Abstract
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.
Highlights
River plume dynamics are controlled by the buoyancy due to river effluent and mixing induced by local forcing such as winds and tides
When IWs propagate into the shallow coastal region, they evolve into various types such as the nonlinear internal waves (NIWs) along isopycnal s urfaces[4,10,11,12]
The shoaling bottom topography along the wave propagation pathway induces the polarity reversal of NIWs which turns from the depression wave to the elevation w ave[10,13]
Summary
River plume dynamics are controlled by the buoyancy due to river effluent and mixing induced by local forcing such as winds and tides. 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%). The reasons causing the turning point of the polarity reversal include the depth of the mixed layer in the water column or the ratio of upper and lower layers Both depression wave and elevation wave could occur in the same areas even though within different s easons[14]. There is a lack of knowledge regarding the influence of the NIWs on the shelf-mixing processes and coastal river plume hydrodynamics which is an important factor to influence the water stratification in nearshore area. The current-induced mixing modified the sea surface temperature
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