Quantifying the roles of ocean circulation and biogeochemistry in governing ocean carbon-13 and atmospheric carbon dioxide at the last glacial maximum

Tagliabue, Alessandro; Bopp, Laurent; Roche, Didier M.; Bouttes, Nathaëlle; Dutay, Jean-Claude; Alkama, Ramdane; Kageyama, Masa; Michel, Élisabeth; Paillard, Didier

doi:10.5194/cp-5-695-2009

Cited by 102 publications

(152 citation statements)

References 40 publications

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“…This supports previous model studies, which have identified GHG variations as an important contributor to Pleistocene glacial cycles (Gallée et al, 1992;Yoshimori et al, 2001;Ganopolski and Calov, 2011;AbeOuchi et al, 2013). And the results emphasize how important it is to identify the mechanisms responsible for the orbitalscale modulation of atmospheric CO 2 concentrations (Kohfeld and Ridgwell, 2009;Tagliabue et al, 2009;Chikamoto et al, 2012;Menviel et al, 2012;Brovkin et al, 2012).…”

Section: Discussionmentioning

confidence: 99%

“…While the changes of earth's orbital and tilt parameters and the resulting shortwave radiative forcing at the top of the atmosphere are well understood, the carbon cycle feedbacks that led to the reconstructed atmospheric CO 2 changes are subject to ongoing research (Kohfeld and Ridgwell, 2009;Tagliabue et al, 2009;Brovkin et al, 2012;Chikamoto et al, 2012;Menviel et al, 2012). It was demonstrated, however, that the carbon cycle feedbacks played an important role during the last deglaciation and the Quaternary Period (last ∼ 2.6 million years), amplifying glacial-interglacial cycles (Gallée et al, 1992;Yoshimori et al, 2001;Ganopolski and Calov, 2011;Abe-Ouchi et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

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Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects

et al. 2014

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Abstract.One hundred thousand years of ice sheet buildup came to a rapid end ∼ 25-10 thousand years before present (ka BP), when ice sheets receded quickly and multi-proxy reconstructed global mean surface temperatures rose by ∼ 3-5 • C. It still remains unresolved whether insolation changes due to variations of earth's tilt and orbit were sufficient to terminate glacial conditions. Using a coupled three-dimensional climate-ice sheet model, we simulate the climate and Northern Hemisphere ice sheet evolution from 78 ka BP to 0 ka BP in good agreement with sea level and ice topography reconstructions. Based on this simulation and a series of deglacial sensitivity experiments with individually varying orbital parameters and prescribed CO 2 , we find that enhanced calving led to a slowdown of ice sheet growth as early as ∼ 8 ka prior to the Last Glacial Maximum (LGM). The glacial termination was then initiated by enhanced ablation due to increasing obliquity and precession, in agreement with the Milankovitch theory. However, our results also support the notion that the ∼ 100 ppmv rise of atmospheric CO 2 after ∼ 18 ka BP was a key contributor to the deglaciation. Without it, the presentday ice volume would be comparable to that of the LGM and global mean temperatures would be about 3 • C lower than today. We further demonstrate that neither orbital forcing nor rising CO 2 concentrations alone were sufficient to complete the deglaciation.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects

et al. 2014

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“…Observations indicate that the deep glacial ocean was much saltier and colder than today (Adkins et al, 2002), thus more stratified in the abyss. Such a deep stratification has important impacts on the ocean's circulation and carbon cycle, as pointed out by climate models of different complexities (Toggweiler, 1999;Paillard and Parrenin, 2004;Köhler et al, 2005a;Bouttes et al, 2009;Tagliabue et al, 2009). In particular, deep stratification is required to reconcile δ 13 C Tagliabue et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

“…Such a deep stratification has important impacts on the ocean's circulation and carbon cycle, as pointed out by climate models of different complexities (Toggweiler, 1999;Paillard and Parrenin, 2004;Köhler et al, 2005a;Bouttes et al, 2009;Tagliabue et al, 2009). In particular, deep stratification is required to reconcile δ 13 C Tagliabue et al, 2009). However, only box models could significantly reduce atmospheric CO 2 when prescribing a reduced Southern ventilation (Watson and Garabato, 2005).…”

Section: Introductionmentioning

confidence: 99%

Impact of brine-induced stratification on the glacial carbon cycle

2010

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Abstract. During the cold period of the Last Glacial Maximum (LGM, about 21 000 years ago) atmospheric CO 2 was around 190 ppm, much lower than the pre-industrial concentration of 280 ppm. The causes of this substantial drop remain partially unresolved, despite intense research. Understanding the origin of reduced atmospheric CO 2 during glacial times is crucial to comprehend the evolution of the different carbon reservoirs within the Earth system (atmosphere, terrestrial biosphere and ocean). In this context, the ocean is believed to play a major role as it can store large amounts of carbon, especially in the abyss, which is a carbon reservoir that is thought to have expanded during glacial times. To create this larger reservoir, one possible mechanism is to produce very dense glacial waters, thereby stratifying the deep ocean and reducing the carbon exchange between the deep and upper ocean. The existence of such very dense waters has been inferred in the LGM deep Atlantic from sediment pore water salinity and δ 18 O inferred temperature. Based on these observations, we study the impact of a brine mechanism on the glacial carbon cycle. This mechanism relies on the formation and rapid sinking of brines, very salty water released during sea ice formation, which brings salty dense water down to the bottom of the ocean. It provides two major features: a direct link from the surface to the deep ocean along with an efficient way of setting a strong stratification. We show with the CLIMBER-2 carbon-climate model that such a brine mechanism can account for a significant decrease in atmospheric CO 2 and contribute to the glacial-interglacial change. This mechanism can be amplified by low vertical diffusion resulting from the brine-induced stratification. The modeled glacial disCorrespondence to: N. Bouttes (nathaelle.bouttes@lsce.ipsl.fr) tribution of oceanic δ 13 C as well as the deep ocean salinity are substantially improved and better agree with reconstructions from sediment cores, suggesting that such a mechanism could have played an important role during glacial times.

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“…Since the pioneer work of Joussaume et al (1984), many models are being equipped with δ 18 O, δD and also δ 17 O water isotopes, including land surface models Henderson-Sellers et al, 2006), regional atmospheric models (Sturm et al, 2010) general circulation models , for the coupled ocean-atmosphere GISS model; Lee et al, 2012, for NCAR CAM2;Tindall et al, 2009, for HadCM3;Risi et al, 2010, for LMDZ4;Werner et al, 2011, for ECHAM5wiso;Yoshimura et al, 2011, for IsoGSM;Dee et al, 2015) and intermediate-complexity climate models (Roche and Caley, 2013, for iLOVECLIM). Similarly, carbon stable isotopes are also implemented in a growing number of land surface and ocean components (e.g., Tagliabue et al, 2009;Menviel et al, 2012;Sternberg et al, 2009). These new functionalities of climate models open the possibility to directly comparing the proxies measured in natural archives with model output, with the double interest of improving the understanding of proxy records, and model evaluation.…”

Section: Introductionmentioning

confidence: 99%

Water and carbon stable isotope records from natural archives: a new database and interactive online platform for data browsing, visualizing and downloading

et al. 2016

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Abstract. Past climate is an important benchmark to assess the ability of climate models to simulate key processes and feedbacks. Numerous proxy records exist for stable isotopes of water and/or carbon, which are also implemented inside the components of a growing number of Earth system model. Model-data comparisons can help to constrain the uncertainties associated with transfer functions. This motivates the need of producing a comprehensive compilation of different proxy sources. We have put together a global database of proxy records of oxygen (δ 18 O), hydrogen (δD) and carbon (δ 13 C) stable isotopes from different archives: ocean and lake sediments, corals, ice cores, speleothems and tree-ring cellulose. Source records were obtained from the georeferenced open access PANGAEA and NOAA libraries, complemented by additional data obtained from a literature survey. About 3000 source records were screened for chronological information and temporal resolution of proxy records. Altogether, this database consists of hundreds of dated δ 18 O, δ 13 C and δD records in a standardized simple text format, complemented with a metadata Excel catalog. A quality control flag was implemented to describe age markers and inform on chronological uncertainty. This compilation effort highlights the need to homogenize and structure the format of datasets and chronological information as well as enhance the distribution of published datasets that are currently highly fragmented and scattered. We also provide an online portal based on the records included in this database with an intuitive and interactive platform (http://climateproxiesfinder.ipsl.fr/), allowing one to easily select, visualize and download subsets of the homogeneously formatted records that constitute this database, following a choice of search criteria, and to upload new datasets. In the last part, we illustrate the type of application allowed by our database by comparing several key periods highly investigated by the paleoclimate community.

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Quantifying the roles of ocean circulation and biogeochemistry in governing ocean carbon-13 and atmospheric carbon dioxide at the last glacial maximum

Cited by 102 publications

References 40 publications

Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects

Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects

Impact of brine-induced stratification on the glacial carbon cycle

Water and carbon stable isotope records from natural archives: a new database and interactive online platform for data browsing, visualizing and downloading

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Quantifying the roles of ocean circulation and biogeochemistry in governing ocean carbon-13 and atmospheric carbon dioxide at the last glacial maximum

Cited by 102 publications

References 40 publications

Deglacial ice sheet meltdown: orbital pacemaking and CO&lt;sub&gt;2&lt;/sub&gt; effects

Deglacial ice sheet meltdown: orbital pacemaking and CO&lt;sub&gt;2&lt;/sub&gt; effects

Impact of brine-induced stratification on the glacial carbon cycle

Water and carbon stable isotope records from natural archives: a new database and interactive online platform for data browsing, visualizing and downloading

Contact Info

Product

Resources

About

Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects

Deglacial ice sheet meltdown: orbital pacemaking and CO<sub>2</sub> effects