Turbulent bottom Ekman boundary layer measured over a continental shelf

Y. Yoshikawa; T. Endoh; T. Matsuno; T. Wagawa; E. Tsutsumi; H. Yoshimura; Y. Morii

doi:10.1029/2010GL044156

Turbulent bottom Ekman boundary layer measured over a continental shelf

Y. Yoshikawa, T. Endoh, T. Matsuno, T. Wagawa, E. Tsutsumi, H. Yoshimura, Y. Morii

Division of Earth Environment Dynamics

Research output: Contribution to journal › Article › peer-review

17 Citations (Scopus)

Abstract

An acoustic Doppler current profiler was deployed in summer and autumn in 2007-2009 at two stations on the East China Sea shelf. Clear velocity spirals that basically correspond to theoretical Ekman spirals were identified for both mean and tidal currents. From these spirals and the corresponding Ekman equation, we estimated the time-averaged eddy viscosity () profiles. The estimate dμ was largest (2-3 × 10^-3 m² s ^-1) around 5 m from the bottom and decreased almost exponentially with height. A qualitatively similar profile of the eddy diffusivity was also inferred from the acoustic Doppler current profiler data and microstructure profiler data. The flux Richardson number was estimated as 0.11±0.10 ∼ 0.46 0.17, indicating relatively large buoyancy contribution to the turbulent kinetic energy budget.

Original language	English
Article number	L15605
Journal	Geophysical Research Letters
Volume	37
Issue number	15
DOIs	https://doi.org/10.1029/2010GL044156
Publication status	Published - Aug 1 2010

All Science Journal Classification (ASJC) codes

Geophysics
Earth and Planetary Sciences(all)

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10.1029/2010GL044156

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title = "Turbulent bottom Ekman boundary layer measured over a continental shelf",

abstract = "An acoustic Doppler current profiler was deployed in summer and autumn in 2007-2009 at two stations on the East China Sea shelf. Clear velocity spirals that basically correspond to theoretical Ekman spirals were identified for both mean and tidal currents. From these spirals and the corresponding Ekman equation, we estimated the time-averaged eddy viscosity () profiles. The estimate dμ was largest (2-3 × 10-3 m2 s -1) around 5 m from the bottom and decreased almost exponentially with height. A qualitatively similar profile of the eddy diffusivity was also inferred from the acoustic Doppler current profiler data and microstructure profiler data. The flux Richardson number was estimated as 0.11±0.10 ∼ 0.46 0.17, indicating relatively large buoyancy contribution to the turbulent kinetic energy budget.",

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T1 - Turbulent bottom Ekman boundary layer measured over a continental shelf

AU - Yoshikawa, Y.

AU - Endoh, T.

AU - Matsuno, T.

AU - Wagawa, T.

AU - Tsutsumi, E.

AU - Yoshimura, H.

AU - Morii, Y.

PY - 2010/8/1

Y1 - 2010/8/1

N2 - An acoustic Doppler current profiler was deployed in summer and autumn in 2007-2009 at two stations on the East China Sea shelf. Clear velocity spirals that basically correspond to theoretical Ekman spirals were identified for both mean and tidal currents. From these spirals and the corresponding Ekman equation, we estimated the time-averaged eddy viscosity () profiles. The estimate dμ was largest (2-3 × 10-3 m2 s -1) around 5 m from the bottom and decreased almost exponentially with height. A qualitatively similar profile of the eddy diffusivity was also inferred from the acoustic Doppler current profiler data and microstructure profiler data. The flux Richardson number was estimated as 0.11±0.10 ∼ 0.46 0.17, indicating relatively large buoyancy contribution to the turbulent kinetic energy budget.

AB - An acoustic Doppler current profiler was deployed in summer and autumn in 2007-2009 at two stations on the East China Sea shelf. Clear velocity spirals that basically correspond to theoretical Ekman spirals were identified for both mean and tidal currents. From these spirals and the corresponding Ekman equation, we estimated the time-averaged eddy viscosity () profiles. The estimate dμ was largest (2-3 × 10-3 m2 s -1) around 5 m from the bottom and decreased almost exponentially with height. A qualitatively similar profile of the eddy diffusivity was also inferred from the acoustic Doppler current profiler data and microstructure profiler data. The flux Richardson number was estimated as 0.11±0.10 ∼ 0.46 0.17, indicating relatively large buoyancy contribution to the turbulent kinetic energy budget.

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Turbulent bottom Ekman boundary layer measured over a continental shelf

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