Swash-by-swash morphology change on a dynamic cobble berm revetment: High-resolution cross-shore measurements

Paul M. Bayle, Chris E. Blenkinsopp, Kévin Martins, George M. Kaminsky, Heather M. Weiner, David Cottrell

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Abstract

Dynamic cobble berm revetments are a promising soft engineering technique capable of protecting sandy coastlines by armouring the sand and dissipating wave energy to protect the hinterland against wave attack. They also form composite beaches as they are essentially mimicking natural composite beach structure and behaviour. This type of coastal protections and beaches have recently been investigated, and this led to a better understanding of their overall behaviour under varying water levels and wave conditions. However, the short-term dynamics of the swash zone (where all bed changes occur) has never been studied at high-resolution, and this is needed to fully understand the underlying dynamics of such structures and relate it to observed processes at larger scale. To do so, the revetment at North Cove (WA, USA) was monitored for a nine-day period in January 2019 over a spring tidal cycle and with offshore significant wave height reaching 6 m. A 2-D lidar was used to survey a cross-shore profile of the revetment, and record all surface changes and interaction with swashes at high spatial (0.1 m) and temporal (swash-by-swash) resolution. The revetment was found to rapidly reshape under these energetic conditions, but reached a relatively stable state during the rising tide. The analysis of bed-level changes and net cross-shore mass fluxes over the revetment showed that revetment changes are mainly driven by very small events, with some rare large bed-level changes of a magnitude comparable to the median cobble diameter. The distribution of event mass fluxes nearly balanced out over the duration of a tide, meaning that positive and negative fluxes tended to be symmetrical. Furthermore, measured net fluxes magnitude were 18 times smaller than the absolute fluxes, which demonstrated the dynamic stability of the revetment as substantial movement occur on a wave-by-wave timescale but these balance out over time. The analysis of swash revealed that the revetment section where the swash reaches a maximum depth between 0.15 and 0.45 m undergoes the more extreme fluxes. Swashes deeper than 0.45 m only occurred in zones inundated more than 50% of the time, and smaller extreme fluxes were measured over the revetment section where these deep swashes were recorded. Bed level change oscillations over the revetment were observed, and the cross shore limit of these was correlated with the mean wave period at the toe of the revetment. Overall, the water depth at the toe of the revetment was identified as the key parameter to describe the energy reaching the revetment. This study enables the morphodynamics of dynamic revetment, observed in previous lab and field studies, to be explained at the swash scale, and brought new information on the sediment dynamics of composite beaches and dynamic revetments. These findings allow to suggest some generic guidance for dynamic cobble berm revetment design. Finally, the results are compared to a similar study on sandy beaches.

Original languageEnglish
Article number104341
JournalCoastal Engineering
Volume184
Early online date5 Jun 2023
DOIs
Publication statusPublished - 30 Sept 2023

Data Availability Statement

Data will be made available on request

Acknowledgements

The authors want to thank the entire Washington Department of Ecology CMAP team, for their logistical support in the field. The authors would also like to thank the community of North Cove for their warm welcome and support throughout the experiment. Special thanks to Richard and Dianne Harris for providing a warm and dry place during the experiment, and to Connie Allen for organising the communication and public relations around the experiment. Finally, we thank William Bazeley, Neil Price, Robert Dyer and David Surgenor from the University of Bath for their technical support during the experiment preparation.

Keywords

  • Dynamic cobble berm revetment
  • Lidar
  • Morphodynamics
  • Sediment fluxes
  • Swash processes

ASJC Scopus subject areas

  • Environmental Engineering
  • Ocean Engineering

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