Abstract

The large‐scale (i.e. bar‐scale) structure of channel deposits of the braided, low‐sinuosity Calamus River, Nebraska, is described using ground‐penetrating radar (GPR) profiles combined with vibracores. Basal erosion surfaces are generally overlain by medium‐scale, trough‐cross‐stratified (sets 3–25 cm thick), very coarse to medium sands, that are associated with relatively high amplitude, discontinuous GPR reflectors. Overlying deposits are bioturbated, small‐scale cross‐stratified (sets <3 cm thick) and vegetation‐rich, fine to very‐fine sands, that are associated with low‐amplitude discontinuous reflectors. Near‐surface peat and turf have no associated GPR reflectors. In along‐stream profiles through braid and point bars, most GPR reflectors dip downstream at up to 2° relative to the basal erosion surface, but some reflectors in the upstream parts of bars are parallel to the basal erosion surface or dip upstream. In cross‐stream profiles through bars, GPR reflectors are either approximately parallel to bar surfaces or have low‐angle inclinations (up to 6°) towards cut banks of adjacent curved channels. Basal erosion surfaces become deeper towards cut banks of curved channels. These structures can be explained by lateral and downstream growth of bars combined with vertical accretion. Convex upwards forms up to 0·5 m high, several metres across and tens of metres long represent episodic accretion of unit bars (scroll bars and bar heads). Stratal patterns in channel fills record a complicated history of erosion and deposition during filling, including migration of relatively small bars. A revised facies model for this type of sandy, braided river has been constructed based on this new information on large‐scale bedding structure.

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