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The influence of sea state on formation speed of alongshore variability in surf zone sand bars
Abstract The formation time of alongshore morphological variability in surf zone sand bars has long been known to differ from one beach to the other and from one post-storm period to another. Here we investigate whether the type of sea state, i.e. distant swell waves or locally generated short period wind sea, affects the formation time of the emerging alongshore topographic variability. A numerical modeling approach is used to examine the emergence of alongshore variability under different shore-normal wave forcing. A research version of Delft3D, operating on the time-scale of wave groups, is applied to a schematised bathymetry with a single bar. The model is then used to investigate several wave scenarios, examining the impact of peak period, frequency spread and directional spread on the formation time of alongshore variability. Results show that an increase in wave period has a large effect, changing the formation time up to O (250%) in case the wave period is changed from a representative value for the Dutch coast (Tp ~5–6s) to an Australian South East coast value (Tp ~10–12s). In contrast, modifications in the directional and frequency spread of the wave field result only in a minor change in the formation time. Examination of hydrodynamics and potential sediment transport shows that the variations in formation time are primarily related to changes in the magnitude of the time-averaged flow conditions. Variations in the magnitude of very low frequency (f <0.004Hz) or infragravity (0.004< f <0.04Hz) surf zone flow velocities do not affect the mean sediment transport capacity. Consequently the formation speed of patterns is primarily governed by positive feedback between mean flow and morphology, and low frequency flow fluctuations are of minor importance. These findings indicate that the development of alongshore topographic variability may be faster at swell dominated open coasts, primarily due to the occurrence of longer period swell. Also, at a given site, the arrival of a long wave period swell after a storm can accelerate the emergence of variability.
Highlights The emergence of alongshore variability is investigated for different sea states. Formation is found to be substantially faster under swell waves than wind sea. An increase in wave period results in an increase in formation speed. Frequency and directional spread alone have only little effect on formation speed. Magnitudes of low frequency flow oscillations do not affect the formation time.
The influence of sea state on formation speed of alongshore variability in surf zone sand bars
Abstract The formation time of alongshore morphological variability in surf zone sand bars has long been known to differ from one beach to the other and from one post-storm period to another. Here we investigate whether the type of sea state, i.e. distant swell waves or locally generated short period wind sea, affects the formation time of the emerging alongshore topographic variability. A numerical modeling approach is used to examine the emergence of alongshore variability under different shore-normal wave forcing. A research version of Delft3D, operating on the time-scale of wave groups, is applied to a schematised bathymetry with a single bar. The model is then used to investigate several wave scenarios, examining the impact of peak period, frequency spread and directional spread on the formation time of alongshore variability. Results show that an increase in wave period has a large effect, changing the formation time up to O (250%) in case the wave period is changed from a representative value for the Dutch coast (Tp ~5–6s) to an Australian South East coast value (Tp ~10–12s). In contrast, modifications in the directional and frequency spread of the wave field result only in a minor change in the formation time. Examination of hydrodynamics and potential sediment transport shows that the variations in formation time are primarily related to changes in the magnitude of the time-averaged flow conditions. Variations in the magnitude of very low frequency (f <0.004Hz) or infragravity (0.004< f <0.04Hz) surf zone flow velocities do not affect the mean sediment transport capacity. Consequently the formation speed of patterns is primarily governed by positive feedback between mean flow and morphology, and low frequency flow fluctuations are of minor importance. These findings indicate that the development of alongshore topographic variability may be faster at swell dominated open coasts, primarily due to the occurrence of longer period swell. Also, at a given site, the arrival of a long wave period swell after a storm can accelerate the emergence of variability.
Highlights The emergence of alongshore variability is investigated for different sea states. Formation is found to be substantially faster under swell waves than wind sea. An increase in wave period results in an increase in formation speed. Frequency and directional spread alone have only little effect on formation speed. Magnitudes of low frequency flow oscillations do not affect the formation time.
The influence of sea state on formation speed of alongshore variability in surf zone sand bars
de Schipper, Matthieu A. (author) / Reniers, Ad J.H.M. (author) / Ranasinghe, Roshanka (author) / Stive, Marcel J.F. (author)
Coastal Engineering ; 91 ; 45-59
2014-05-05
15 pages
Article (Journal)
Electronic Resource
English
The influence of sea state on formation speed of alongshore variability in surf zone sand bars
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