Solitary wave transformation, breaking and run-up at a beach

doi:10.1680/maen.2006.159.3.97

Solitary wave transformation, breaking and run-up at a beach

Authors: A. G. L. Borthwick ¹ ; M. Ford ² ; B. P. Weston ¹ ; P. H. Taylor ¹ ; P. K. Stansby ³
Source: Proceedings of the ICE - Maritime Engineering, Volume 159, Issue 3, pages 97 –105 , ISSN: 1741-7597, E-ISSN: 1751-7737

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In this subject: Water and Wastewater, Maritime, Sitework
By this author: A. G. L. Borthwick , M. Ford , B. P. Weston , P. H. Taylor , P. K. Stansby

A validated one-dimensional Boussinesq–non-linear shallow water equations numerical model was used to investigate the interaction of solitary waves with beaches. The numerical model requires two adjustable parameters: the bed friction coefficient and a wave breaking parameter. Excellent agreement was achieved between the numerical predictions of solitary wave transformation and run-up at a plane beach with two sets of high-quality laboratory measurements: one a large number of experiments in a wave flume by Synolakis, the other in the UK Coastal Research Facility. A parameter study investigated the effect of uniform offshore water depth, bed friction and bed slope on solitary wave run-up. A uniform water depth may be associated with a continental shelf region. The non-dimensional run-up was found to be an asymptotic function of non-dimensional wave amplitude at high and low values of initial wave steepness. Both asymptotes scale as (R/h _o)~α(A _o/h _o)^β where R is run-up (defined as the vertical elevation reached by the wave uprush above still water level), A _o is the offshore wave amplitude and h _o is the uniform depth offshore of the beach. The empirical coefficients α and β depend on the beach characteristics. The model is then used to simulate the interaction of a full-scale tsunami event with an idealised beach profile representative of a beach in Eastern Kamchatka.

Keywords: safety & hazards; sea defences; coastal engineering
Document Type: Research Article
DOI: 10.1680/maen.2006.159.3.97
Affiliations: 1: Department of Engineering Science, University of Oxford UK; 2: Arup, Solihull West Midlands, UK; 3: School of Mechanical, Aerospace and Civil Engineering and Tyndall Centre for Climate Change Research, University of Manchester UK

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Solitary wave transformation, breaking and run-up at a beach