This is a Preprint and has not been peer reviewed. The published version of this Preprint is available: https://doi.org/10.1002/dep2.75. This is version 2 of this Preprint.
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Abstract
Channel-bend expansion and downstream translation, as well as vertical movements by aggradation and incision, set the stratigraphic architecture of channelized depositional systems. Early work on submarine-channel evolution has suggested that downstream translation is rare. We propose that downstream translation of bends might be common in deep-water salt-tectonic provinces, where complex topography can localize channel pathways that promote meander cutoffs and the generation of high-curvature bends. We use three-dimensional seismic-reflection data from a region with salt-influenced topography in the Campos basin, offshore Brazil, to characterize the structural geometry of a salt diapir and stratigraphic architecture of an adjacent ~18 km-long reach of a submarine-channel system. We interpret the structural and stratigraphic evolution, including meander-cutoff development near the salt diapir followed by ~10 km of downstream translation of a channel bend. We test the stratigraphic evolution with a simple numerical model of channel meandering. This integrated subsurface characterization and stratigraphic modeling study sheds light on the processes and controls of submarine-channel downstream translation, which might be common in rapidly deforming settings, such as salt basins, that promote localized subsidence, meander cutoffs, and rapidly translating, high-curvature bends.
DOI
https://doi.org/10.31223/osf.io/e4at7
Subjects
Earth Sciences, Geology, Physical Sciences and Mathematics
Keywords
numerical modeling, continental margin, submarine channel, salt basin
Dates
Published: 2018-12-08 08:44
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