Sedimentation processes and sedimentary characteristics of tidal bores along the north bank of the Qiantang Estuary |
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Authors: | DaiDu Fan GuoFu Cai Shuai Shang YiJing Wu YanWei Zhang Lei Gao |
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Institution: | [1]State Key Laboratory of Marine Geology, Tongji University, Shanghai 200092, China; [2]Key Laboratory of Marine Sedimentology & Environmental Geology, State Oceanic Administration, Qingdao 266061, China [3]State Key Laboratory of Estuarine and Coastal Research, East China Normal University, Shanghai 200062, China |
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Abstract: | A tidal bore is a unique Earth surface process, characterized by its highly destructive energy, predictable periodicities
and magnitudes, and the production of characteristic sedimentary features. Tidal bores and associated rapid flood flows are
highly turbulent flows of the upper-flow regime with a velocity over several meters per second. Reynolds (R
e) and Froude (F
r) numbers, respectively, are larger than 104 and 1.0, making them significantly different from regular tidal flows but analogous to turbidity currents. Until now, understanding
of tidal-bore depositional processes and products has been limited because of the difficulty and hazards involved with gauging
tidal bores directly. The Qiantang bore is known as the largest breaking bore in the world. Field surveys were carried out
in May 2010, along the north bank of the Qiantang Estuary to observe the occurrence of peak bores, including regular observations
of current, water level and turbidity at the main channel. Several short cores were sampled on the intertidal flats to study
the characteristic sedimentary features of tidal bores. Hydrodynamic and sedimentological studies show that the processes
of sediment resuspension, transport and deposition are controlled primarily by the tidal bores, and the subsequent abruptly
accelerated and decelerated flood flows, which only account for one tenth of each semidiurnal tidal cycle in the estuary.
Tidal-bore deposits are generally poorly sorted because of rapid sedimentation after highly mixed suspension by intense turbulence.
This behavior is characteristic of the absence of tractive-current depositional components in a C-M diagram. It also goes along with well-developed massive bedding, graded bedding, basal erosion structures, convolute bedding
and dewatering structures. Together, these sedimentary features can constitute fingerprinting of turbidites, widely distributed
in the deep-water environment. However, a tidal bore is triggered by intensely deformed tidal waves propagating into a shallow-water
environment, which returns to regular tidal flows rapidly after the passage of the bore head. The tidal-bore deposits are
usually bounded by the intertidal-flat deposits with typical tidal beddings at the top and on both flanks. The difference
between tidal-bore deposits (TBD) and tidal sandy/muddy deposits (TSD/TMD) is evident not only in sedimentary structures,
but also in the grain-size composition. They can be clearly distinguished in grain-size bivariate plots, typically the plot
of mean grain size vs. standard deviation (or sorting). Some trend variations generally exist in mean grain size with TBD>TSD>TMD,
sorting with TMD>TBD>TSD (larger value indicating poorer sorting), and both skewness and kurtosis with TSD>TBD>TMD. These
findings will undoubtedly shed new light on our understanding of tidal-bore sedimentology, ancient tidal-bore sedimentary
facies and environments, and related oil-and-gas field prospecting. |
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Keywords: | Qiantang River tidal bore sediment-dynamics turbulence flow grain-size analysis sedimentary structure tidal rhythmite |
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