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Routes to energy dissipation for geostrophic flows in the Southern Ocean
by
Nikurashin, Maxim
, Adcroft, Alistair
, Vallis, Geoffrey K.
in
704/106/829/2737
/ Boundary layers
/ Carbon dioxide
/ Earth Sciences
/ Earth System Sciences
/ Eddies
/ Energy dissipation
/ Energy transfer
/ Geochemistry
/ Geology
/ Geophysics/Geodesy
/ Internal waves
/ Kinetic energy
/ letter
/ Ocean circulation
/ Potential energy
/ Topography
/ Water circulation
/ Wind power
2013
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Routes to energy dissipation for geostrophic flows in the Southern Ocean
by
Nikurashin, Maxim
, Adcroft, Alistair
, Vallis, Geoffrey K.
in
704/106/829/2737
/ Boundary layers
/ Carbon dioxide
/ Earth Sciences
/ Earth System Sciences
/ Eddies
/ Energy dissipation
/ Energy transfer
/ Geochemistry
/ Geology
/ Geophysics/Geodesy
/ Internal waves
/ Kinetic energy
/ letter
/ Ocean circulation
/ Potential energy
/ Topography
/ Water circulation
/ Wind power
2013
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While trying to remove the title from your shelf something went wrong :( Kindly try again later!
Do you wish to request the book?
Routes to energy dissipation for geostrophic flows in the Southern Ocean
by
Nikurashin, Maxim
, Adcroft, Alistair
, Vallis, Geoffrey K.
in
704/106/829/2737
/ Boundary layers
/ Carbon dioxide
/ Earth Sciences
/ Earth System Sciences
/ Eddies
/ Energy dissipation
/ Energy transfer
/ Geochemistry
/ Geology
/ Geophysics/Geodesy
/ Internal waves
/ Kinetic energy
/ letter
/ Ocean circulation
/ Potential energy
/ Topography
/ Water circulation
/ Wind power
2013
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Routes to energy dissipation for geostrophic flows in the Southern Ocean
Journal Article
Routes to energy dissipation for geostrophic flows in the Southern Ocean
2013
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Overview
Wind power inputs at the surface ocean are dissipated through smaller-scale processes in the ocean interior and turbulent boundary layer. Simulations suggest that seafloor topography enhances turbulent mixing and energy dissipation in the ocean interior.
The ocean circulation is forced at a global scale by winds and fluxes of heat and fresh water. Kinetic energy is dissipated at much smaller scales in the turbulent boundary layers and in the ocean interior
1
,
2
, where turbulent mixing controls the transport and storage of tracers such as heat and carbon dioxide
3
,
4
. The primary site of wind power input is the Southern Ocean, where the westerly winds are aligned with the Antarctic Circumpolar Current
5
. The potential energy created here is converted into a vigorous geostrophic eddy field through baroclinic instabilities. The eddy energy can power mixing in the ocean interior
6
,
7
,
8
, but the mechanisms governing energy transfer to the dissipation scale are poorly constrained. Here we present simulations that simultaneously resolve meso- and submeso-scale motions as well as internal waves generated by topography in the Southern Ocean. In our simulations, more than 80% of the wind power input is converted from geostrophic eddies to smaller-scale motions in the abyssal ocean. The conversion is catalysed by rough, small-scale topography. The bulk of the energy is dissipated within the bottom 100 m of the ocean, but about 20% is radiated and dissipated away from topography in the ocean interior, where it can sustain turbulent mixing. We conclude that in the absence of rough topography, the turbulent mixing in the ocean interior would be diminished.
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