Estuarine hurricane wind can intensify surge-dominated extreme water level in shallow and converging coastal systems

Natural Hazards and Earth System Sciences Pub Date : 2024-07-19 DOI:10.5194/nhess-24-2461-2024

Mithun Deb, James J. Benedict, Ning Sun, Zhaoqing Yang, R. Hetland, D. Judi, Taiping Wang

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引用次数: 1

Abstract

Abstract. Based on the projected increase in hurricane landfall frequency on the middle to lower US east coast, we examined the crucial role of the estuarine wind field in exacerbating coastal flooding. A regionally refined atmospheric and two high-resolution hydrology and ocean models are integrated to provide plausible and physically consistent ensembles of hurricane events and the associated flooding inside the Delaware Bay and River, a US mid-Atlantic estuary. Model results show that the hurricane propagation direction, estuarine geometry, remote surge from the open ocean, and direct nearshore upwind stress could magnify the flood magnitude. More specifically, inland-bound tracks that make landfall before reaching the mid-Atlantic coast produce a more significant surge within Delaware Bay than the shore-parallel tracks, where the estuarine wind direction plays the primary role in surge amplification. Ultimately, this study emphasized the need for integrated models to capture the nonlinear dynamics and interactions in flood hazard modeling.

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河口飓风会加剧以浪涌为主的浅海和汇合沿岸系统的极端水位

摘要根据飓风登陆美国东海岸中下游频率增加的预测，我们研究了河口风场在加剧沿岸洪水中的关键作用。我们将一个区域精细大气模型和两个高分辨率水文及海洋模型进行了整合，以提供飓风事件及美国大西洋中部河口特拉华湾和特拉华河内相关洪水的可信且物理上一致的集合。模型结果表明，飓风的传播方向、河口几何形状、来自公海的远距离浪涌以及直接的近岸上风压力都会放大洪水的规模。更具体地说，与平行于海岸的飓风路径相比，在到达大西洋中部海岸之前登陆的内陆路径会在特拉华湾产生更显著的浪涌，而在内陆路径中，河口风向是浪涌放大的主要因素。最终，这项研究强调了综合模型的必要性，以捕捉洪水灾害建模中的非线性动态和相互作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Natural Hazards and Earth System Sciences

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