Print Email Facebook Twitter Repeatability of beach morphology change under identical wave forcing Title Repeatability of beach morphology change under identical wave forcing Author Blenkinsopp, Chris E. (University of Bath) Hunter, Alan J. (University of Bath) Baldock, Tom E. (University of Queensland) Bayle, P.B. (TU Delft Environmental Fluid Mechanics; University of Bath) Bosboom, J. (TU Delft Coastal Engineering) Conley, Daniel (Plymouth University) Masselink, Gerd (Plymouth University) Date 2024 Abstract Laboratory investigations of beach morphology change under wave action are undertaken to gain insight into coastal processes, design coastal structures and validate the predictions of numerical models. For the results of such experiments to be reliable, it is necessary that they are repeatable. The equilibrium beach concept, that beach morphology will evolve to a quasi-static equilibrium shape for a given forcing suggests that experiments should be repeatable to some degree. However, sediment transport in turbulent breaking and broken waves is complex and highly variable and the level of repeatability at different temporal and spatial scales is challenging to measure, as such, previous work has restricted comparisons to small numbers of waves. Here we use the results of two identical, 20-h large-scale wave flume experiments to investigate the repeatability of sediment transport and beach morphology change under waves at timescales down to individual swash events. It is shown that while flow characteristics from identical swash events are very repeatable, the sediment transported can be very different in both magnitude and direction due to differences in turbulence, sediment advection and morphological feedback. Over longer periods containing multiple matching swash events however, the beach responds in a very similar manner, with the level of morphological repeatability increasing with time. The results also demonstrate that gross swash zone sediment transport remains high even as a beach profile approaches quasi-equilibrium, but the proportion of individual swash events that cause large sediment fluxes (>±7.5 kg/event/m) reduces with time. The results of this laboratory study indicate that beach morphology change has a level of determinism over timescales of several minutes and longer, giving confidence in the results from physical modelling studies. However, the large differences in sediment transport from apparently identical swash events questions the value in pursuing numerical predictions of sediment transport at the wave-by-wave timescale unless the reversals in sediment transport between apparently near identical swash events can also be predicted. To reference this document use: http://resolver.tudelft.nl/uuid:d51ff694-d672-4d8c-b7dd-7e60fbd38bb6 DOI https://doi.org/10.1016/j.coastaleng.2024.104485 ISSN 0378-3839 Source Coastal Engineering, 189 Part of collection Institutional Repository Document type journal article Rights © 2024 Chris E. Blenkinsopp, Alan J. Hunter, Tom E. Baldock, P.B. Bayle, J. Bosboom, Daniel Conley, Gerd Masselink Files PDF 1-s2.0-S0378383924000334-main.pdf 9.14 MB Close viewer /islandora/object/uuid:d51ff694-d672-4d8c-b7dd-7e60fbd38bb6/datastream/OBJ/view