Mechanism of Formation and Estuarine Turbidity Maxima in the Hau River Mouth

Nguyen Ngoc Tien,Nguyen Xuan Tung,Dinh Van Uu,Le Dinh Mau,Do Huy Cuong,Pham Duc Hung

doi:10.3390/w12092547

Nguyen Ngoc Tien, Nguyen Xuan Tung + Show 4 more

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https://doi.org/10.3390/w12092547

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Abstract

Observation of the Hau River distributary of the Mekong River delta in Vietnam, conducted in dry and flood season (2009, 2014, and 2015), is utilized to investigate the mechanism of formation, distribution of estuarine turbidity maxima (ETM), and links with sediment transport in the system. Additionally, 3D (three-dimensional) numerical models are applied to simulate the seasonal tidal variation (flood and dry seasons) of the water and suspended sediment transport processes of the Mekong River Delta. The 3D model, with a combination of hydrodynamic-wave and suspended sediment transport, was set up and validated with measured data in the study area. The mechanism that measures ETM is the process of suspended sediment from the river when it interacts with seawater and speeds up the flocculation, combined with the asymmetry of the tidal current, which will create the region with ETM by moving in/out with the tidal current’s ups and downs. As there is surface flow velocity towards the sea, the bottom baroclinic flow has a decisive role in deposition and erosion, and it causes the suspended sediment concentration (SSC) to be maximized. During the flood season, the salt wedge near the river’s mouth, at the peak of the tide, pushes towards the sea’s direction when there are ebbing tides, with a scope of about 20 km. In the dry season, there is estuary disturbance as well; the salt wedge forms, but is relatively weak or does not exist, depending on the time of the tide. The maximum turbidity zone in the flood season moves the subaqueous delta with a scope of about 20 km and SSC of about 0.1 to 0.6 g L−1, whereas in the dry season, the seawater has high salinity, and seaward SSC penetrates the estuaries to cause a disturbance and flocculation. The penetration scope is up to 50 km and creates a water mass that has high SSC, from 0.2 to 0.7 g L−1, to run in/off by the tidal current’s ups and downs for several kilometers in the tidal phase.

Highlights

Estuarine turbidity maxima (ETMs) are zones of the interaction between a river and sea and are characterized by higher suspended sediment concentrations (SSCs) than in the river and lower parts [1].The estuarine turbidity maxima (ETM) dynamic is focused on long-term deposition in the estuaries and tidal flats [1,2]
Tidal current is enhanced in near-surface waters at ebbs is a key factor for creating high SSC concentration [6,7,14,15,16,17,18], and tidal asymmetry is and isresuspension bottom-intensified during floods
By applying MIKE 21/3 coupled model FM to simulate the tidal, seasonal, and interannual variations of the water and suspended sediment transport processes in the Mekong River delta, the results demonstrate that the salt wedges in the Hau River mouth exist year-round, but their position and length vary depending on the hydrographic season, tidal phase, and the strong change in space and time

Summary

Introduction

Estuarine turbidity maxima (ETMs) are zones of the interaction between a river and sea and are characterized by higher suspended sediment concentrations (SSCs) than in the river and lower parts [1].The ETM dynamic is focused on long-term deposition in the estuaries and tidal flats [1,2]. Tidal current is enhanced in near-surface waters at ebbs is a key factor for creating high SSC concentration [6,7,14,15,16,17,18], and tidal asymmetry is and isresuspension bottom-intensified during floods. The influence of vertical mixing may be suppressed at another factor promote ETM formation [8,9,10,11,19]. The location of ETMs depend on the interaction of seawater near‐surface waters at ebbs and is bottom‐intensified during floods. The influence of vertical mixing and river water; they move to the upper river if there is weakened freshwater (in the dry season) and may be suppressed at ebbs and enhanced during floods [1,20]. The location of ETMs depend on movethe downriver when the riverand water stronger, in thetowet [21,22,23,24,25]

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