On the impact of an offshore bathymetric anomaly on surf zone rip channels

We use a nonlinear morphodynamic model to demonstrate that the presence of a single persistent offshore bathymetric anomaly strongly affects the formation, nonlinear evolution and saturation of surf zone rip channels. In the case of an offshore bump or trough and waves with oblique incidence, a rip...

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Bibliographic Details
Published in:Journal of Geophysical Research: Earth Surface 2012-03, Vol.117 (F1), p.n/a
Main Authors: Castelle, B., Marieu, V., Coco, G., Bonneton, P., Bruneau, N., Ruessink, B. G.
Format: Article
Language:English
Subjects:
bathymetric control
Behavior
Earth sciences
Earth, ocean, space
Energy dissipation
Exact sciences and technology
Geophysics
Marine geology
Nonlinear systems
Oceanography
Physical oceanography
rip current
rip migration
rip spacing
Sand bars
self-organization
Surf
Wave energy
Wave refraction
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Summary:We use a nonlinear morphodynamic model to demonstrate that the presence of a single persistent offshore bathymetric anomaly strongly affects the formation, nonlinear evolution and saturation of surf zone rip channels. In the case of an offshore bump or trough and waves with oblique incidence, a rip channel shoreward of the anomaly is enforced by the more seaward alongshore variability in depth. The degree of rip channel enforcement is controlled by the strength of the rotational nature of surf zone rip current circulations, which is, in turn, driven by differential broken wave energy dissipation induced by wave refraction across the offshore bathymetric anomaly. The alongshore location of this forced rip channel is more stable with increasing offshore anomaly amplitude, decreasing offshore wave obliquity and decreasing bathymetric anomaly distance to the shore. Simulations show that rip channel behavior downdrift and updrift of the offshore perturbation are different. In our numerical experiments, downdrift rip channels have systematically larger alongshore scales, smaller alongshore migration rates and more erosive megacusps than those updrift. Rip channels therefore self‐organize into patterns of different alongshore scales and migration rates as a result of an alongshore perturbation in the wave forcing enforced by wave refraction across an offshore bathymetric anomaly. These simulations are qualitatively corroborated by video observations of sandbar behavior during a down‐state sequence at a site with a persistent offshore trough. Key Points For a given wave forcing rip channels can self‐organize into different patterns Updrift and downdrift rip channel behaviors are different An offshore anomaly influences surf zone rip migration and spacing
ISSN:0148-0227
2169-9003
2156-2202
2169-9011
DOI:10.1029/2011JF002141