BakkerPepijnCEOASEvolutionDeep-Ocean.pdf

To investigate the dynamics of the Atlantic meridional overturning circulation (AMOC) on timescales longer than the observational records, model-data comparisons of past AMOC variability are imperative. However, this remains challenging because of dissimilarities between different proxy-based AMOC t...

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Main Authors: Bakker, Pepijn, Govin, Aline, Thornalley, David J. R., Roche, Didier M., Renssen, Hans
Language:unknown
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Online Access:https://ir.library.oregonstate.edu/concern/articles/bz60d181c
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spelling ftoregonstate:ir.library.oregonstate.edu:bz60d181c 2024-09-15T17:47:33+00:00 BakkerPepijnCEOASEvolutionDeep-Ocean.pdf Bakker, Pepijn Govin, Aline Thornalley, David J. R. Roche, Didier M. Renssen, Hans https://ir.library.oregonstate.edu/concern/articles/bz60d181c unknown https://ir.library.oregonstate.edu/concern/articles/bz60d181c Copyright Not Evaluated ftoregonstate 2024-07-22T18:06:04Z To investigate the dynamics of the Atlantic meridional overturning circulation (AMOC) on timescales longer than the observational records, model-data comparisons of past AMOC variability are imperative. However, this remains challenging because of dissimilarities between different proxy-based AMOC tracers and the difficulty of comparing these to model output. We present an iLOVECLIM simulation with tuned AMOC evolution and focus on AMOC tracers that are directly comparable to reconstructions: flow speeds and δ¹³C. We deduce their driving factors and show that they yield different but complementary information about AMOC changes. Simulated flow speed changes are only linked to AMOC changes in regions bathed by North Atlantic Deep Water; however, in those regions they do provide details on vertical migration and thickness changes of the water masses. Simulated δ¹³C changes in the North Atlantic Deep Water region are again related to AMOC changes. Yet in regions bathed by Antarctic Bottom Water or Antarctic Intermediate Water, the δ¹³C evolution is driven by Southern Hemisphere source water δ¹³C changes, while in the Nordic Seas and the two major overflow regions it is driven by Northern Hemisphere source water δ¹³C changes. This shows that AMOC changes are not necessarily recorded by δ¹³C and stresses the need for combining both tracers in paleoclimate studies. A preliminary model-data comparison for Last Interglacial flow speeds and δ¹³C changes in the Deep Western Boundary Current shows that this integrated approach is far from straightforward and currently inconclusive on the Last Interglacial AMOC evolution. Nonetheless, the approach yields potential for more direct and in-depth model-data comparisons of past AMOC changes. Keywords: Atlantic meridional overturning circulation, Paleoclimate modeling Other/Unknown Material Antarc* Antarctic Nordic Seas North Atlantic Deep Water North Atlantic ScholarsArchive@OSU (Oregon State University)
institution Open Polar
collection ScholarsArchive@OSU (Oregon State University)
op_collection_id ftoregonstate
language unknown
description To investigate the dynamics of the Atlantic meridional overturning circulation (AMOC) on timescales longer than the observational records, model-data comparisons of past AMOC variability are imperative. However, this remains challenging because of dissimilarities between different proxy-based AMOC tracers and the difficulty of comparing these to model output. We present an iLOVECLIM simulation with tuned AMOC evolution and focus on AMOC tracers that are directly comparable to reconstructions: flow speeds and δ¹³C. We deduce their driving factors and show that they yield different but complementary information about AMOC changes. Simulated flow speed changes are only linked to AMOC changes in regions bathed by North Atlantic Deep Water; however, in those regions they do provide details on vertical migration and thickness changes of the water masses. Simulated δ¹³C changes in the North Atlantic Deep Water region are again related to AMOC changes. Yet in regions bathed by Antarctic Bottom Water or Antarctic Intermediate Water, the δ¹³C evolution is driven by Southern Hemisphere source water δ¹³C changes, while in the Nordic Seas and the two major overflow regions it is driven by Northern Hemisphere source water δ¹³C changes. This shows that AMOC changes are not necessarily recorded by δ¹³C and stresses the need for combining both tracers in paleoclimate studies. A preliminary model-data comparison for Last Interglacial flow speeds and δ¹³C changes in the Deep Western Boundary Current shows that this integrated approach is far from straightforward and currently inconclusive on the Last Interglacial AMOC evolution. Nonetheless, the approach yields potential for more direct and in-depth model-data comparisons of past AMOC changes. Keywords: Atlantic meridional overturning circulation, Paleoclimate modeling
author Bakker, Pepijn
Govin, Aline
Thornalley, David J. R.
Roche, Didier M.
Renssen, Hans
spellingShingle Bakker, Pepijn
Govin, Aline
Thornalley, David J. R.
Roche, Didier M.
Renssen, Hans
BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
author_facet Bakker, Pepijn
Govin, Aline
Thornalley, David J. R.
Roche, Didier M.
Renssen, Hans
author_sort Bakker, Pepijn
title BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
title_short BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
title_full BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
title_fullStr BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
title_full_unstemmed BakkerPepijnCEOASEvolutionDeep-Ocean.pdf
title_sort bakkerpepijnceoasevolutiondeep-ocean.pdf
url https://ir.library.oregonstate.edu/concern/articles/bz60d181c
genre Antarc*
Antarctic
Nordic Seas
North Atlantic Deep Water
North Atlantic
genre_facet Antarc*
Antarctic
Nordic Seas
North Atlantic Deep Water
North Atlantic
op_relation https://ir.library.oregonstate.edu/concern/articles/bz60d181c
op_rights Copyright Not Evaluated
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