Wave-induced flow and its influence on ridge erosion and channel deposition in Lanshayang channel of radial sand ridges

Very limited modeling studies were available of the wave-induced current under the complex hydrodynamic conditions in the South Yellow Sea Radial Sand Ridge area(SYSRSR). Partly it is due to the difficulties in estimating the influence of the waveinduced current in this area. In this study, a couple...

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Published inJournal of hydrodynamics. Series B Vol. 26; no. 6; pp. 882 - 893
Main Author 徐卓 张玮 陆培东 安翔 陈可峰
Format Journal Article
LanguageEnglish
Published Singapore Elsevier Ltd 01.01.2015
Springer Singapore
Subjects
Channels
Computational fluid dynamics
Deposition
Engineering
Engineering Fluid Dynamics
Erosion mechanisms
Fluid flow
Hydrodynamics
Hydrology/Water Resources
Numerical and Computational Physics
radiation stress
Ridges
ridges erosion and channel deposition
Sand
Simulation
South Yellow Sea Radial Sand Ridges
typhoon wave
Typhoons
wave-induced current
侵蚀
感应电流
沉积
流动
渠道
烂沙洋
辐射沙洲
通道
INW, Huanghai Sea
radiation stress
typhoon wave
wave-induced current
South Yellow Sea Radial Sand Ridges
ridges erosion and channel deposition
ridges erosion and cha-nnel deposition
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Summary:Very limited modeling studies were available of the wave-induced current under the complex hydrodynamic conditions in the South Yellow Sea Radial Sand Ridge area(SYSRSR). Partly it is due to the difficulties in estimating the influence of the waveinduced current in this area. In this study, a coupled 3-D storm-surge-wave model is built. In this model, the time-dependent varying Collins coefficient with the water level method(TCL) are used. The wave-flow environment in the Lanshayang Channel(LSYC) during the "Winnie" typhoon is successfully represented by this model. According to the modelling results, at a high water level(HWL), the wave-induced current similar to the long-shore current will emerge in the shallow area of the ridges, and has two different motion trends correlated with the morphological characteristics of the ridges. The wave-induced current velocity could be as strong as 1 m/s, which is at the same magnitude as the tidal current. This result is verified by the bathymetric changes in the LSYC during the "Matsa" typhoon. Thus, the wave-induced current may be one of the driven force of the ridge erosion and channel deposition in the SYSRSR. These conclusions will help to further study the mechanism of the ridge erosion and channel deposition in the SYSRSR.
Bibliography:typhoon wave,radiation stress,wave-induced current,South Yellow Sea Radial Sand Ridges,ridges erosion and cha-nnel deposition
31-1563/T
Very limited modeling studies were available of the wave-induced current under the complex hydrodynamic conditions in the South Yellow Sea Radial Sand Ridge area(SYSRSR). Partly it is due to the difficulties in estimating the influence of the waveinduced current in this area. In this study, a coupled 3-D storm-surge-wave model is built. In this model, the time-dependent varying Collins coefficient with the water level method(TCL) are used. The wave-flow environment in the Lanshayang Channel(LSYC) during the "Winnie" typhoon is successfully represented by this model. According to the modelling results, at a high water level(HWL), the wave-induced current similar to the long-shore current will emerge in the shallow area of the ridges, and has two different motion trends correlated with the morphological characteristics of the ridges. The wave-induced current velocity could be as strong as 1 m/s, which is at the same magnitude as the tidal current. This result is verified by the bathymetric changes in the LSYC during the "Matsa" typhoon. Thus, the wave-induced current may be one of the driven force of the ridge erosion and channel deposition in the SYSRSR. These conclusions will help to further study the mechanism of the ridge erosion and channel deposition in the SYSRSR.
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:1001-6058
1878-0342
DOI:10.1016/S1001-6058(14)60097-4