Measuring compound flood potential from river discharge and storm surge extremes at the global scale

The interaction between physical drivers from oceanographic, hydrological, and meteorological processes in coastal areas can result in compound flooding. Compound flood events, like Cyclone Idai and Hurricane Harvey, have revealed the devastating consequences of the co-occurrence of coastal and rive...

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Published in	Natural hazards and earth system sciences Vol. 20; no. 2; pp. 489 - 504
Main Authors	Couasnon, Anaïs, Eilander, Dirk, Muis, Sanne, Veldkamp, Ted I. E., Haigh, Ivan D., Wahl, Thomas, Winsemius, Hessel C., Ward, Philip J.
Format	Journal Article
Language	English
Published	Katlenburg-Lindau Copernicus GmbH 21.02.2020 Copernicus Publications
Subjects	Analysis Atmospheric forcing Atmospheric models Bivariate analysis Case studies Coastal flooding Coastal meteorology Coastal processes Coastal zone Computer simulation Cyclones Dependence Emergency preparedness Environmental risk Extreme weather Flood hazards Flood risk Flooding Floods Hurricanes Hydrologic processes Hydrology Measurement Motor vehicle drivers Natural disaster damage open climate campaign Physical oceanography Precipitation (Meteorology) Probability theory Regions Risk assessment River discharge River flow River mouth Rivers Statistical analysis Statistics Storm surges Storms Tidal waves Time Water discharge Weather Madagascar
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Abstract	The interaction between physical drivers from oceanographic, hydrological, and meteorological processes in coastal areas can result in compound flooding. Compound flood events, like Cyclone Idai and Hurricane Harvey, have revealed the devastating consequences of the co-occurrence of coastal and river floods. A number of studies have recently investigated the likelihood of compound flooding at the continental scale based on simulated variables of flood drivers, such as storm surge, precipitation, and river discharges. At the global scale, this has only been performed based on observations, thereby excluding a large extent of the global coastline. The purpose of this study is to fill this gap and identify regions with a high compound flooding potential from river discharge and storm surge extremes in river mouths globally. To do so, we use daily time series of river discharge and storm surge from state-of-the-art global models driven with consistent meteorological forcing from reanalysis datasets. We measure the compound flood potential by analysing both variables with respect to their timing, joint statistical dependence, and joint return period. Our analysis indicates many regions that deviate from statistical independence and could not be identified in previous global studies based on observations alone, such as Madagascar, northern Morocco, Vietnam, and Taiwan. We report possible causal mechanisms for the observed spatial patterns based on existing literature. Finally, we provide preliminary insights on the implications of the bivariate dependence behaviour on the flood hazard characterisation using Madagascar as a case study. Our global and local analyses show that the dependence structure between flood drivers can be complex and can significantly impact the joint probability of discharge and storm surge extremes. These emphasise the need to refine global flood risk assessments and emergency planning to account for these potential interactions.
AbstractList	The interaction between physical drivers from oceanographic, hydrological, and meteorological processes in coastal areas can result in compound flooding. Compound flood events, like Cyclone Idai and Hurricane Harvey, have revealed the devastating consequences of the co-occurrence of coastal and river floods. A number of studies have recently investigated the likelihood of compound flooding at the continental scale based on simulated variables of flood drivers, such as storm surge, precipitation, and river discharges. At the global scale, this has only been performed based on observations, thereby excluding a large extent of the global coastline. The purpose of this study is to fill this gap and identify regions with a high compound flooding potential from river discharge and storm surge extremes in river mouths globally. To do so, we use daily time series of river discharge and storm surge from state-of-the-art global models driven with consistent meteorological forcing from reanalysis datasets. We measure the compound flood potential by analysing both variables with respect to their timing, joint statistical dependence, and joint return period. Our analysis indicates many regions that deviate from statistical independence and could not be identified in previous global studies based on observations alone, such as Madagascar, northern Morocco, Vietnam, and Taiwan. We report possible causal mechanisms for the observed spatial patterns based on existing literature. Finally, we provide preliminary insights on the implications of the bivariate dependence behaviour on the flood hazard characterisation using Madagascar as a case study. Our global and local analyses show that the dependence structure between flood drivers can be complex and can significantly impact the joint probability of discharge and storm surge extremes. These emphasise the need to refine global flood risk assessments and emergency planning to account for these potential interactions. The interaction between physical drivers from oceanographic, hydrological, and meteorological processes in coastal areas can result in compound flooding. Compound flood events, like Cyclone Idai and Hurricane Harvey, have revealed the devastating consequences of the co-occurrence of coastal and river floods. A number of studies have recently investigated the likelihood of compound flooding at the continental scale based on simulated variables of flood drivers, such as storm surge, precipitation, and river discharges. At the global scale, this has only been performed based on observations, thereby excluding a large extent of the global coastline. The purpose of this study is to fill this gap and identify regions with a high compound flooding potential from river discharge and storm surge extremes in river mouths globally. To do so, we use daily time series of river discharge and storm surge from state-of-the-art global models driven with consistent meteorological forcing from reanalysis datasets. We measure the compound flood potential by analysing both variables with respect to their timing, joint statistical dependence, and joint return period. Our analysis indicates many regions that deviate from statistical independence and could not be identified in previous global studies based on observations alone, such as Madagascar, northern Morocco, Vietnam, and Taiwan. We report possible causal mechanisms for the observed spatial patterns based on existing literature. Finally, we provide preliminary insights on the implications of the bivariate dependence behaviour on the flood hazard characterisation using Madagascar as a case study. Our global and local analyses show that the dependence structure between flood drivers can be complex and can significantly impact the joint probability of discharge and storm surge extremes. These emphasise the need to refine global flood risk assessments and emergency planning to account for these potential interactions.
Audience	Academic
Author	Eilander, Dirk Ward, Philip J. Winsemius, Hessel C. Couasnon, Anaïs Haigh, Ivan D. Wahl, Thomas Muis, Sanne Veldkamp, Ted I. E.
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SubjectTerms	Analysis Atmospheric forcing Atmospheric models Bivariate analysis Case studies Coastal flooding Coastal meteorology Coastal processes Coastal zone Computer simulation Cyclones Dependence Emergency preparedness Environmental risk Extreme weather Flood hazards Flood risk Flooding Floods Hurricanes Hydrologic processes Hydrology Measurement Motor vehicle drivers Natural disaster damage open climate campaign Physical oceanography Precipitation (Meteorology) Probability theory Regions Risk assessment River discharge River flow River mouth Rivers Statistical analysis Statistics Storm surges Storms Tidal waves Time Water discharge Weather
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Title	Measuring compound flood potential from river discharge and storm surge extremes at the global scale
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