Compound effects in complex estuary-ocean interaction region under various combination patterns of storm surge and fluvial floods

IF 6 2区工程技术 Q1 ENVIRONMENTAL SCIENCES

Urban Climate Pub Date : 2024-11-01 DOI:10.1016/j.uclim.2024.102186

Zhaoli Wang , Yuhong Chen , Zhaoyang Zeng , Ruishuang Li , Zeyan Li , Xuefang Li , Chengguang Lai

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引用次数: 0

Abstract

Estuary-ocean interaction regions typically confront compound floods caused by multiple drivers. However, current researches on formation mechanism and compound effect of such disaster remain inadequately profound. Therefore, this study proposed a framework to evaluate the encountering rules and hazards of compound flood based on Copula theory and hydrodynamic model. Taking Pearl River Delta (PRD) in China as a case study, the compound flood hazards under different joint scenarios with various drivers were analyzed. The results indicated that concurrent fluvial floods and storm surge will result in higher flood hazards than single driver. The simulated water levels in most areas of the PRD demonstrated a pattern that water levels of Survival Kendall Return period are greater than that of Kendall Return period, and water levels of AND Return period are the lowest. Flood hazards induced by two drivers with moderate magnitude may be more serious than one extreme event in estuary-ocean interaction region. Neglecting the combination compound effects of storm surge and fluvial flood may underestimate the flood hazards in coastal areas. Our findings yield valuable insights to compound flood hazards and provide scientific guidance for prevention and adaption of compound flood disasters in estuary-ocean interaction region.

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风暴潮和河道洪水各种组合模式下复杂河口-海洋相互作用区域的复合效应

河口-海洋相互作用地区通常会面临由多种驱动因素引发的复合型洪灾。然而，目前对此类灾害的形成机理和复合效应的研究仍不够深入。因此，本研究提出了一个基于 Copula 理论和水动力模型的复合洪水成灾规律及危害评价框架。以中国珠江三角洲（PRD）为案例，分析了不同驱动因素共同作用下的复合洪水灾害。结果表明，与单一驱动因素相比，同时发生的河漫滩洪水和风暴潮将导致更高的洪水危害。珠江三角洲大部分地区的模拟水位表现出 "肯德尔重现期 "的水位大于 "肯德尔重现期 "的水位，而 "安德重现期 "的水位最低。在河口-海洋相互作用地区，两个中等程度的驱动因素所引发的洪水灾害可能比一个极端事件更为严重。忽视风暴潮和河流洪水的复合效应可能会低估沿海地区的洪水灾害。我们的研究结果对复合洪水灾害提出了有价值的见解，为河口-海洋相互作用区复合洪水灾害的预防和适应提供了科学指导。

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来源期刊

Urban Climate Social Sciences-Urban Studies

CiteScore

9.70

自引率

9.40%

发文量

286

期刊介绍： Urban Climate serves the scientific and decision making communities with the publication of research on theory, science and applications relevant to understanding urban climatic conditions and change in relation to their geography and to demographic, socioeconomic, institutional, technological and environmental dynamics and global change. Targeted towards both disciplinary and interdisciplinary audiences, this journal publishes original research papers, comprehensive review articles, book reviews, and short communications on topics including, but not limited to, the following: Urban meteorology and climate[...] Urban environmental pollution[...] Adaptation to global change[...] Urban economic and social issues[...] Research Approaches[...]