Abstract
To develop beach engineering, the submerged structure’s primary physical functions have to be understood. This study focuses on submerged structures in order to understand the strategy of reduced wave energy, stabilizing the shoreline and not generating erosion or adversely modifying coastal processes. Important developments have been made since the 1990s, taking into account the functions of recreational amenity. However, non-dimensional models cannot explain the physical mechanisms that generate accretion or erosion morphological features in the lee of the submerged structure. The present study aims to collaborate with the understanding of the mechanism of beach response to a submerged structure. For this, 26 surveys were made using topographic, Lagrangian, and Eulerian hydrodynamic measures during one seasonal cycle of a beach system from Rio de Janeiro (Brazil) with a natural submerged reef or rocky bank V-shape in the plan. This beach system is energetic and intermediate when referring to wave energy conditions and beach states, respectively. The wave breaking vector system on the rocky bank’s geometry was examined in the intermediate and dissipative beach morphodynamic organization. The variability of the wave breaking vector system determines the establishment, deformation, and erosion features in the lee of the structure. During high-energy waves, the submerged structure’s hydrodynamic and morphodynamic processes are transparent. When the submerged structure combines with the dissipative beach state, the surfing wave conditions are improved. These results provide the dimensional and positional references for an engineering proposal for a beach system.
Highlights
IntroductionThe large amount of temporal and spatial coastal diversity around the world makes coasts potential natural laboratories for beach dynamic studies [1,2,3,4,5,6,7,8], helping to improve the knowledge of shoreline adjustment for different coastal features [9,10,11]
Observing natural processes is one of the best ways to develop engineering
The present study aims to determine the mechanism of beach response to a multifunctional coastal submerged structure through data collection at a highly dynamic beach system with a natural submerged rocky bank V-shape in plan
Summary
The large amount of temporal and spatial coastal diversity around the world makes coasts potential natural laboratories for beach dynamic studies [1,2,3,4,5,6,7,8], helping to improve the knowledge of shoreline adjustment for different coastal features [9,10,11]. Climate change makes it increasingly urgent to find coastal engineering solutions that could help control the coastal dynamics, thereby solving or reducing erosion problems [12]. Interest in submerged coastal engineering has increased over the last decade due to multi-purposing [9], such as coastal protection and public amenities [13,14,15,16,17,18].
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