especially for the SNP, where there is evidence of enhanced upper water column ventilation during the last ice age. We offer an interpretation that may explain key aspects of the AZ and SNP observations. In both regions, with a weakening in westerly wind-driven upwelling, nutrients may have been “mined out” of the upper water column, possibly accompanied by a poleward “slumping” of isopycnals. In the AZ, this would have encouraged declines in both the nutrient content and the formation rate of new deep water, each of which would have contributed to the lowering of atmospheric CO 2 . Through several effects, the reduction in AZ upwelling may have invigorated the upwelling of deep water into the low latitude pycnocline, roughly maintaining the pycnocline’s supply of water and nutrients so as to (1) support the high productivity of the glacial SAZ and (2) balance the removal of water from the pycnocline by the formation of Glacial North Atlantic Intermediate Water. The proposed return route from the deep ocean to the surface resembles that of Broecker’s (1991) “global ocean conveyor,” but applying to the ice age as opposed to the modern ocean.
format Article in Journal/Newspaper
author Sigman, D.M.
Fripiat, F.
Studer, A.S.
Martínez-Garcia, A.
Hain, M.P.
Ai, X.
Wang, X.
Ren, H.
Haug, G.H.
spellingShingle Sigman, D.M.
Fripiat, F.
Studer, A.S.
Martínez-Garcia, A.
Hain, M.P.
Ai, X.
Wang, X.
Ren, H.
Haug, G.H.
The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
author_facet Sigman, D.M.
Fripiat, F.
Studer, A.S.
Martínez-Garcia, A.
Hain, M.P.
Ai, X.
Wang, X.
Ren, H.
Haug, G.H.
author_sort Sigman, D.M.
title The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
title_short The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
title_full The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
title_fullStr The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
title_full_unstemmed The Southern Ocean during the ice ages: a review of the Antarctic surface isolation hypothesis, with comparison to the North Pacific
title_sort southern ocean during the ice ages: a review of the antarctic surface isolation hypothesis, with comparison to the north pacific
publishDate 2021
url https://www.vliz.be/imisdocs/publications/361225.pdf
geographic Antarctic
Southern Ocean
The Antarctic
Pacific
geographic_facet Antarctic
Southern Ocean
The Antarctic
Pacific
genre Antarc*
Antarctic
North Atlantic
Southern Ocean
Subarctic
genre_facet Antarc*
Antarctic
North Atlantic
Southern Ocean
Subarctic
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op_relation info:eu-repo/semantics/altIdentifier/wos/000616643800001
https://www.vliz.be/imisdocs/publications/361225.pdf
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