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

Clément Bouvier,Yann Balouin,Bruno Castelle

doi:10.3390/jmse7040117

Abstract

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.

Highlights

Coastal protection hard structures such as groynes, breakwaters, seawalls, and revetments have been implemented worldwide to limit coastal erosion and to provide flooding protection to the hinterland [1,2]
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
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

Summary

Introduction

Coastal protection hard structures such as groynes, breakwaters, seawalls, and revetments have been implemented worldwide to limit coastal erosion and to provide flooding protection to the hinterland [1,2]. A proper understanding of the effects of SBWs on nearshore waves and horizontal circulation is necessary for the calculation of sediment transport and morphological evolution [16,17] These structures result in wave energy dissipation through depth-induced wave breaking. At the alongshore edges of the SBW, adjacent regions of breaking and non-breaking waves form a large differential in wave forcing and, in turn, a vertical vorticity forcing [18], which is key to rip-flow circulation formation [19] This results in two-dimensional horizontal (2DH) flow and sediment transport patterns [17]. Results indicated that shoreline response to SBW implementation was governed by 2DH nearshore circulation patterns, consisting of longshore flows in the lee of the structures, and offshore flow outside.

Numerical Morphodynamic Model

Residual and Vorticity Forcing

Wave-Driven Circulation Measurements