A Comparison of Beach Nourishment Methodology and Performance at Two Fringing Reef Beaches in Waikiki (Hawaii, USA) and Cadiz (SW Spain)

Muñoz-Pérez

et al. 2020

JMSE

Self Cite

The southwestern coast of Spain is in a tidal zone (mesotidal) which causes the equilibrium profile to be developed in two different sections: the breakage section and the swash section. These two sections give rise to the typical bi-parabolic profile existing in tidal seas. The existence of areas with reefs/rocks which interrupt the normal development of the typical bi-parabolic profile causes different types of beach profiles. The objective of this article is designing an easy methodology for determining new formulations for the design parameters of the equilibrium profile of beaches with reefs in tidal seas. These formulations are applied on 16 profiles to quantify the error between the real profile data and the modelling results. A comparative analysis is extended to the formulations proposed by other authors, from which it is found that better results are obtained with the new formulations.

Section: Methodsmentioning

confidence: 99%

A Design Parameter for Reef Beach Profiles—A Methodology Applied to Cadiz, Spain

Muñoz-Pérez

et al. 2020

JMSE

Self Cite

Science of The Total Environment

“…leaky systems), which is likely to increase in nourished geologically controlled beaches. The adjustment of a nourished beach profile when there are cross-shore geological constraints is also likely to depart from theoretical models of cross-shore sediment redistribution used in coastal engineering (Muñoz-Perez et al, 2020). Scaling up to a local sediment cell, there is scant understanding of and limited modelling tools to predict the rates of sediment transport from geologically controlled beaches to other coastal systems, or between these beaches (Naylor et al, 2016).…”

Section: Management Of Geologically Controlled Beachesmentioning

confidence: 99%

“…For example, a geologically controlled beach might be an important supply of sediment to a nearby spit (as in Westward Ho!, North Devon, UK), but we have limited understanding of the process and of how much geologically controlled beach material serves as a key source of sediment to an economically and socially valuable beach spit. Moreover, it is largely unclear how to account for spatial variations in geological controls to quantify beach nourishment volumes and costs, and how to include the effect of this variation on the beach morphodynamics and hence nourishment performance and longevity (Muñoz-Perez et al, 2020).…”

Section: Management Of Geologically Controlled Beachesmentioning

confidence: 99%

Geologically controlled sandy beaches: Their geomorphology, morphodynamics and classification

Gallop

Kennedy

Loureiro

et al. 2020

Self Cite

Beaches that are geologically controlled by rock and coral formations are the rule, not the exception. This paper reviews current understanding of geologically controlled beaches, bringing together a range of terminologies (including embayed beaches, shore platform beaches, relict beaches, and perched beaches among others) and processes, with the aim of exploring the multiple ways in which geology influences beach morphology and morphodynamics. We show how in addition to sediment supply, the basement geology influences where beaches will form by providing accommodation, and in the cross-shore, aspects of rock platform morphology such as elevation and slope are also important. Geologically controlled beaches can have significant variations in sediment coverage with seasons and storms, and geological controls have fundamental influences on their contemporary morphodynamics. This includes wave shadowing by headlands and rocky/coral formations inducing strong alongshore gradients in wave energy, resulting in corresponding variations in morphodynamic beach state and storm response. Geologically-induced rip currents such as shadow rips and deflection rips, and even mega-rips that can develop on embayed beaches during storms, are an integral feature of the nearshore circulation and morphodynamics of geologically controlled beaches. We bring these processes together by presenting a conceptual model of alongshore and cross-shore levels of geological control. In the longshore dimension, this ranges from beaches that are slightly embayed, through to highly embayed beaches where headlands dominate the entire beach morphodynamic response. In the cross-shore dimension, this ranges from beaches without discernible geological controls, through to relict beaches above the influence of the contemporary littoral zone. Given the prevalence of geologically controlled beaches along the world's coasts, it is paramount for coastal management to consider how these beaches differ from unconstrained beaches and avoid applying inappropriate models and tools, especially with our uncertain future climate.

“…Thus, these studies suggest that the effect of reefs on beach dynamics is highly complex, and variable alongshore, even at a single beach. Moreover, while there has been extensive research on the cross-shore response of hydrodynamics over reefs, such as wave transformation [17][18][19], less attention has been paid to the overall alongshore variations in both cross-shore and longshore sediment transport [20] and the resulting beach dynamics. This is a complex task because, in addition to the cross-shore process of wave attenuation, the alongshore variability of reefs is a key factor in controlling sediment transport and beach morphodynamics drivers.…”

Section: Introductionmentioning

confidence: 99%

The Influence of Reef Topography on Storm-Driven Sand Flux

Bosserelle

Gallop

Haigh

et al. 2021

JMSE

Self Cite

Natural formations of rock and coral can support geologically controlled beaches, where the beach dynamics are significantly influenced by these structures. However, little is known about how alongshore variations in geological controls influence beach morphodynamics. Therefore, in this study we focus on the storm response of a beach (Yanchep in south Western Australia) that has strong alongshore variation in the level of geological control because of the heterogeneous calcarenite limestone reef. We used a modified version of XBeach to simulate the beach morphodynamics during a significant winter storm event. We find that the longshore variation in topography of the reef resulted in: (1) strong spatial difference in current distribution, including areas with strong currents jets; and (2) significant alongshore differences in sand flux, with larger fluxes in areas strongly geologically controlled by reefs. In particular, this resulted in enhanced beach erosion at the boundary of the reef where strong currents jet-exited the nearshore.