Impact of oceanic processes on the carbon cycle during the last termination

During the last termination (from ~18 000 years ago to ~9000 years ago), the climate significantly warmed and the ice sheets melted. Simultaneously, atmospheric CO 2 increased from ~190 ppm to ~260 ppm. Although this CO 2 rise plays an important role in the deglacial warming, the reasons for its evo...

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Published in:Climate of the Past
Main Authors: Bouttes, N., Paillard, D., Roche, D. M., Waelbroeck, C., Kageyama, M., Lourantou, A., Michel, E., Bopp, L.
Format: Text
Language:English
Published: 2018
Subjects:
Antarctic
Southern Ocean
The Antarctic
Antarc*
ice core
Ice Sheet
NADW
Sea ice
Online Access:https://doi.org/10.5194/cp-8-149-2012
https://cp.copernicus.org/articles/8/149/2012/
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spelling ftcopernicus:oai:publications.copernicus.org:cp11695 2023-05-15T13:36:36+02:00 Impact of oceanic processes on the carbon cycle during the last termination Bouttes, N. Paillard, D. Roche, D. M. Waelbroeck, C. Kageyama, M. Lourantou, A. Michel, E. Bopp, L. 2018-09-27 application/pdf https://doi.org/10.5194/cp-8-149-2012 https://cp.copernicus.org/articles/8/149/2012/ eng eng doi:10.5194/cp-8-149-2012 https://cp.copernicus.org/articles/8/149/2012/ eISSN: 1814-9332 Text 2018 ftcopernicus https://doi.org/10.5194/cp-8-149-2012 2020-07-20T16:25:55Z During the last termination (from ~18 000 years ago to ~9000 years ago), the climate significantly warmed and the ice sheets melted. Simultaneously, atmospheric CO 2 increased from ~190 ppm to ~260 ppm. Although this CO 2 rise plays an important role in the deglacial warming, the reasons for its evolution are difficult to explain. Only box models have been used to run transient simulations of this carbon cycle transition, but by forcing the model with data constrained scenarios of the evolution of temperature, sea level, sea ice, NADW formation, Southern Ocean vertical mixing and biological carbon pump. More complex models (including GCMs) have investigated some of these mechanisms but they have only been used to try and explain LGM versus present day steady-state climates. In this study we use a coupled climate-carbon model of intermediate complexity to explore the role of three oceanic processes in transient simulations: the sinking of brines, stratification-dependent diffusion and iron fertilization. Carbonate compensation is accounted for in these simulations. We show that neither iron fertilization nor the sinking of brines alone can account for the evolution of CO 2 , and that only the combination of the sinking of brines and interactive diffusion can simultaneously simulate the increase in deep Southern Ocean δ 13 C. The scenario that agrees best with the data takes into account all mechanisms and favours a rapid cessation of the sinking of brines around 18 000 years ago, when the Antarctic ice sheet extent was at its maximum. In this scenario, we make the hypothesis that sea ice formation was then shifted to the open ocean where the salty water is quickly mixed with fresher water, which prevents deep sinking of salty water and therefore breaks down the deep stratification and releases carbon from the abyss. Based on this scenario, it is possible to simulate both the amplitude and timing of the long-term CO 2 increase during the last termination in agreement with ice core data. The atmospheric δ 13 C appears to be highly sensitive to changes in the terrestrial biosphere, underlining the need to better constrain the vegetation evolution during the termination. Text Antarc* Antarctic ice core Ice Sheet NADW Sea ice Southern Ocean Copernicus Publications: E-Journals Antarctic Southern Ocean The Antarctic Climate of the Past 8 1 149 170
institution Open Polar
collection Copernicus Publications: E-Journals
op_collection_id ftcopernicus
language English
description During the last termination (from ~18 000 years ago to ~9000 years ago), the climate significantly warmed and the ice sheets melted. Simultaneously, atmospheric CO 2 increased from ~190 ppm to ~260 ppm. Although this CO 2 rise plays an important role in the deglacial warming, the reasons for its evolution are difficult to explain. Only box models have been used to run transient simulations of this carbon cycle transition, but by forcing the model with data constrained scenarios of the evolution of temperature, sea level, sea ice, NADW formation, Southern Ocean vertical mixing and biological carbon pump. More complex models (including GCMs) have investigated some of these mechanisms but they have only been used to try and explain LGM versus present day steady-state climates. In this study we use a coupled climate-carbon model of intermediate complexity to explore the role of three oceanic processes in transient simulations: the sinking of brines, stratification-dependent diffusion and iron fertilization. Carbonate compensation is accounted for in these simulations. We show that neither iron fertilization nor the sinking of brines alone can account for the evolution of CO 2 , and that only the combination of the sinking of brines and interactive diffusion can simultaneously simulate the increase in deep Southern Ocean δ 13 C. The scenario that agrees best with the data takes into account all mechanisms and favours a rapid cessation of the sinking of brines around 18 000 years ago, when the Antarctic ice sheet extent was at its maximum. In this scenario, we make the hypothesis that sea ice formation was then shifted to the open ocean where the salty water is quickly mixed with fresher water, which prevents deep sinking of salty water and therefore breaks down the deep stratification and releases carbon from the abyss. Based on this scenario, it is possible to simulate both the amplitude and timing of the long-term CO 2 increase during the last termination in agreement with ice core data. The atmospheric δ 13 C appears to be highly sensitive to changes in the terrestrial biosphere, underlining the need to better constrain the vegetation evolution during the termination.
format Text
author Bouttes, N.
Paillard, D.
Roche, D. M.
Waelbroeck, C.
Kageyama, M.
Lourantou, A.
Michel, E.
Bopp, L.
spellingShingle Bouttes, N.
Paillard, D.
Roche, D. M.
Waelbroeck, C.
Kageyama, M.
Lourantou, A.
Michel, E.
Bopp, L.
Impact of oceanic processes on the carbon cycle during the last termination
author_facet Bouttes, N.
Paillard, D.
Roche, D. M.
Waelbroeck, C.
Kageyama, M.
Lourantou, A.
Michel, E.
Bopp, L.
author_sort Bouttes, N.
title Impact of oceanic processes on the carbon cycle during the last termination
title_short Impact of oceanic processes on the carbon cycle during the last termination
title_full Impact of oceanic processes on the carbon cycle during the last termination
title_fullStr Impact of oceanic processes on the carbon cycle during the last termination
title_full_unstemmed Impact of oceanic processes on the carbon cycle during the last termination
title_sort impact of oceanic processes on the carbon cycle during the last termination
publishDate 2018
url https://doi.org/10.5194/cp-8-149-2012
https://cp.copernicus.org/articles/8/149/2012/
geographic Antarctic
Southern Ocean
The Antarctic
geographic_facet Antarctic
Southern Ocean
The Antarctic
genre Antarc*
Antarctic
ice core
Ice Sheet
NADW
Sea ice
Southern Ocean
genre_facet Antarc*
Antarctic
ice core
Ice Sheet
NADW
Sea ice
Southern Ocean
op_source eISSN: 1814-9332
op_relation doi:10.5194/cp-8-149-2012
https://cp.copernicus.org/articles/8/149/2012/
op_doi https://doi.org/10.5194/cp-8-149-2012
container_title Climate of the Past
container_volume 8
container_issue 1
container_start_page 149
op_container_end_page 170
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