Observed eddy-internal wave interactions in the Southern Ocean
Date
2020
Authors
Cusack, J.S.
Brearley, J. Alexander
Garabato, Albert C. Naveira
Smeed, David A.
Polzin, Kurt L.
Velzeboer, Nick
Shakespeare, Callum
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Volume Title
Publisher
American Meteorological Society
Abstract
The physical mechanisms that remove energy from the Southern Ocean’s vigorous mesoscale eddy field are
not well understood. One proposed mechanism is direct energy transfer to the internal wave field in the ocean
interior, via eddy-induced straining and shearing of preexisting internal waves. The magnitude, vertical structure, and
temporal variability of the rate of energy transfer between eddies and internal waves is quantified from a 14-month
deployment of a mooring cluster in the Scotia Sea. Velocity and buoyancy observations are decomposed into wave
and eddy components, and the energy transfer is estimated using the Reynolds-averaged energy equation. We find
that eddies gain energy from the internal wave field at a rate of 22.2 6 0.6 mW m22
, integrated from the bottom to
566 m below the surface. This result can be decomposed into a positive (eddy to wave) component, equal to 0.2 6
0.1 mW m22
, driven by horizontal straining of internal waves, and a negative (wave to eddy) component, equal
to 22.5 6 0.6 mW m22
, driven by vertical shearing of the wave spectrum. Temporal variability of the transfer rate is
much greater than the mean value. Close to topography, large energy transfers are associated with low-frequency
buoyancy fluxes, the underpinning physics of which do not conform to linear wave dynamics and are thereby in need
of further research. Our work suggests that eddy–internal wave interactions may play a significant role in the energy
balance of the Southern Ocean mesoscale eddy and internal wave fields.
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Journal of Physical Oceanography
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Journal article
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