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Simulating the role of tides and sediment characteristics on tidal flat sorting and bedding dynamics

Zeng Zhou, Qian Liu, Daidu Fan, Giovanni Coco, Zheng Gong, Iris Möller, Fan Xu, Ian Townend, Changkuan Zhang

2021Earth Surface Processes and Landforms14 citationsDOI

Abstract

Abstract Understanding sediment sorting and bedding dynamics has high value to unravelling the mechanisms underlying geomorphological, geological, ecological and environmental imprints of tidal wetlands and hence to predicting their future changes. Using the Nanhui tidal flat on the Changjiang (Yangtze) Delta, China, as a reference site, this study establishes a schematized morphodynamic model coupling flow, sediment dynamics and bed level change to explore the processes that govern sediment sorting and bedding phenomena. Model results indicate an overall agreement with field data in terms of tidal current velocities, suspended sediment concentrations (SSCs), deposition thicknesses and sedimentary structures. Depending on the variation of tidal current strength, sand‐dominated layers (SDLs) and mud‐dominated layers (MDLs) tend to form during spring and neap tides, respectively. Thinner tidal couplets are developed during daily scale flood–ebb variations. A larger tidal level variation during a spring–neap tidal cycle, associated with a stronger tidal current variation, favours the formation of SDLs and tidal couplets. A larger boundary sediment supply generally promotes the formation of tidal bedding, though the bedding detail is partially dependent on the SSC composition of different sediment types. Sediment properties, including for example grain size and settling velocity, are also found to influence sediment sorting and bedding characteristics. In particular, finer and coarser sediment respond differently to spring and neap tides. During neap tides, relatively small flow velocities favour the deposition of finer sediment, with limited coarser sediment being transported to the upper tidal flat because of the larger settling velocity. During spring tides, larger flow velocities transport more coarser sediment to the upper tidal flat, accounting for distinct lamination formation. Model results are qualitatively consistent with field observations, but the role of waves, biological processes and alongshore currents needs to be included in further studies to establish a more complete understanding.

Topics & Concepts

GeologySortingSedimentDeposition (geology)SettlingBeddingSedimentary rockSediment transportCurrent (fluid)GeomorphologySedimentary structuresSedimentary depositional environmentGraded beddingHydrology (agriculture)OceanographyGeochemistryGeotechnical engineeringEnvironmental scienceProgramming languageHorticultureStructural basinBiologyComputer scienceEnvironmental engineeringCoastal wetland ecosystem dynamicsCoastal and Marine DynamicsGeological formations and processes