Wave-induced deep equatorial ocean circulation

Wave-induced deep equatorial ocean circulation

Thesis (Ph.D.)--University of Hawaii at Manoa, 2008. === For weak Yanai wave amplitude, currents resembling the TEJs are obtained, but only within the beam. They are the mean Eulerian flow, which cancels the Stokes drift of the Yanai waves, yielding a zero-mean Lagrangian flow: the water parcels con...

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Main Author: Ascani, Francois
Language:en-US
Published: 2011
Online Access:http://hdl.handle.net/10125/20786
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spelling ndltd-UHAWAII-oai-scholarspace.manoa.hawaii.edu-10125-207862013-01-08T11:16:05ZWave-induced deep equatorial ocean circulationAscani, FrancoisThesis (Ph.D.)--University of Hawaii at Manoa, 2008.For weak Yanai wave amplitude, currents resembling the TEJs are obtained, but only within the beam. They are the mean Eulerian flow, which cancels the Stokes drift of the Yanai waves, yielding a zero-mean Lagrangian flow: the water parcels conserve their potential vorticity (PV) and are stationary over a wave cycle. With stronger amplitude, the Yanai waves become unstable, and lose their energy to small vertical scales where it is dissipated. The resulting vertical decay of the Yanai waves provides a source of PV, allowing water parcels to move meridionally within the beam. This process results in TEJs with a mean Lagrangian zonal flow extending to the west of the beam.In the Pacific and Atlantic oceans, a complex equatorial current structure is found below the thermocline. The currents are zonal with typical speeds from 5 to 20 cm s-1 and extend as deep as 2500 m. The structure can be divided into two overlapping parts: the Tall Equatorial Jets (TEJs), with large vertical scale and alternating with latitude, and the Equatorial Deep Jets (EDJs), centered on the equator and alternating in the vertical with a wavelength of several hundred meters.In the present study, using idealized numerical simulations and analytical solutions, we demonstrate that the TEJs could result from a rectification of a beam of monthly-periodic Yanai waves that is generated in the eastern part of the basin by instabilities of the swift equatorial surface currents.This circulation poses a computational and a theoretical challenge. First, state-of-the-art high-resolution regional models and Ocean General Circulation Models (OGCMs) typically produce a rather weak, inaccurate and incomplete picture of the circulation. Second, the most promising existing theory, based on the rectification of intraseasonal Yanai waves, cannot account for the basin-wide presence of the TEJs.Includes bibliographical references (leaves 148-157).Also available by subscription via World Wide Web158 leaves, bound 29 cm2011-07-22T00:08:31Z2011-07-22T00:08:31Z2008ThesisText9780549808312http://hdl.handle.net/10125/20786en-USTheses for the degree of Doctor of Philosophy (University of Hawaii at Manoa) no. 5090All UHM dissertations and theses are protected by copyright. They may be viewed from this source for any purpose, but reproduction or distribution in any format is prohibited without written permission from the copyright owner.
collection NDLTD
language en-US
sources NDLTD
description Thesis (Ph.D.)--University of Hawaii at Manoa, 2008. === For weak Yanai wave amplitude, currents resembling the TEJs are obtained, but only within the beam. They are the mean Eulerian flow, which cancels the Stokes drift of the Yanai waves, yielding a zero-mean Lagrangian flow: the water parcels conserve their potential vorticity (PV) and are stationary over a wave cycle. With stronger amplitude, the Yanai waves become unstable, and lose their energy to small vertical scales where it is dissipated. The resulting vertical decay of the Yanai waves provides a source of PV, allowing water parcels to move meridionally within the beam. This process results in TEJs with a mean Lagrangian zonal flow extending to the west of the beam. === In the Pacific and Atlantic oceans, a complex equatorial current structure is found below the thermocline. The currents are zonal with typical speeds from 5 to 20 cm s-1 and extend as deep as 2500 m. The structure can be divided into two overlapping parts: the Tall Equatorial Jets (TEJs), with large vertical scale and alternating with latitude, and the Equatorial Deep Jets (EDJs), centered on the equator and alternating in the vertical with a wavelength of several hundred meters. === In the present study, using idealized numerical simulations and analytical solutions, we demonstrate that the TEJs could result from a rectification of a beam of monthly-periodic Yanai waves that is generated in the eastern part of the basin by instabilities of the swift equatorial surface currents. === This circulation poses a computational and a theoretical challenge. First, state-of-the-art high-resolution regional models and Ocean General Circulation Models (OGCMs) typically produce a rather weak, inaccurate and incomplete picture of the circulation. Second, the most promising existing theory, based on the rectification of intraseasonal Yanai waves, cannot account for the basin-wide presence of the TEJs. === Includes bibliographical references (leaves 148-157). === Also available by subscription via World Wide Web === 158 leaves, bound 29 cm
author Ascani, Francois
spellingShingle Ascani, Francois
Wave-induced deep equatorial ocean circulation
author_facet Ascani, Francois
author_sort Ascani, Francois
title Wave-induced deep equatorial ocean circulation
title_short Wave-induced deep equatorial ocean circulation
title_full Wave-induced deep equatorial ocean circulation
title_fullStr Wave-induced deep equatorial ocean circulation
title_full_unstemmed Wave-induced deep equatorial ocean circulation
title_sort wave-induced deep equatorial ocean circulation
publishDate 2011
url http://hdl.handle.net/10125/20786
work_keys_str_mv AT ascanifrancois waveinduceddeepequatorialoceancirculation
_version_ 1716506548226752512

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