非线性潮汐-河涌相互作用及其对珠江三角洲台风 "哈托 "期间复合洪水的影响

IF 3.3 2区 地球科学 Q1 OCEANOGRAPHY
Haoxuan Du, Kai Fei, Liang Gao
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引用次数: 0

摘要

在沿海地区,多种水动力过程同时发生,包括天文潮汐、河流排水和风暴潮。它们在沿海潮汐河流中的传播和相互作用导致了内陆地区强烈的非线性行为。本研究采用水动力模型和连续小波变换分析,研究了在极端台风事件中复杂的潮汐-河流-风暴潮相互作用及其对珠江三角洲西江复合洪水的影响。经过验证的模型输出结果提供了有关河流排泄量、水位和水流时空变化的见解。小波分析表明,河流排水量调节潮汐特性,导致非稳态潮汐和不对称,大流量抑制了潮汐范围,但促进了过潮时的能量转移。在台风 "哈托 "期间,风暴潮主导了高频水位波动,并迅速向上游传播。最重要的是,高频潮汐-河流-风暴潮的强耦合作用引起了水位的显著放大,相互作用的强度向陆地方向增加。在河流和海岸驱动因素交汇的上游地区,由于这种强烈的多驱动因素复合作用,洪水风险超过了通常的估计值。研究结果突显了现有的洪水减灾方法如何过于简单地叠加单个洪水源,从而忽略了这种非线性相互作用,严重低估了洪水位。全面考虑潮汐、排水、风暴潮和海平面上升的累积乘法效应势在必行。这种对关键物理驱动因素的定量分析提供了适用于复合洪水风险评估和政策指导的可转移见解,以提高其他河口和三角洲地区的抗灾能力。未来的工作重点应放在多变量极端事件及其相互作用的整体建模上。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Nonlinear Tide-River-Surge Interactions and Their Impacts on Compound Flooding During Typhoon Hato in the Pearl River Delta

Nonlinear Tide-River-Surge Interactions and Their Impacts on Compound Flooding During Typhoon Hato in the Pearl River Delta

In coastal areas, multiple hydrodynamic processes co-occur, including the astronomical tide, river discharge, and storm surge. Their propagation and interaction within coastal tidal river result in strong nonlinear behavior in inland areas. This study employed a hydrodynamic model and continuous wavelet transform analysis to investigate the complex tide-river-surge interactions and their impacts on compound flooding in the West River of the Pearl River Delta during an extreme typhoon event. Validated model outputs provided insights into the spatial and temporal variations of river discharge, water levels, and currents. Wavelet analysis revealed river discharge modulates tidal properties, causing nonstationary tides and asymmetries, with high flows suppressing tidal ranges but facilitating energy transfers to overtides. During Typhoon Hato, storm surges dominated high-frequency water level fluctuations that rapidly propagated upstream. Crucially, strong high-frequency tide-river-surge coupling induced significant water level amplifications, with interaction intensities increasing landward. In upstream areas where riverine and coastal drivers converged, flood risks exceeded typical estimates due to this vigorous multi-driver compounding. Findings highlighted how existing flood mitigation approaches over simplistically superposing individual sources may severely underestimate flood levels by neglecting such nonlinear interactions. A comprehensive accounting of the cumulative, multiplicative effects of tides, discharge, storm surge, and sea level rise is imperative. This quantitative unraveling of key physical drivers offers transferable insights applicable to compound flood risk evaluations and policy guidance for enhancing resilience in other estuary and delta regions. Future work should focus on holistically modeling multivariate extremes and their interactions.

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来源期刊
Journal of Geophysical Research-Oceans
Journal of Geophysical Research-Oceans Earth and Planetary Sciences-Oceanography
CiteScore
7.00
自引率
13.90%
发文量
429
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