EFFECTIVENESS OF CORAL REEF RESTORATION IN WAVE ATTENUATION APPLICATIONS

Justin Geldard, Ryan Lowe, Scott Draper, Marco Ghisalberti, Sonia Westera, George Ellwood, Michael Cuttler, David Smith, Alicia McArdle
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Abstract

Coral reefs are not only one of the most biologically diverse ecosystems, but they also deliver critical ecosystem services to millions of people worldwide, for example coastal hazard mitigation. Extreme surface waves associated with storm systems generate coastal flooding and erosion that can impact coastal populations and infrastructure. The large roughness of healthy coral reefs has the potential to significantly attenuate this wave energy prior to reaching the shoreline through the drag forces that coral roughness exerts on the water column. The magnitude of these drag forces is dependent on how the complex geometries of corals interact with wave-driven oscillatory flows. This interaction is most commonly described both physically and numerically with idealised models of canopies, typically using arrays of submerged cylinders that lack the natural complexity of coral reef roughness. A physical modelling approach with a canopy of complex coral shapes is needed to sufficiently investigate the properties of the canopy which best represent their interaction with wave-driven oscillatory flows resulting in the attenuation of wave energy. In this study we investigated the performance of a coral reef restoration approach developed by MARS Inc. to attenuate wave energy across a range of incident wave conditions, water depths and coral cover.
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珊瑚礁恢复在波浪衰减应用中的有效性
珊瑚礁不仅是最具生物多样性的生态系统之一,而且还为全世界数百万人提供关键的生态系统服务,例如减轻沿海灾害。与风暴系统相关的极端表面波会导致沿海洪水和侵蚀,从而影响沿海人口和基础设施。健康珊瑚礁的大粗糙度有可能通过珊瑚粗糙度对水柱施加的阻力,在到达海岸线之前显着减弱这种波浪能量。这些阻力的大小取决于珊瑚复杂的几何形状如何与波浪驱动的振荡流相互作用。这种相互作用最常见的描述是物理和数值上的理想冠层模型,通常使用水下圆柱体阵列,缺乏珊瑚礁粗糙度的自然复杂性。需要一种具有复杂珊瑚形状的冠层的物理建模方法来充分研究冠层的特性,这些特性最能代表它们与波浪驱动的振荡流的相互作用,从而导致波浪能量的衰减。在这项研究中,我们调查了由MARS公司开发的珊瑚礁恢复方法的性能,该方法可以在一系列入射波条件、水深和珊瑚覆盖范围内衰减波浪能量。
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