Assessing the Effects of Climate Change on Compound Flooding in Coastal River Areas

Bermúdez, María; Farfán, Juan F.; Willems, Patrick; Cea, Luís

doi:10.1029/2020wr029321

Cited by 42 publications

(28 citation statements)

References 60 publications

(99 reference statements)

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“…Second, the quantitative stress test framework applied in this study can be viewed as a simplified and targeted climatological-hydrodynamic approach, which is originally proposed by Lin et al (2012). To our best knowledge, this climatological-hydrodynamic methodology tends to be a standard workflow to quantify how global warming affects the compound flood hazards caused by storm surge, sea-level rise, and extreme rainfall in coastal cities (Bermúdez et al, 2021;Ganguli et al, 2020;Garner et al, 2017;Gori et al, 2022;Lin & Emanuel, 2016;Marsooli et al, 2019;Marsooli & Lin, 2020;Rezaie et al, 2021). Instead of driving the hydrodynamic model by large ensembles of synthetic TCs, which are statistically generated from reanalysis or GCM-projected future climate, our framework is based on the physically consistent storylines depicting several worst-case scenarios, making it possible to achieve the same goal but at the minimal computational cost.…”

Section: Discussionmentioning

confidence: 99%

“…Bermúdez et al. (2021) employ a continuous simulation approach that considers seasonality and correlation between different flood drivers to assess compound flood hazards in Mandeo Delta under historical and future climates. The climatological‐hydrodynamic methodology used in these studies tend to be a standard framework to explore the impact of global warming on compound flood hazards in river deltas.…”

Section: Introductionmentioning

confidence: 99%

“…Statistical methods are routinely used to investigate possible compound mechanisms by examining statistical dependence between proxy variables of different flood types regionally or globally, such as rainfall and storm surge (Lai et al., 2021; Sanuy et al., 2021; Zellou & Rahali, 2019; Zheng et al., 2014), river flow and storm surge (Couasnon et al., 2020; Nasr et al., 2021b), and river flow and sea level (Ghanbari et al., 2021; Piecuch et al., 2018; Ward et al., 2018). Numerical models are widely applied to simulate tide, storm surge, river flow, and their nonlinear interactions on coastal inundation dynamics locally, for example, in Mississippi Delta (Bunya et al., 2010), Ganges‐Brahmaputra‐Meghna Delta (Ikeuchi et al., 2017), Lee River Delta (Olbert et al., 2017), Shoalhaven Delta (Kumbier et al., 2018), Pearl River Delta (PRD) (De Dominicis et al., 2020), Humber and Dyfi Delta (Harrison et al., 2021), Breede Delta (Kupfer et al., 2021), and Betanzos Delta (Bermúdez et al., 2021). To perform a robust and integrated assessment, intrinsic characteristics of statistical and numerical methods are suggested to be linked for representative compound flood hazard assessments (Moftakhari et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

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Quantitative Stress Test of Compound Coastal‐Fluvial Floods in China's Pearl River Delta

et al. 2022

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Floods in river deltas are driven by complex interactions between astronomical tides, sea levels, storm surges, wind waves, rainfall‐runoff, and river discharge. Given the anticipated increase in compound flood hazards in river deltas in a warming climate, climate‐informed regional to local extreme water levels (EWLs) is thus critical for decision‐makers to evaluate flood hazards and take adaptation measures. We develop a simple yet computationally efficient stress test framework, which combines historical and projected climatological information and a state‐of‐the‐art hydrodynamic model, to assess future compound coastal‐fluvial flood hazards in river deltas. Our framework is applied in the world's largest single urban area, China's Pearl River Delta (PRD), which is also characterized by densely crossed river network. We find that extreme sea level is the dominant driver causing the compound coastal‐fluvial flood in the PRD over the past 60 years. Meanwhile, there is large spatial heterogeneity of the individual and compound effects of the typhoon intensity, local sea‐level rise, and riverine inflow on coastal‐fluvial floods. In a plausible disruptive scenario (e.g., a 0.50 m sea‐level rise combined with a 9% increase in typhoon intensity in a 2°C warming), the EWL will increase by 0.76 m on average. An additional 1.54 and 0.56 m increase in EWL will occur in the river network and near the river mouth, respectively, if coastal floods coincide with the upstream mean annual flood. Findings from our modeling framework provide important insights to guide adaptation planning in river deltas to withstand future compound floods under climate change.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Quantitative Stress Test of Compound Coastal‐Fluvial Floods in China's Pearl River Delta

et al. 2022

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“…These extreme events may have a negative impact on biodiversity [6], crop yields [7], human health [2] and on various other socioeconomic factors [8]. Coastal areas typically have dense populations, concentrated urban construction and developed economies that are highly vulnerable to extreme floods [9,10]. Thus, it is imperative to explore the potential changes in future flow regimes by considering both climate change and human activities under global warming and socioeconomic development to formulate adaptation and mitigation strategies, especially for coastal basins [11].…”

Section: Introductionmentioning

confidence: 99%

Future Changes in High and Low Flows under the Impacts of Climate and Land Use Changes in the Jiulong River Basin of Southeast China

Yang

Zhao

et al. 2022

Atmosphere

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Climate change and human activities have profoundly affected the world with extreme precipitation, heat waves, water scarcity, frequent floods and intense droughts. It is acknowledged that climate change will persist and perhaps intensify in the future, and it is thus meaningful to explore the quantitative impacts of these changes on hydrological regimes. The Jiulong River basin serves as an important watershed on the southeast coast of China. However, future hydrological changes under the combined impacts of climate change and land use change have been barely investigated. In this study, the climate outputs from five general circulation models (GCMs) under the Coupled Model Intercomparison Project Phase 6 (CMIP6) were corrected and spatially downscaled by a statistical downscaling method combining quantile mapping and machine learning. The future high-resolution land use maps were projected by the CA–Markov model with land use changes from the Land-Use Harmonization 2 (LUH2) as constraints. The future dynamic vegetation process was projected by the Biome-GBC model, and then, the future hydrological process under four representative concentration pathways and shared socioeconomic pathways (RCP–SSP) combined scenarios was simulated by a distributed hydrological model. Based on the copula method, the flood frequency and corresponding return periods were derived. The results demonstrated that future precipitation and air temperature would continue to rise, and future land use changes would have different developing pathways determined by the designs in various SSP–RCPs. Under the combined impacts of climate and land use change, the total available water resources will increase due to increasing precipitation, and the high flow and low flow will both increase at three stations under the four SSP–RCPs. The annual 1-day maximum discharge is projected to increase by 67–133% in the last decade of the 21st century, and the annual 7-day minimum discharge is projected to increase by 19–39%. The flood frequency analysis showed that the Jiulong River basin would face more frequent floods in the future. By the end of the 21st century, the station-average frequency of a historical 100-year flood will increase by 122% under the most optimistic scenario (SSP126) and increase by 213% under the scenario of greatest regional rivalry (SSP370). We demonstrated that climate change would be the major cause for the increase in future high flows and that land use change would dominate future changes in low flows. Finally, we recommend integrated and sustainable water management systems to tackle future challenges in this coastal basin.

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“…To develop an accurate future flood risk assessment, it is necessary to assess all factors related to flood hazards in the context of climate change. The vulnerability of coastal river reaches is growing due to the increasing number of extreme hydrometeorological events caused by climate change [1][2][3][4][5]. Thus, the assessment of compound flooding with respect to climate change scenarios in coastal river reaches has become more relevant.…”

Section: Introductionmentioning

confidence: 99%

Sea Level Rise Impact on Compound Coastal River Flood Risk in Klaipėda City (Baltic Coast, Lithuania)

Čepienė

Dailidytė²,

Stonevičius

et al. 2022

Water

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Due to climate change, extreme floods are projected to increase in the 21st century in Europe. As a result, flood risk and flood-related losses might increase. It is therefore essential to simulate potential floods not only relying on historical but also future projecting data. Such simulations can provide necessary information for the development of flood protection measures and spatial planning. This paper analyzes the risk of compound flooding in the Danė River under different river discharge and Klaipėda Strait water level probabilities. Additionally, we examine how a water level rise of 1 m in the Klaipėda Strait could impact Danė River floods in Klaipėda city. Flood extent was estimated with the Hydrologic Engineering Center’s River Analysis System (HEC-RAS) and visualized with ArcGIS Pro. Research results show that a rise in the water level in the Klaipėda Strait has a greater impact on the central part of Klaipėda city, while that of the maximum discharge rates of the river affected the northern upstream part of the analyzed river section. A sea level rise of 1 m could lead to an increase in areas affected by Danė floods by up to three times. Floods can cause significant damage to the infrastructure of Klaipėda port city, urbanized territories in the city center, and residential areas in the northern part of the city. Our results confirm that, in the long run, sea level rise will significantly impact the urban areas of the Klaipėda city situated near the Baltic Sea coast.

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Assessing the Effects of Climate Change on Compound Flooding in Coastal River Areas

Cited by 42 publications

References 60 publications

Quantitative Stress Test of Compound Coastal‐Fluvial Floods in China's Pearl River Delta

Quantitative Stress Test of Compound Coastal‐Fluvial Floods in China's Pearl River Delta

Future Changes in High and Low Flows under the Impacts of Climate and Land Use Changes in the Jiulong River Basin of Southeast China

Sea Level Rise Impact on Compound Coastal River Flood Risk in Klaipėda City (Baltic Coast, Lithuania)

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