70 research outputs found
The wind-driven overturning circulation of the World Ocean
International audienceThe wind driven aspects of the meridional overturning circulation of the world ocean and the Conveyor Belt is studied making use of a simple analytical model. The model consists of three reduced gravity layers with an inviscid Sverdrupian interior and a western boundary layer. The net north-south exchange is made possible by setting appropriate western boundary conditions, so that most of the transport is confined to the western boundary layer, while the interior is the Sverdrupian solution to the wind stress. The flow across the equator is made possible by the change of potential vorticity by the Rayleigh friction in the western boundary layer, which is sufficient to permit water and the Conveyor Belt to cross the equator. The cross-equatorial flow is driven by a weak meridional pressure gradient in opposite direction in the two layers on the equator at the western boundary. The model is applied to the World Ocean with a realistic wind stress. The amplitude of the Conveyor Belt is set by the northward Ekman transport in the Southern Ocean and the outcropping latitude of the NADW. It is in this way possible to set the amount of NADW that is pumped up from the deep ocean and driven northward by the wind and converted in the surface layer into less dense water by choosing the outcropping latitude and the depth of the layers at the western boundary. The model has proved to be able to simulate many of the key features of the Conveyor Belt and the meridional overturning cells of the World Ocean. This despite that there is no deep ocan mixing and that the water mass conversions in the this model are made at the surface
Simulating the emergence of the organizing structures of work
This article is a first step toward a visualization and classification system for studying dynamic organizing structures of work. As a first step toward this research objective, this study brings together two active projects. One called "relatonics" studies work group formation and is primarily empirical and inductive. The other called "Human Interaction Dynamics (HID)" imports concepts, relationships and modeling from complexity science and is therefore primarily theoretical and deductive. The vision is to use social media, data gathering, and process simulation technologies to rigorously describe, systematically visualize, and validly model the complex dynamics of work processes of different types. This work will serve as a means to classify, study and improve the performance of work systems. We describe our progress to data and suggest further research
Difference in Particle Transport Between Two Coastal Areas in the Baltic Sea Investigated with High-Resolution Trajectory Modeling
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Freshwater transport in the coupled ocean-atmosphere system: a passive ocean
Conservation of water demands that meridional ocean and atmosphere freshwater transports (FWT) are of equal magnitude but opposite in direction. This suggests that the atmospheric FWT and its associated latent heat (LH) transport could be thought of as a \textquotedblleft coupled ocean/atmosphere mode\textquotedblright. But what is the true nature of this coupling? Is the ocean passive or active?
Here we analyze a series of simulations with a coupled ocean-atmosphere-sea ice model employing highly idealized geometries but with markedly different coupled climates and patterns of ocean circulation. Exploiting streamfunctions in specific humidity coordinates for the atmosphere and salt coordinates for the ocean to represent FWT in their respective medium, we find that atmospheric FWT/LH transport is essentially independent of the ocean state. Ocean circulation and salinity distribution adjust to achieve a return freshwater pathway demanded of them by the atmosphere. So, although ocean and atmosphere FWTs are indeed coupled by mass conservation, the ocean is a passive component acting as a reservoir of freshwater
Time-dependent response of a zonally averaged ocean–atmosphere–sea ice model to Milankovitch forcing
Author Posting. © The Author(s), 2010. This is the author's version of the work. It is posted here by permission of Springer-Verlag for personal use, not for redistribution. The definitive version was published in Climate Dynamics 6 (2010): 763-779, doi:10.1007/s00382-010-0790-6.An ocean-atmosphere-sea ice model is developed to explore the time-dependent
response of climate to Milankovitch forcing for the time interval 5-3 Myr BP. The ocean
component is a zonally averaged model of the circulation in five basins (Arctic, Atlantic,
Indian, Pacific, and Southern Oceans). The atmospheric component is a one-dimensional
(latitudinal) energy balance model, and the sea-ice component is a thermodynamic model.
Two numerical experiments are conducted. The first experiment does not include sea ice
and the Arctic Ocean; the second experiment does. Results from the two experiments are
used to investigate (i) the response of annual mean surface air and ocean temperatures to
Milankovitch forcing, and (ii) the role of sea ice in this response.
In both experiments, the response of air temperature is dominated by obliquity cycles
at most latitudes. On the other hand, the response of ocean temperature varies with latitude
and depth. Deep water formed between 45°N-65°N in the Atlantic Ocean mainly responds
to precession. In contrast, deep water formed south of 60°S responds to obliquity when sea
ice is not included. Sea ice acts as a time-integrator of summer insolation changes such that
annual mean sea-ice conditions mainly respond to obliquity. Thus, in the presence of sea
ice, air temperature changes over the sea ice are amplified, and temperature changes in deep
water of southern origin are suppressed since water below sea ice is kept near the freezing
point.This work was supported by an NSERC Discovery
Grant awarded to L.A.M. We also thank GEC3 for a Network Grant
Vertical mixing in the ocean
The thermohaline circulation of the ocean results primarily from downwelling at sites in the Nordic and Labrador Seas and upwelling throughout the rest of the ocean. The latter is often described as being due to breaking internal waves. Here we reconcile the difference between theoretical and observed estimates of vertical mixing in the deep ocean by presenting a revised view of the thermohaline circulation, which allows for additional upwelling in the Southern Ocean and the separation of the North Atlantic Deep Water cell from the Antarctic Bottom Water cell. The changes also mean that much less wind and tidal energy needs to be dissipated in the deep ocean than was originally thought
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