Rates and mechanisms of turbulent dissipation and mixing in the Southern Ocean: Results from the Diapycnal and Isopycnal Mixing Experiment in the Southern Ocean (DIMES)
Rates and mechanisms of turbulent dissipation and mixing in the Southern Ocean: Results from the Diapycnal and Isopycnal Mixing Experiment in the Southern Ocean (DIMES)
The spatial distribution of turbulent dissipation rates and internal wave field characteristics is analysed across two contrasting regimes of the Antarctic Circumpolar Current (ACC), using microstructure and finestructure data collected as part of the Diapycnal and Isopycnal Mixing Experiment in the Southern Ocean (DIMES). Mid-depth turbulent dissipation rates are found to increase from O (1×10-10 W kg-1) in the Southeast Pacific to O (1×10-9 W kg-1) in the Scotia Sea, typically reaching 3×10-9 W kg-1 within a kilometre of the seabed. Enhanced levels of turbulent mixing are associated with strong near-bottom flows, rough topography, and regions where the internal wave field is found to have enhanced energy, a less-inertial frequency content and a dominance of upward-propagating energy. These results strongly suggest that bottom-generated internal waves play a major role in determining the spatial distribution of turbulent dissipation in the ACC. The energy flux associated with the bottom internal wave generation process is calculated using wave radiation theory, and found to vary between 0.8 mWm-2 in the Southeast Pacific and 14 m W m-2 in the Scotia Sea. Typically, 10-30% of this energy is found to dissipate within 1 km of the seabed. Comparison between turbulent dissipation rates inferred from finestructure parameterizations and microstructure-derived estimates suggests a significant departure from wave-wave interaction physics in the near-field of wave generation sites.
Turbulent dissipation, Internal Wave, Antarctic Circumpolar Current
2774-2792
Sheen, K.L.
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Brearley, J. A.
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Naveira Garabato, A.C.
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Waterman, S.
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Smeed, D.A.
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Ledwell, J.R.
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Meredith, M.P.
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St. Laurent, L.
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Thurnherr, A.M.
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Toole, J.M.
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Watson, A.J.
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June 2013
Sheen, K.L.
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Brearley, J. A.
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Naveira Garabato, A.C.
97c0e923-f076-4b38-b89b-938e11cea7a6
Waterman, S.
3283414a-1681-4328-9cb0-9b5209fb5b45
Smeed, D.A.
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Ledwell, J.R.
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Meredith, M.P.
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St. Laurent, L.
745fc400-a419-4bce-859b-89e63b0cd80d
Thurnherr, A.M.
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Toole, J.M.
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Watson, A.J.
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Sheen, K.L., Brearley, J. A., Naveira Garabato, A.C., Waterman, S., Smeed, D.A., Ledwell, J.R., Meredith, M.P., St. Laurent, L., Thurnherr, A.M., Toole, J.M. and Watson, A.J.
(2013)
Rates and mechanisms of turbulent dissipation and mixing in the Southern Ocean: Results from the Diapycnal and Isopycnal Mixing Experiment in the Southern Ocean (DIMES).
Journal of Geophysical Research: Oceans, 118 (6), .
(doi:10.1002/jgrc.20217).
Abstract
The spatial distribution of turbulent dissipation rates and internal wave field characteristics is analysed across two contrasting regimes of the Antarctic Circumpolar Current (ACC), using microstructure and finestructure data collected as part of the Diapycnal and Isopycnal Mixing Experiment in the Southern Ocean (DIMES). Mid-depth turbulent dissipation rates are found to increase from O (1×10-10 W kg-1) in the Southeast Pacific to O (1×10-9 W kg-1) in the Scotia Sea, typically reaching 3×10-9 W kg-1 within a kilometre of the seabed. Enhanced levels of turbulent mixing are associated with strong near-bottom flows, rough topography, and regions where the internal wave field is found to have enhanced energy, a less-inertial frequency content and a dominance of upward-propagating energy. These results strongly suggest that bottom-generated internal waves play a major role in determining the spatial distribution of turbulent dissipation in the ACC. The energy flux associated with the bottom internal wave generation process is calculated using wave radiation theory, and found to vary between 0.8 mWm-2 in the Southeast Pacific and 14 m W m-2 in the Scotia Sea. Typically, 10-30% of this energy is found to dissipate within 1 km of the seabed. Comparison between turbulent dissipation rates inferred from finestructure parameterizations and microstructure-derived estimates suggests a significant departure from wave-wave interaction physics in the near-field of wave generation sites.
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jgrc20217_Sheen.pdf
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Accepted/In Press date: May 2013
Published date: June 2013
Keywords:
Turbulent dissipation, Internal Wave, Antarctic Circumpolar Current
Organisations:
Marine Systems Modelling, Physical Oceanography
Identifiers
Local EPrints ID: 352457
URI: http://eprints.soton.ac.uk/id/eprint/352457
ISSN: 2169-9275
PURE UUID: 6c7aa186-ddb3-4d50-81cf-f7e6386b2af4
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Date deposited: 14 May 2013 11:05
Last modified: 15 Mar 2024 03:24
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Contributors
Author:
K.L. Sheen
Author:
J. A. Brearley
Author:
S. Waterman
Author:
D.A. Smeed
Author:
J.R. Ledwell
Author:
M.P. Meredith
Author:
L. St. Laurent
Author:
A.M. Thurnherr
Author:
J.M. Toole
Author:
A.J. Watson
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