Beach Morphodynamic Response to a Submerged Reef

Nemes, Douglas Duarte; Criado-Sudau, Francisco Fabián; Gallo, Marcos Esteban

doi:10.3390/w11020340

Cited by 12 publications

(13 citation statements)

References 31 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…They are among the most diverse and productive ecosystems of the oceans since they provide a large number of goods and services such as food, habitat, biodiversity, tourism, recreation, shoreline protection, and erosion regulation [1]. In particular, coral reefs play an important role in coastal areas acting as natural breakwaters that can dissipate up to 97% incident wave energy [2] controlling the shoreline evolution in their lee [3]. In addition, taking into account that low-crested detached breakwaters generate a wave height reduction of 30%-70% [4][5][6], the wave dissipation effect of coral reefs is generally similar or even larger than conventional structures.…”

Section: Introductionmentioning

confidence: 99%

Impact of Climate Change on Nearshore Waves at a Beach Protected by a Barrier Reef

Lalouvière

Gràcia

Sierra

et al. 2020

Water

View full text Add to dashboard Cite

Barrier reefs dissipate most incoming wind-generated waves and, as a consequence, regulate the morphodynamics of its inbounded shorelines. The coastal protective capacity of reefs may nevertheless be compromised by climate change effects, such as reef degradation and sea-level rise. To assess the magnitude of these climate change effects, an analysis of the waves propagating across the barrier reef is carried out in Flic-en-Flac beach, Mauritius, based on scenarios of future sea levels and predicted coral reef condition. In the study, both the mean wave climate and extreme event conditions are considered. The results show that lower coral structure complexity jointly with higher water levels allow for higher waves to pass over the reef and, therefore, to reach the shoreline. In addition, modeling for cyclonic conditions showed that nearshore waves would also increase in height, which could lead to major coastal morphodynamic changes. Measures aimed at preserving the coral reef may allow the system to accommodate for the gradual climatic changes forecasted while keeping its coastal protective function.

show abstract

Section: Introductionmentioning

confidence: 99%

Impact of Climate Change on Nearshore Waves at a Beach Protected by a Barrier Reef

Lalouvière

Gràcia

Sierra

et al. 2020

Water

View full text Add to dashboard Cite

show abstract

“…These circulations are essentially enforced by a strong alongshore differential broken wave energy dissipation. This contrasted with other, smoother, SBWs where the control of nearshore hydrodynamics was more subtle [59].…”

Section: Discussionmentioning

confidence: 75%

Modeling the Impact of the Implementation of a Submerged Structure on Surf Zone Sandbar Dynamics

Bouvier

Castelle

Balouin³

2019

JMSE

View full text Add to dashboard Cite

Coastal defense strategies based on structures are increasingly unpopular as they are costly, leave lasting scars on the landscape, and sometimes have limited effectiveness or even adverse impacts. While a clear improvement concerning aesthetic considerations using soft submerged breakwater is undeniable, their design has often focused on wave transmission processes across the crest of the structure, overlooking short- to medium-term morphodynamic responses. In this study, we used a time- and depth-averaged morphodynamic model to investigate the impact of the implementation of a submerged breakwater on surf zone sandbar dynamics at the beach of Sète, SE France. The hydrodynamic module was calibrated with data collected during a field experiment using three current profilers deployed to capture rip-cell circulation at the edge of the structure. The model showed good agreement with measurements, particularly for the longshore component of the flow (RMSE = 0.07 m/s). Results showed that alongshore differential wave breaking at the edge of the submerged breakwater drove an intense (0.4 m/s) two-dimensional circulation for low- to moderate-energy waves. Simulations indicated that inner-bar rip channel development, which was observed prior to the submerged reef implementation, was inhibited in the lee of the structure as rip-cell circulation across the inner bar disappeared owing to persistently low-energy breaking waves. The cross-shore sandbar dynamics in the lee of the structure were also impacted due to the drastic decrease of the offshore-directed flow over the inner-bar during energetic events. This paper highlights that implementation of a submerged breakwater results in larges changes in nearshore hydrodynamics that, in turn, can affect overall surf zone sandbar behavior.

show abstract

“…The breakwater design needs to be adapted to the local bathymetry and its evolution. In addition, the implementation of such artificial structure will have important impact on the beach morphodynamics [57,58]. These issues, which are outside of the scope of the present paper, also need to be addressed with care.…”

Section: Discussionmentioning

confidence: 98%

A Numerical Assessment of Artificial Reef Pass Wave-Induced Currents as a Renewable Energy Source

Sous

2019

JMSE

View full text Add to dashboard Cite

The present study aims to estimate the potential of artificial reef pass as a renewable source of energy. The overall idea is to mimic the functioning of natural reef–lagoon systems in which the cross-reef pressure gradient induced by wave breaking is able to drive an outward flow through the pass. The objective is to estimate the feasibility of a positive energy breakwater, combining the usual wave-sheltering function of immersed breakwater together with the production of renewable energy by turbines. A series of numerical simulations is performed using a depth-averaged model to understand the effects of each geometrical reef parameter on the reef–lagoon hydrodynamics. A synthetic wave and tide climate is then imposed to estimate the potential power production. An annual production between 50 and 70 MWh is estimated.

show abstract

Beach Morphodynamic Response to a Submerged Reef

Cited by 12 publications

References 31 publications

Impact of Climate Change on Nearshore Waves at a Beach Protected by a Barrier Reef

Impact of Climate Change on Nearshore Waves at a Beach Protected by a Barrier Reef

Modeling the Impact of the Implementation of a Submerged Structure on Surf Zone Sandbar Dynamics

A Numerical Assessment of Artificial Reef Pass Wave-Induced Currents as a Renewable Energy Source

Contact Info

Product

Resources

About