How momentum advection schemes influence current-topography interactions at eddy permitting resolution

Recent studies have shown that the use of an enstrophy-and-energy-conserving momentum advection scheme substantially reduces widespread biases of mean currents in the global 1/4° DRAKKAR model. This paper investigates the origin of these improvements. A series of sensitivity simulations with differe...

Full description

Saved in:
Bibliographic Details
Published in:Ocean modelling (Oxford) 2009, Vol.29 (1), p.1-14
Main Authors: Le Sommer, Julien, Penduff, Thierry, Theetten, Sébastien, Madec, Gurvan, Barnier, Bernard
Format: Article
Language:English
Subjects:
Earth Sciences
Engineering Sciences
Fluid mechanics
Fluids mechanics
Marine
Mechanics
Momentum advection schemes
Oceanography
Physics
Sciences of the Universe
Topography
z-level models
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Recent studies have shown that the use of an enstrophy-and-energy-conserving momentum advection scheme substantially reduces widespread biases of mean currents in the global 1/4° DRAKKAR model. This paper investigates the origin of these improvements. A series of sensitivity simulations with different momentum advection schemes is performed with the North Atlantic 1/4° DRAKKAR model. Three second order momentum advection schemes conserving, respectively, enstrophy ( ens), energy ( efx) and both quantities ( een) are tested and their impact on the model solution are compared. The mean kinetic energy vertical profile is found to change up to 10% depending on the chosen scheme. This sensitivity is maximum in bottom layers. The analysis of the vorticity tendency due to horizontal momentum advection reveals that the three schemes differ mostly in bottom layers as well. The average magnitude of this term is enhanced with the efx scheme and reduced with the een scheme. These differences are found to be consistent with the instantaneous tendency of each scheme. In addition, we show that the differences between the schemes are related to the grid-scale irregularity of the velocity field. Both the grid scale irregularity and the differences between the schemes are found to be enhanced in bottom layers. We conclude that the model solution depends crucially on the ability of the momentum advection scheme to handle under-resolved flows close to the bottom topography. This work emphasizes the critical influence of topography in eddy-active regions on mean circulation features such as the position of the North-Atlantic current or the Gulf Stream separation.
ISSN:1463-5003
1463-5011
DOI:10.1016/j.ocemod.2008.11.007