Bin Zhang , Jianhong Ye , Haoran Zhou , Dong-Sheng Jeng , Yakun Guo
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引用次数: 0
Abstract
The South China Sea (SCS), located at the intersection of two major tectonic plates and near the Manila Fault Zone, is a region highly susceptible to earthquakes and tsunami activities. To develop a more comprehensive and reliable understanding of tsunami behaviours over coral reefs, this study employs the actual topography of a coral reef in the SCS and N-wave theory for the numerical simulation, encompassing the entire tsunami life cycle. Utilizing the open-source solver OlaFlow, driven by the Reynolds-averaged Navier-Stokes (RANS) equations, this study performs a series of numerical simulations of N-wave tsunamis considering the measured topography of the coral reef, as well as the real dimension of an engineering defence structure on the top of the coral reef. The adopted tsunami parameters are equivalent to an earthquake with a moment magnitude of 7.1. The simulations focus on the impact of wave profiles and initial static water levels on the propagation and evolution of tsunamis. Numerical simulations reveal that tsunami profiles, water depth, and topography significantly influence the tsunami dynamics, notably in the waveform transformation, the relationship between wave height and trough-to-peak ratio, and the topographic effects on the wave energy dissipation. These results highlight the critical need to incorporate factors such as tsunami profiles, dispersion, and realistic topography into tsunami predictive models for the purpose of more reliable hazard evaluation and the development of effective coastal defences.
中国南海(SCS)位于两大板块交汇处,靠近马尼拉断裂带,是地震和海啸活动的高发区。为了更全面、更可靠地了解珊瑚礁上的海啸行为,本研究采用了南中国海珊瑚礁的实际地形和 N 波理论进行数值模拟,涵盖了整个海啸生命周期。本研究利用由雷诺平均纳维-斯托克斯(RANS)方程驱动的开源求解器 OlaFlow,对 N 波海啸进行了一系列数值模拟,考虑了珊瑚礁的实测地形以及珊瑚礁顶部工程防御结构的实际尺寸。所采用的海啸参数相当于时刻震级为 7.1 级的地震。模拟的重点是波浪剖面和初始静态水位对海啸传播和演变的影响。数值模拟显示,海啸剖面、水深和地形对海啸动力学有重大影响,特别是在波形转换、波高与波谷-波峰比之间的关系以及地形对波能消散的影响方面。这些结果突出表明,为了进行更可靠的灾害评估和建立有效的海岸防御工事,亟需将海啸剖面、扩散和实际地形等因素纳入海啸预测模式。
期刊介绍:
Coastal Engineering is an international medium for coastal engineers and scientists. Combining practical applications with modern technological and scientific approaches, such as mathematical and numerical modelling, laboratory and field observations and experiments, it publishes fundamental studies as well as case studies on the following aspects of coastal, harbour and offshore engineering: waves, currents and sediment transport; coastal, estuarine and offshore morphology; technical and functional design of coastal and harbour structures; morphological and environmental impact of coastal, harbour and offshore structures.