Synchronism of sediment erosion and deposition processes during high-turbidity events in a large shallow lake

•High-turbidity events are triggered by wind waves with wind speeds of > 7 m s−1.•Sediment erosion and deposition are synchronous during HTEs.•Synchronism causes a near-lakebed turbid water layer and sustains the lutocline. High-turbidity events (HTEs) frequently occur in shallow lakes and can de...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2023-08, Vol.623, p.129853, Article 129853
Main Authors: Wu, Tingfeng, Sheng, Yongwei, Chen, Dong, Qin, Boqiang
Format: Article
Language:English
Subjects:
High-turbidity events
Sediment deposition
Sediment erosion
Shallow lake
Synchronism
Three-dimensional sediment transport model
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Summary:•High-turbidity events are triggered by wind waves with wind speeds of > 7 m s−1.•Sediment erosion and deposition are synchronous during HTEs.•Synchronism causes a near-lakebed turbid water layer and sustains the lutocline. High-turbidity events (HTEs) frequently occur in shallow lakes and can deeply influence lake ecosystems. However, the processes of sediment erosion and deposition are not fully understood. To investigate these processes, two investigative campaigns that integrate bed sediment measurements, sediment settling experiments, in-situ observations, or a hydrodynamics-sediment model were conducted to quantitatively study wind-induced HTEs in Lake Taihu, China. Cohesive sediments were massively entrained from the lakebed by wind waves when the wind speed exceeded its critical value of 7 m s−1, as estimated by water depth, triggering HTEs with turbidity waves of > 100 nephelometric turbidity units. The suspended sediment concentration was the net sediment flux of erosion (average: 5.9 mg m−2 s−1) and deposition (average: 5.5 mg m−2 s−1), which occurred synchronously for most of the HTEs and resulted in high temporal variation in suspended sediment concentration. This synchronism was determined by the critical erosional stress of lakebed sediments, which was spatially heterogeneous (0.017–0.055 N m−2) in a large lake. Equations for erosion and deposition processes were derived following the investigative campaigns and used to develop a cohesive sediment transport model for simulating HTEs in Lake Taihu. Simulations indicate that the synchronism of sediment erosion and deposition led to a near-lakebed turbid water layer during an HTE, which sustained the sediment lutocline in Lake Taihu. Further investigation should be conducted on the role of the near-lakebed turbid water layer during endogenous pollution in large eutrophic lakes.
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2023.129853