Oblique Internal Hydraulic Jumps at a Stratified Estuary Mouth

Honegger, D.; Haller, Merrick C.; Geyer, W. Rockwell; Farquharson, Gordon

doi:10.1175/jpo-d-15-0234.1

Cited by 19 publications

(16 citation statements)

References 41 publications

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“…A large gradient in wave energy flux would be expected across such a current gradient 2dU/dx, even on following currents, because of the rapid change in wave steepness required from conservation of wave action and dispersion (Chawla and Kirby 2002). The SWIFT buoys were visually confirmed to be caught in this front at approximate longitude 2124.04, which matches with tower-based radar measurements of the front (not shown; see Honegger et al 2017). The drifters stayed in the front until they were reset to avoid grounding, and therefore the drift track is discontinuous at longitude 2124.…”

Section: Frontssupporting

confidence: 70%

Turbulence from Breaking Surface Waves at a River Mouth

Zippel

Thomson

Farquharson

2018

Journal of Physical Oceanography

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Observations of surface waves, currents, and turbulence at the Columbia River mouth are used to investigate the source and vertical structure of turbulence in the surface boundary layer. Turbulent velocity data collected on board freely drifting Surface Wave Instrument Float with Tracking (SWIFT) buoys are corrected for platform motions to estimate turbulent kinetic energy (TKE) and TKE dissipation rates. Both of these quantities are correlated with wave steepness, which has previously been shown to determine wave breaking within the same dataset. Estimates of the turbulent length scale increase linearly with distance from the free surface, and roughness lengths estimated from velocity statistics scale with significant wave height. The vertical decay of turbulence is consistent with a balance between vertical diffusion and dissipation. Below a critical depth, a power-law scaling commonly applied in the literature works well to fit the data. Above this depth, an exponential scaling fits the data well. These results, which are in a surface-following reference frame, are reconciled with results from the literature in a fixed reference frame. A mapping between freesurface and mean-surface reference coordinates suggests 30% of the TKE is dissipated above the mean sea surface.

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Section: Frontssupporting

confidence: 70%

Turbulence from Breaking Surface Waves at a River Mouth

Zippel

Thomson

Farquharson

2018

Journal of Physical Oceanography

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“…the plume-related hydraulic jump and tidal pumping etc.) might trigger the similar phenomenon 31 , 60 – 62 , our measurements (e.g. strong across-shore current variation, consistently NE wind; Figs.…”

Section: Discussionsupporting

confidence: 68%

Encountering shoaling internal waves on the dispersal pathway of the pearl river plume in summer

Lee

Liu

Lee

et al. 2021

Sci Rep

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Fundamentally, river plume dynamics are controlled by the buoyancy due to river effluent and mixing induced by local forcing such as winds and tides. Rarely the influence of far-field internal waves on the river plume dynamics is documented. Our 5-day fix-point measurements and underway acoustic profiling identified hydrodynamic processes on the dispersal pathway of the Pearl River plume. The river plume dispersal was driven by the SW monsoon winds that induced the intrusion of cold water near the bottom. The river effluent occupied the surface water, creating strong stratification and showing on-offshore variability due to tidal fluctuations. However, intermittent disruptions weakened stratification due to wind mixing and perturbations by nonlinear internal waves (NIWs) from the northern South China Sea (NSCS). During events of NIW encounter, significant drawdowns of the river plume up to 20 m occurred. The EOF deciphers and ranks the contributions of abovementioned processes: (1) the stratification/mixing coupled by wind-driven plume water and NIWs disruptions (81.7%); (2) the variation caused by tidal modulation (6.9%); and (3) the cold water intrusion induced by summer monsoon winds (5.1%). Our findings further improve the understanding of the Pearl River plume dynamics influenced by the NIWs from the NSCS.

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“…Therefore, a hydraulic jump formed as a result of the transition of the freshened flow from the supercritical near-field plume to the subcritical far-field plume generated IW, which were detected by satellite imagery and in situ measurements. A number of previous studies addressed generation of IW by a hydraulic jump in a two-layered fluid 30 , 31 . A schematic diagram of this process occurring in a river plume is shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Small Mountainous Rivers Generate High-Frequency Internal Waves in Coastal Ocean

Osadchiev

2018

Sci Rep

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High-frequency internal waves propagating offshore in small river plumes are regularly observed at satellite imagery in many world regions. In this work we describe a mechanism of generation of these internal waves by discharges of small and rapid rivers inflowing to coastal sea. Friction between river runoff at high velocity and the subjacent sea of one order of magnitude lower velocity causes abrupt deceleration of a freshened flow and increase of its depth, i.e., a hydraulic jump is formed. Transition from supercritical to subcritical flow conditions induces generation of high-frequency internal waves that propagate off a river mouth at a stratified layer between a buoyant river plume and subjacent ambient sea and influence turbulence and mixing at this layer. Basing on in situ and satellite data we estimated wavelengths, phase speeds, and frequencies of internal waves generated in small river plumes located off the northeastern coast of the Black Sea. This process is typical for many other world mountainous regions where numerous and closely spaced small and rapid rivers inflow to sea during high discharge periods and can strongly influence, first, structure and dynamics of river plumes and, second, physical, biological, and geochemical processes in adjacent coastal areas.

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Oblique Internal Hydraulic Jumps at a Stratified Estuary Mouth

Cited by 19 publications

References 41 publications

Turbulence from Breaking Surface Waves at a River Mouth

Turbulence from Breaking Surface Waves at a River Mouth

Encountering shoaling internal waves on the dispersal pathway of the pearl river plume in summer

Small Mountainous Rivers Generate High-Frequency Internal Waves in Coastal Ocean

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