Abstract
Integrated observations were made on the South China Sea shelf at 19°37’ N, 112°04’ E, under strong wind and heavy raining weather conditions in August 2005. Current data were obtained using a moored 150-kHz Acoustic Doppler Current Profiler, turbulent kinetic energy dissipation rate were measured with TurboMapII, and temperature was recorded by thermistor chains. Both the mixed layer thickness and the corresponding mean dissipation rate increased after the strong wind bursts. Average surface mixed layer thickness was 13.4 m pre-wind and 22.4 m post-wind, and the average turbulent dissipation rate in the mixed layer pre-wind and post-wind were 4.26 × 10−7 and 1.09 × 10−6 Wkg−1, respectively. The post-wind dissipation rate was 2.5 times larger than the pre-wind dissipation rate in the interior layer and four times larger in the intermediate water column. Spectra and vertical mode analysis revealed that near-inertial motion post-wind, especially with high modes, was strengthened and propagated downward toward the intermediate layer. The downward group velocity of near-inertial current was about 8.1 × 10−5 ms−1 during the strong wind bursts. The mean percentage of wind work transmitted into the intermediate layer is about 4.2 %. The ratio of post-wind high-mode energy to total horizontal kinetic energy increased below the surface mixed layer, which would have caused instabilities and result in turbulent mixing. Based on these data, we discuss a previous parameterization that relates dissipation rate, stratification, and shear variance calculated from baroclinic currents with high modes (higher than mode 1) which concentrate a large fraction of energy.
Highlights
Ocean mixing is an important process in controlling the distribution of physical properties of water masses, ocean circulation, nutrient fluxes, and concentration of particulate matter (Sandstrom and Elliot 1984; Wunsch and Ferrari 2004; Sharples et al 2001)
The results documented in our study and those of other studies indicate that strong turbulent mixing occurs below the base of the mixed layer during the strong wind bursts (Grant and Belcher 2011; Dohan and Davis 2011)
Current velocity was primarily low-frequency, and low-mode internal waves dominated by a first-mode structure with flow above 40 m depth moving opposite the deeper flow (Figs. 4b and 5b)
Summary
Ocean mixing is an important process in controlling the distribution of physical properties of water masses, ocean circulation, nutrient fluxes, and concentration of particulate matter (Sandstrom and Elliot 1984; Wunsch and Ferrari 2004; Sharples et al 2001). Wind-forced near-inertial waves, which frequently are observed both in the open ocean and in coastal seas (D’Asaro and Perkins 1984; Watanabe and Hibiya 2002; MacKinnon and Gregg 2005a; Alford et al 2012), propagate downward and represent a major flux. MacKinnon and Gregg (2005b) reported that the largest turbulent dissipation away from boundaries was coincident with shear from lower-mode near-inertial waves generated by passing storms. They argued that turbulent dissipation rates increased with both shear and stratification which is confirmed by the measurements observed in the Baltic Sea (van der Lee and Umlauf 2011); this differs from Gregg-Henyey scaling (Gregg 1989) used for the open ocean. 24 thermistor sensors and 5 temperature-salinity sensors were deployed at different depths to record
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