Energetics of internal tides around the Kerguelen Plateau from modeling and altimetry
Identifieur interne : 006443 ( Main/Exploration ); précédent : 006442; suivant : 006444Energetics of internal tides around the Kerguelen Plateau from modeling and altimetry
Auteurs : Claire Maraldi [France] ; Florent Lyard [France] ; Laurent Testut [France] ; Richard Coleman [Australie]Source :
- Journal of Geophysical Research: Oceans [ 0148-0227 ] ; 2011-06.
Descripteurs français
- Wicri :
- topic : énergie marémotrice.
English descriptors
- KwdEn :
- Altimeter, Altimeter data, Altimeter track, Altimetry, Amplitude, Antarctic, Antarctic climate, Approximate wavelength, Baines, Baroclinic, Baroclinic mode, Baroclinic modes, Baroclinic tide generation, Baroclinic tides, Barotropic, Barotropic energy, Barotropic energy flux, Barotropic model, Barotropic response, Barotropic tide, Barotropic tide model, Barotropic tides, Bathymetric, Bathymetric gradient, Bathymetry, Bathymetry contours, Bottom friction dissipation, Deep ocean, Dissipation, Dissipation term, Egbert, Energetics, Energy flux, Energy transfer, First baroclinic mode, First baroclinic rossby radius, First mode, First mode baroclinic wave speed, Geophys, Global baroclinic tide model, Global ocean, Global scale, Gravitational acceleration, Harmonic analysis, Hawaii region, Hawaiian islands, Inclination angle, Internal tide, Internal tide energy, Internal tide generation, Internal tide generation process, Internal tide modes, Internal tides, Internal wave drag energy dissipation, Internal wave generation, Internal wave propagation rays, Internal waves, Kerguelen, Kerguelen islands, Kerguelen plateau, Laurent, Layer model, Lett, Llewellyn smith, Lyard, Maraldi, Mesoscale, Mesoscale activity, Mesoscale variability, Mitchum, Modeling, Node tide variability, Ocean tides, Oceanogr, Other studies, Parameterization, Parameterization term, Potential density profile, Residual signal, Right angles, Scotia ridge, Service hydrographique, Southern indian ocean, Strong bathymetric gradients, Surface height signals, Surface height signatures, Surface manifestation, Surface signal, Surface signature, Theoretical criterion, Tidal, Tidal component, Tidal constituents, Tidal ellipses, Tidal energy, Tidal period, Tide, Tierney, Water column, Wave drag dissipation, Wave number.
- Teeft :
- Altimeter, Altimeter data, Altimeter track, Altimetry, Amplitude, Antarctic, Antarctic climate, Approximate wavelength, Baines, Baroclinic, Baroclinic mode, Baroclinic modes, Baroclinic tide generation, Baroclinic tides, Barotropic, Barotropic energy, Barotropic energy flux, Barotropic model, Barotropic response, Barotropic tide, Barotropic tide model, Barotropic tides, Bathymetric, Bathymetric gradient, Bathymetry, Bathymetry contours, Bottom friction dissipation, Deep ocean, Dissipation, Dissipation term, Egbert, Energetics, Energy flux, Energy transfer, First baroclinic mode, First baroclinic rossby radius, First mode, First mode baroclinic wave speed, Geophys, Global baroclinic tide model, Global ocean, Global scale, Gravitational acceleration, Harmonic analysis, Hawaii region, Hawaiian islands, Inclination angle, Internal tide, Internal tide energy, Internal tide generation, Internal tide generation process, Internal tide modes, Internal tides, Internal wave drag energy dissipation, Internal wave generation, Internal wave propagation rays, Internal waves, Kerguelen, Kerguelen islands, Kerguelen plateau, Laurent, Layer model, Lett, Llewellyn smith, Lyard, Maraldi, Mesoscale, Mesoscale activity, Mesoscale variability, Mitchum, Modeling, Node tide variability, Ocean tides, Oceanogr, Other studies, Parameterization, Parameterization term, Potential density profile, Residual signal, Right angles, Scotia ridge, Service hydrographique, Southern indian ocean, Strong bathymetric gradients, Surface height signals, Surface height signatures, Surface manifestation, Surface signal, Surface signature, Theoretical criterion, Tidal, Tidal component, Tidal constituents, Tidal ellipses, Tidal energy, Tidal period, Tide, Tierney, Water column, Wave drag dissipation, Wave number.
Abstract
A barotropic tidal model, with a parameterization term to account for the internal wave drag energy dissipation, is used to examine areas of possible M2 internal tide generation in the Kerguelen Plateau region. Barotropic energy flux and a distribution of wave drag dissipation are computed. The results suggest important conversion of barotropic energy into baroclinic tide generation over the northern Kerguelen Plateau shelf break, consistent with a theoretical criterion based on ocean stratification, tidal forcing frequency, and bathymetric gradients. The sea surface height signatures of time‐coherent internal tides are studied using TOPEX/Poseidon and Jason‐1 altimeter data, whose ascending tracks cross nearly perpendicular to the eastern and western Kerguelen Plateau shelf break. Oscillations of a few centimeters associated with phase‐locked internal tides propagate away from the plateau over distances of several hundred kilometers with a ∼110 km wavelength. When reaching the frontal area of the Antarctic Circumpolar Current, the internal tide cannot be identified because of the aliasing of mesoscale variability into the same alias band as M2. Finally, using altimeter data, we estimate the M2 barotropic tidal power converted through the internal tide generation process. We find consistent values with the barotropic model parameterization estimation, which is also in good agreement with global internal tide model estimates. Combined with modeling, this study has shown that altimetry can be used to estimate internal tide dissipation.
Url:
DOI: 10.1029/2010JC006515
Affiliations:
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Coleman</name><affiliation wicri:level="1"><country xml:lang="fr">Australie</country><wicri:regionArea>Antarctic Climate and Ecosystems CRC, Hobart</wicri:regionArea><wicri:noRegion>Hobart</wicri:noRegion></affiliation><affiliation wicri:level="1"><country xml:lang="fr">Australie</country><wicri:regionArea>Institute for Marine and Antarctic Studies, University of Tasmania, Hobart, Tasmania</wicri:regionArea><wicri:noRegion>Tasmania</wicri:noRegion></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Journal of Geophysical Research: Oceans</title><title level="j" type="alt">JOURNAL OF GEOPHYSICAL RESEARCH: OCEANS</title><idno type="ISSN">0148-0227</idno><idno type="eISSN">2156-2202</idno><imprint><biblScope unit="vol">116</biblScope><biblScope unit="issue">C6</biblScope><biblScope unit="page-count">10</biblScope><date type="published" when="2011-06">2011-06</date></imprint><idno type="ISSN">0148-0227</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0148-0227</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Altimeter</term><term>Altimeter data</term><term>Altimeter track</term><term>Altimetry</term><term>Amplitude</term><term>Antarctic</term><term>Antarctic climate</term><term>Approximate wavelength</term><term>Baines</term><term>Baroclinic</term><term>Baroclinic mode</term><term>Baroclinic modes</term><term>Baroclinic tide generation</term><term>Baroclinic tides</term><term>Barotropic</term><term>Barotropic energy</term><term>Barotropic energy flux</term><term>Barotropic model</term><term>Barotropic response</term><term>Barotropic tide</term><term>Barotropic tide model</term><term>Barotropic tides</term><term>Bathymetric</term><term>Bathymetric gradient</term><term>Bathymetry</term><term>Bathymetry contours</term><term>Bottom friction dissipation</term><term>Deep ocean</term><term>Dissipation</term><term>Dissipation term</term><term>Egbert</term><term>Energetics</term><term>Energy flux</term><term>Energy transfer</term><term>First baroclinic mode</term><term>First baroclinic rossby radius</term><term>First mode</term><term>First mode baroclinic wave speed</term><term>Geophys</term><term>Global baroclinic tide model</term><term>Global ocean</term><term>Global scale</term><term>Gravitational acceleration</term><term>Harmonic analysis</term><term>Hawaii region</term><term>Hawaiian islands</term><term>Inclination angle</term><term>Internal tide</term><term>Internal tide energy</term><term>Internal tide generation</term><term>Internal tide generation process</term><term>Internal tide modes</term><term>Internal tides</term><term>Internal wave drag energy dissipation</term><term>Internal wave generation</term><term>Internal wave propagation rays</term><term>Internal waves</term><term>Kerguelen</term><term>Kerguelen islands</term><term>Kerguelen plateau</term><term>Laurent</term><term>Layer model</term><term>Lett</term><term>Llewellyn smith</term><term>Lyard</term><term>Maraldi</term><term>Mesoscale</term><term>Mesoscale activity</term><term>Mesoscale variability</term><term>Mitchum</term><term>Modeling</term><term>Node tide variability</term><term>Ocean tides</term><term>Oceanogr</term><term>Other studies</term><term>Parameterization</term><term>Parameterization term</term><term>Potential density profile</term><term>Residual signal</term><term>Right angles</term><term>Scotia ridge</term><term>Service hydrographique</term><term>Southern indian ocean</term><term>Strong bathymetric gradients</term><term>Surface height signals</term><term>Surface height signatures</term><term>Surface manifestation</term><term>Surface signal</term><term>Surface signature</term><term>Theoretical criterion</term><term>Tidal</term><term>Tidal component</term><term>Tidal constituents</term><term>Tidal ellipses</term><term>Tidal energy</term><term>Tidal period</term><term>Tide</term><term>Tierney</term><term>Water column</term><term>Wave drag dissipation</term><term>Wave number</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Altimeter</term><term>Altimeter data</term><term>Altimeter track</term><term>Altimetry</term><term>Amplitude</term><term>Antarctic</term><term>Antarctic climate</term><term>Approximate wavelength</term><term>Baines</term><term>Baroclinic</term><term>Baroclinic mode</term><term>Baroclinic modes</term><term>Baroclinic tide generation</term><term>Baroclinic tides</term><term>Barotropic</term><term>Barotropic energy</term><term>Barotropic energy flux</term><term>Barotropic model</term><term>Barotropic response</term><term>Barotropic tide</term><term>Barotropic tide model</term><term>Barotropic tides</term><term>Bathymetric</term><term>Bathymetric gradient</term><term>Bathymetry</term><term>Bathymetry contours</term><term>Bottom friction dissipation</term><term>Deep ocean</term><term>Dissipation</term><term>Dissipation term</term><term>Egbert</term><term>Energetics</term><term>Energy flux</term><term>Energy transfer</term><term>First baroclinic mode</term><term>First baroclinic rossby radius</term><term>First mode</term><term>First mode baroclinic wave speed</term><term>Geophys</term><term>Global baroclinic tide model</term><term>Global ocean</term><term>Global scale</term><term>Gravitational acceleration</term><term>Harmonic analysis</term><term>Hawaii region</term><term>Hawaiian islands</term><term>Inclination angle</term><term>Internal tide</term><term>Internal tide energy</term><term>Internal tide generation</term><term>Internal tide generation process</term><term>Internal tide modes</term><term>Internal tides</term><term>Internal wave drag energy dissipation</term><term>Internal wave generation</term><term>Internal wave propagation rays</term><term>Internal waves</term><term>Kerguelen</term><term>Kerguelen islands</term><term>Kerguelen plateau</term><term>Laurent</term><term>Layer model</term><term>Lett</term><term>Llewellyn smith</term><term>Lyard</term><term>Maraldi</term><term>Mesoscale</term><term>Mesoscale activity</term><term>Mesoscale variability</term><term>Mitchum</term><term>Modeling</term><term>Node tide variability</term><term>Ocean tides</term><term>Oceanogr</term><term>Other studies</term><term>Parameterization</term><term>Parameterization term</term><term>Potential density profile</term><term>Residual signal</term><term>Right angles</term><term>Scotia ridge</term><term>Service hydrographique</term><term>Southern indian ocean</term><term>Strong bathymetric gradients</term><term>Surface height signals</term><term>Surface height signatures</term><term>Surface manifestation</term><term>Surface signal</term><term>Surface signature</term><term>Theoretical criterion</term><term>Tidal</term><term>Tidal component</term><term>Tidal constituents</term><term>Tidal ellipses</term><term>Tidal energy</term><term>Tidal period</term><term>Tide</term><term>Tierney</term><term>Water column</term><term>Wave drag dissipation</term><term>Wave number</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>énergie marémotrice</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">A barotropic tidal model, with a parameterization term to account for the internal wave drag energy dissipation, is used to examine areas of possible M2 internal tide generation in the Kerguelen Plateau region. Barotropic energy flux and a distribution of wave drag dissipation are computed. The results suggest important conversion of barotropic energy into baroclinic tide generation over the northern Kerguelen Plateau shelf break, consistent with a theoretical criterion based on ocean stratification, tidal forcing frequency, and bathymetric gradients. The sea surface height signatures of time‐coherent internal tides are studied using TOPEX/Poseidon and Jason‐1 altimeter data, whose ascending tracks cross nearly perpendicular to the eastern and western Kerguelen Plateau shelf break. Oscillations of a few centimeters associated with phase‐locked internal tides propagate away from the plateau over distances of several hundred kilometers with a ∼110 km wavelength. When reaching the frontal area of the Antarctic Circumpolar Current, the internal tide cannot be identified because of the aliasing of mesoscale variability into the same alias band as M2. Finally, using altimeter data, we estimate the M2 barotropic tidal power converted through the internal tide generation process. We find consistent values with the barotropic model parameterization estimation, which is also in good agreement with global internal tide model estimates. Combined with modeling, this study has shown that altimetry can be used to estimate internal tide dissipation.</div></front></TEI><affiliations><list><country><li>Australie</li><li>France</li></country><region><li>Midi-Pyrénées</li><li>Occitanie (région administrative)</li></region><settlement><li>Toulouse</li></settlement></list><tree><country name="France"><region name="Occitanie (région administrative)"><name sortKey="Maraldi, Claire" sort="Maraldi, Claire" uniqKey="Maraldi C" first="Claire" last="Maraldi">Claire Maraldi</name></region><name sortKey="Lyard, Florent" sort="Lyard, Florent" uniqKey="Lyard F" first="Florent" last="Lyard">Florent Lyard</name><name sortKey="Maraldi, Claire" sort="Maraldi, Claire" uniqKey="Maraldi C" first="Claire" last="Maraldi">Claire Maraldi</name><name sortKey="Testut, Laurent" sort="Testut, Laurent" uniqKey="Testut L" first="Laurent" last="Testut">Laurent Testut</name></country><country name="Australie"><noRegion><name sortKey="Coleman, Richard" sort="Coleman, Richard" uniqKey="Coleman R" first="Richard" last="Coleman">Richard Coleman</name></noRegion><name sortKey="Coleman, Richard" sort="Coleman, Richard" uniqKey="Coleman R" first="Richard" last="Coleman">Richard Coleman</name></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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