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Global energy dissipation rate of deep-ocean low frequency flows by quadratic bottom boundary layer drag: computations from current-meter data

Global energy dissipation rate of deep-ocean low frequency flows by quadratic bottom boundary layer drag: computations from current-meter data
Global energy dissipation rate of deep-ocean low frequency flows by quadratic bottom boundary layer drag: computations from current-meter data
The global energy dissipation rate of deep-ocean low-frequency flows by quadratic bottom boundary layer drag is estimated in three ways. First, an average over the dissipations computed from the near-bottom velocities recorded by 290 moored current meters is multiplied by the World Ocean area. Second, near-global maps of surface velocities derived from satellite altimetry data are used to estimate the bias due to the sparse spatial coverage of the moorings. Third, a relationship between bottom and surface flows, computed over the mooring locations, is used to estimate global maps of bottom flows from the surface data. All three methods suggest that at least 0.2 TW of the wind-power input into geostrophic flows is dissipated in deep water by quadratic bottom drag. Implications for the oceanic overturning circulation, and for oceanic mesoscale eddy dynamics, are briefly discussed.
0094-8276
L09606
Sen, Ayon
59af599f-deab-4c46-91ee-5d7233f5acad
Scott, Robert B.
f82756a5-f04c-41f1-a6c8-12574b9814cf
Arbic, Brian K.
297f49fc-6755-42f6-b6b2-6307bcd375a3
Sen, Ayon
59af599f-deab-4c46-91ee-5d7233f5acad
Scott, Robert B.
f82756a5-f04c-41f1-a6c8-12574b9814cf
Arbic, Brian K.
297f49fc-6755-42f6-b6b2-6307bcd375a3

Sen, Ayon, Scott, Robert B. and Arbic, Brian K. (2008) Global energy dissipation rate of deep-ocean low frequency flows by quadratic bottom boundary layer drag: computations from current-meter data. Geophysical Research Letters, 35, L09606. (doi:10.1029/2008GL033407).

Record type: Article

Abstract

The global energy dissipation rate of deep-ocean low-frequency flows by quadratic bottom boundary layer drag is estimated in three ways. First, an average over the dissipations computed from the near-bottom velocities recorded by 290 moored current meters is multiplied by the World Ocean area. Second, near-global maps of surface velocities derived from satellite altimetry data are used to estimate the bias due to the sparse spatial coverage of the moorings. Third, a relationship between bottom and surface flows, computed over the mooring locations, is used to estimate global maps of bottom flows from the surface data. All three methods suggest that at least 0.2 TW of the wind-power input into geostrophic flows is dissipated in deep water by quadratic bottom drag. Implications for the oceanic overturning circulation, and for oceanic mesoscale eddy dynamics, are briefly discussed.

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Published date: 2008
Organisations: National Oceanography Centre,Southampton

Identifiers

Local EPrints ID: 65651
URI: http://eprints.soton.ac.uk/id/eprint/65651
DOI: doi:10.1029/2008GL033407
ISSN: 0094-8276
PURE UUID: fdd5f634-d57d-48f1-9b3a-78867f49f894

Catalogue record

Date deposited: 03 Mar 2009
Last modified: 13 Mar 2024 17:47

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Contributors

Author: Ayon Sen
Author: Robert B. Scott
Author: Brian K. Arbic

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