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    Coupling breakwalls with oyster restoration structures enhances living shoreline performance along energetic shorelines
    (Elsevier, 2020) Safak, I.; Norby, P. L.; Dix, N.; Grizzle, R. E.; Southwell, M.; Veenstra, J. J.; Acevedo, A.
    Interest and investment in constructing living shorelines rather than harder engineering structures are on the rise worldwide. However, the performance of these interventions in rejuvenating coastal habitats, depositing fine sediments with elevated organic content, and reducing erosion varies widely and is often low along energetic shorelines. In this study, we test the efficacy of a living shoreline design that couples breakwalls and oyster restoration structures, in protecting coastal estuarine ecosystems and their services along energetic shorelines. A field experiment was conducted between 2015 and 2019 along a section of the Atlantic Intracoastal Waterway in northeast Florida, which experiences commercial and recreational vessel traffic. We discovered that organic matter, silt and clay content all increased in sediments collected in the living shorelines compared to paired control treatments. In addition, oysters established and developed into robust reefs on the gabions - wire cages filled with seasoned oyster shells - that were used to facilitate oyster recovery within this living shorelines design, although oyster growth was highest where the gabions were placed at lower intertidal elevations. Additionally, salt marsh cordgrass along shoreline margins protected by the living shoreline structures remained stable or began advancing toward the Intracoastal Waterway channel at rates of similar to 1 m per year, whereas cordgrass in control treatments retreated at rates approaching 2 m per year. This study provides powerful evidence that vessel wake stress is indeed driving ecosystem loss and that simple nature-based living shoreline structures designed to dissipate this energy can slow or reverse ecosystem decline. More research is needed to optimize these nature-based solutions for shoreline protection in coastal and estuarine settings, and to improve their durability.
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    Wave transmission through living shoreline breakwalls
    (Pergamon-Elsevier Science Ltd, 2020) Safak, I.; Angelini, C.; Norby, P. L.; Dix, N.; Roddenberry, A.; Herbert, D.; Astrom, E.
    Living shorelines are being widely implemented to mitigate shoreline erosion and provide ecosystem services, but how they interact with waves remains poorly understood. Wave transmission through living shoreline breakwalls is studied using field observations and theoretical approaches. The following hypotheses are tested: (i) living shoreline breakwalls can act as buffers against waves; (ii) wave transmission through these nature -based solutions is modulated by tides; and (iii) wave transmission through living shoreline breakwalls is similar to the behavior observed in waves through porous breakwaters. Observations were collected in intertidal settings where boat wakes and tides are the major flow components. Nearly 1000 boat wakes were identified in the observations using advanced time-frequency data analysis methods. Wave transmission through the break -walls composed of tree branches was quantified and modulation of this process by tides was investigated. The two tested breakwall designs provided different behaviors of wave transmission. In the first design with an estimated porosity of 0.7 where the tree branches were bundled, transmission rates were found to vary mostly between 9% and 70% and had an average of 53%. Transmission increased with increasing water depth especially at mid-tide and low-tide where the height of the breakwall relative to depth was between 0.5 and 1. In the second design with an estimated porosity of 0.9 where the tree branches were not bundled, transmission rates exceeded 70% in 84% of the cases, sometimes reaching 100% transmission, and had an average of 83% with much less variability with depth compared to the first design. Wave transmission estimates based on theory of porous media were found to be most sensitive to breakwall porosity and the friction coefficient. Best agreement between the observed and theoretical estimates of wave transmission was found using a turbulent friction coefficient of 2.7, the median value of the most common range given in the literature on waves through porous media. The highest discrepancy between observed and theoretical estimates of wave transmission occurs at shallow depths when the breakwall emerged. In these conditions, the theory overestimates transmitted wave energy, most likely due to significant wave breaking and bottom friction in shallow water. The findings support our hypotheses that well-engineered semi-porous living shorelines act as buffers against human-mediated boat traffic and waves, and their related performance in dissipating wave energy and sustaining coastal ecosystems is modulated by depth. The results can be used as guidelines for design of living shorelines for given wave climate and breakwall properties.