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W2022092875 abstract "Sand banks and elongated sand ridges occur in many coastal and shelf seas where there is abundant sand and where the currents are strong enough to move sediment, but they have a wide variety of forms. Their generation requires a source of mobile sediment, either from the local sea bed, or from coast erosion. Most appear to have been created during the post-glacial rise in sea level, but they have been subsequently modified by changing currents and waves, thus losing their relict characteristics. A descriptive classification scheme is developed to unify the approaches of marine geologists and physical oceanographers, which emphasizes the formation and present hydrodynamic setting in their long-term development. Open shelf linear ridges (Type 1) are up to 80 km long, average 13 km wide and are tens of metres in height. They are oriented at an angle to the flow, are asymmetrical and appear to migrate in the direction of their steep face. They appear to be in near equilibrium with the flow. These contrast with linear ridges formed in mouths of wide estuaries, which are aligned with the flow, and which migrate away from their steeper face (Type2A). In narrow-mouthed estuaries and inlets, tidal currents are strong only close to the mouth and waves are more dominant. The banks then form close to the mouth as ebb and flood deltas (Type 2Bi). When the coast is retreating, the ebb delta forms a primary source of sand to the nearshore region, which can become modified by storm flows into `shore attached ridges’ at angles to the coastline (Type 2Bii). Tidal eddies produced by headlands can create `banner banks’ (Type 3A), but when the headland is retreating alternating or `en-echelon’ ridges can be formed which can become isolated from the coast as it recedes (Type 3B). Coastal retreat and rising sea level can then cause the ridges to become moribund. Thus the majority of ridges rely on sea level rise for their origin. Theoretical and modelling studies of the shorter term response to present hydrodynamic forcing are generally confined to Types 1 ridges and 3A banks. The most promising work considers the coupled system of hydrodynamics, sediment transport and morphology on Type 1 ridges, and predicts features such as the ridge spacing and angle to the flow. Type 3A sand banks are clearly related to the flow patterns produced by the headlands, and the models can reproduce the eddy structures and sand bank extents. Nevertheless, the vital role of shoreline processes has not been fully incorporated into the models, and there is little modelling of ebb tidal deltas or other Type 2 banks. There thus appears to be a wide scope for modelling the generation, evolution and stability of sank banks under the scenario of rising sea level and coastal retreat." @default.
W2022092875 created "2016-06-24" @default.
W2022092875 creator A5022120071 @default.
W2022092875 creator A5061864905 @default.
W2022092875 date "1999-08-01" @default.
W2022092875 modified "2023-10-12" @default.
W2022092875 title "The origin, classification and modelling of sand banks and ridges" @default.
W2022092875 cites W1510666862 @default.
W2022092875 cites W1541090301 @default.
W2022092875 cites W1641638483 @default.
W2022092875 cites W1667985022 @default.
W2022092875 cites W1716078301 @default.
W2022092875 cites W1975006297 @default.
W2022092875 cites W1977617050 @default.
W2022092875 cites W1979863787 @default.
W2022092875 cites W1983670496 @default.
W2022092875 cites W1985951790 @default.
W2022092875 cites W1988061033 @default.
W2022092875 cites W1988453873 @default.
W2022092875 cites W1998542949 @default.
W2022092875 cites W2000432997 @default.
W2022092875 cites W2000572447 @default.
W2022092875 cites W2001533139 @default.
W2022092875 cites W2005774437 @default.
W2022092875 cites W2008867829 @default.
W2022092875 cites W2011793749 @default.
W2022092875 cites W2015830939 @default.
W2022092875 cites W2016367127 @default.
W2022092875 cites W2019612195 @default.
W2022092875 cites W2024506915 @default.
W2022092875 cites W2024932448 @default.
W2022092875 cites W2027988144 @default.
W2022092875 cites W2028473509 @default.
W2022092875 cites W2030709835 @default.
W2022092875 cites W2030818803 @default.
W2022092875 cites W2040205418 @default.
W2022092875 cites W2045364760 @default.
W2022092875 cites W2050490760 @default.
W2022092875 cites W2051156560 @default.
W2022092875 cites W2052873228 @default.
W2022092875 cites W2053388060 @default.
W2022092875 cites W2053658228 @default.
W2022092875 cites W2053944142 @default.
W2022092875 cites W2054616920 @default.
W2022092875 cites W2055063809 @default.
W2022092875 cites W2063317862 @default.
W2022092875 cites W2063920852 @default.
W2022092875 cites W2064163972 @default.
W2022092875 cites W2068195958 @default.
W2022092875 cites W2069437580 @default.
W2022092875 cites W2069894247 @default.
W2022092875 cites W2070005135 @default.
W2022092875 cites W2080319698 @default.
W2022092875 cites W2080567139 @default.
W2022092875 cites W2082172696 @default.
W2022092875 cites W2087527696 @default.
W2022092875 cites W2090349965 @default.
W2022092875 cites W2117978049 @default.
W2022092875 cites W2131962942 @default.
W2022092875 cites W2132913079 @default.
W2022092875 cites W2145694796 @default.
W2022092875 cites W2154033322 @default.
W2022092875 cites W2157609727 @default.
W2022092875 cites W2163936461 @default.
W2022092875 cites W2167695096 @default.
W2022092875 cites W4213262658 @default.
W2022092875 cites W4232557411 @default.
W2022092875 cites W4251433048 @default.
W2022092875 cites W4365787291 @default.
W2022092875 doi "https://doi.org/10.1016/s0278-4343(99)00028-x" @default.
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