Modeling the water masses of the Atlantic Ocean at the Last Glacial Maximum

Paul, André; Schäfer-Neth, Christian

doi:10.1029/2002pa000783

Cited by 110 publications

(143 citation statements)

References 92 publications

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“…Alternatively, longer integration periods for each iteration would be required. Paleo-data from regions where Antarctic Bottom Water is formed may become more important on longer timescales, because the relative densities of the North Atlantic and Southern Ocean source waters are expected to play a larger role for the meridional overturning circulation in the steady-state problem (e.g., Paul and Schäfer-Neth, 2003;Weber et al, 2007). However, in our experiments the adjustment of the AMOC was very fast; it typically occurred in the first 10 years of a 20-year experiment.…”

Section: Discussionmentioning

confidence: 53%

Can sparse proxy data constrain the strength of the Atlantic meridional overturning circulation?

2014

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Abstract. In a feasibility study, the potential of proxy data for the temperature and salinity during the Last Glacial Maximum (LGM, about 19 000 to 23 000 years before present) in constraining the strength of the Atlantic meridional overturning circulation (AMOC) with a general ocean circulation model was explored. The proxy data were simulated by drawing data from four different model simulations at the ocean sediment core locations of the Multiproxy Approach for the Reconstruction of the Glacial Ocean surface (MARGO) project, and perturbing these data with realistic noise estimates. The results suggest that our method has the potential to provide estimates of the past strength of the AMOC even from sparse data, but in general, paleo-seasurface temperature data without additional prior knowledge about the ocean state during the LGM is not adequate to constrain the model. On the one hand, additional data in the deep-ocean and salinity data are shown to be highly important in estimating the LGM circulation. On the other hand, increasing the amount of surface data alone does not appear to be enough for better estimates. Finally, better initial guesses to start the state estimation procedure would greatly improve the performance of the method. Indeed, with a sufficiently good first guess, just the sea-surface temperature data from the MARGO project promise to be sufficient for reliable estimates of the strength of the AMOC.

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Section: Discussionmentioning

confidence: 53%

Can sparse proxy data constrain the strength of the Atlantic meridional overturning circulation?

2014

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“…The main difference between the LGM experiments discussed here and those presented in Paul and Schäfer-Neth (2003) is the use of the corebased as opposed to the isoline-based temperature reconstruction (see our accompanying publication Schäfer-Neth and Paul this volume). With respect to δ 18 O w , Experiments GA-GC are not true simulations of the LGM, but important sensitivity experi-ments that isolate the effect of only the circulation changes on the distribution at depth, without changes of the surface hydrology.…”

Section: Methodsmentioning

confidence: 99%

“…In contrast to our previous study (Paul and Schäfer-Neth 2003), we now use as model forcing the SST fields obtained with the most reliable gridding technique (i.e. variogram analysis and kriging) applied to the proxy-data at the core locations, to simulate the glacial-to-interglacial changes in the hydrology and circulation of the Atlantic Ocean.…”

Section: Modeling the Paleo-oceanmentioning

confidence: 99%

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The Atlantic Ocean at the Last Glacial Maximum: 2. Reconstructing the Current Systems with a Global Ocean Model

Paul

Schäfer-Neth

2003

The South Atlantic in the Late Quaternary

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Abstract:We use a global ocean general circulation model (OGCM) with low vertical diffusion and isopycnal mixing to simulate the circulation in the Atlantic Ocean at present-day and the Last Glacial Maximum (LGM). The OGCM includes δ 18 O as a passive tracer. Regarding the LGM sea-surface boundary conditions, the temperature is based on the GLAMAP reconstruction, the salinity is estimated from the available δ 18 O data, and the wind-stress is derived from the output of an atmospheric general circulation model. Our focus is on changes in the upper-ocean hydrology, the large-scale horizontal circulation and the δ 18 O distribution. In a series of LGM experiments with a step-wise increase of the sea-surface salinity anomaly in the Weddell Sea, the ventilated thermocline was colder than today by 2-3°C in the North Atlantic Ocean and, in the experiment with the largest anomaly (1.0 beyond the global anomaly), by 4-5°C in the South Atlantic Ocean; furthermore it was generally shallower. As the meridional density gradient grew, the Antarctic Circumpolar Current strengthened and its northern boundary approached Cape of Good Hope. At the same time the southward penetration of the Agulhas Current was reduced, and less thermocline-to-intermediate water slipped from the Indian Ocean along the southern rim of the African continent into the South Atlantic Ocean; the 'Agulhas leakage' was diminished by up to 60% with respect to its modern value, such that the cold water route became the dominant path for North Atlantic Deep Water (NADW) renewal. It can be speculated that the simulated intensification of the Benguela Current and the enhancement of NADW upwelling in the Southern Ocean might reduce the import of silicate into the Benguela System, which could possibly resolve the 'Walvis Opal Paradox'. Although δ 18 O w was restored to the same surface values and could only reflect changes in advection and diffusion, the resulting δ 18 O c distribution came close to reconstructions based on fossil shells of benthic foraminifera.

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“…In addition, changes of greenhouse gas concentrations (Berger et al, 1998;Shackleton, 2000), sea-surface temperatures (CLIMAP, 1984;Paul and Schaefer-Neth, 2003;Kageyama et al, 2006;Colleoni et al, 2010) and vegetation cover (Claussen et al, 2006;Colleoni et al, 2009) need to be considered. Furthermore, features associated with ice-sheet dynamics and the atmospheric state remain sources of uncertainty.…”

Section: Introductionmentioning

confidence: 99%

Interactions between topographically and thermally forced stationary waves: implications for ice-sheet evolution

Liakka

2012

Tellus A: Dynamic Meteorology and Oceanography

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A B S T R A C TThis study examines mutual interactions between stationary waves and ice sheets using a dry atmospheric primitive-equation model coupled to a three-dimensional thermomechanical ice-sheet model. The emphasis is on how non-linear interactions between thermal and topographical forcing of the stationary waves influence the ice-sheet evolution by changing the ablation. Simulations are conducted in which a small ice cap, on an idealised Northern Hemisphere continent, evolves to an equilibrium continental-scale ice sheet. In the absence of stationary waves, the equilibrium ice sheet arrives at symmetric shape with a zonal equatorward margin. In isolation, the topographically induced stationary waves have essentially no impact on the equilibrium features of the ice sheet. The reason is that the temperature anomalies are located far from the equatorward ice margin. When forcing due to thermal cooling is added to the topographical forcing, thermally induced perturbation winds amplify the topographically induced stationary-wave response, which that serves to increase both the equatorward extent and the volume of the ice sheet. Roughly, a 10% increase in the ice volume is reported here. Hence, the present study suggests that the topographically induced stationary-wave response can be substantially enhanced by the high albedo of ice sheets.

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Modeling the water masses of the Atlantic Ocean at the Last Glacial Maximum

Cited by 110 publications

References 92 publications

Can sparse proxy data constrain the strength of the Atlantic meridional overturning circulation?

Can sparse proxy data constrain the strength of the Atlantic meridional overturning circulation?

The Atlantic Ocean at the Last Glacial Maximum: 2. Reconstructing the Current Systems with a Global Ocean Model

Interactions between topographically and thermally forced stationary waves: implications for ice-sheet evolution

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