D. Eilander, A. Couasnon, F. Sperna Weiland, W. Ligtvoet, A. Bouwman, H. Winsemius, P. Ward
{"title":"利用全球适用框架模拟复合洪水风险和降低风险:莫桑比克索法拉省的试点项目","authors":"D. Eilander, A. Couasnon, F. Sperna Weiland, W. Ligtvoet, A. Bouwman, H. Winsemius, P. Ward","doi":"10.5194/nhess-23-2251-2023","DOIUrl":null,"url":null,"abstract":"Abstract. In low-lying coastal areas floods occur from\n(combinations of) fluvial, pluvial, and coastal drivers. If these flood\ndrivers are statistically dependent, their joint probability might be\nmisrepresented if dependence is not accounted for. However, few studies have examined flood risk and risk reduction measures while accounting for\nso-called compound flooding. We present a globally applicable framework for\ncompound flood risk assessments using combined hydrodynamic, impact, and\nstatistical modeling and apply it to a case study in the Sofala province of\nMozambique. The framework broadly consists of three steps. First, a large\nstochastic event set is derived from reanalysis data, taking into account\nco-occurrence of and dependence between all annual maximum flood drivers.\nThen, both flood hazard and impact are simulated for different combinations\nof drivers at non-flood and flood conditions. Finally, the impact of each\nstochastic event is interpolated from the simulated events to derive a\ncomplete flood risk profile. Our case study results show that from all\ndrivers, coastal flooding causes the largest risk in the region despite a\nmore widespread fluvial and pluvial flood hazard. Events with return periods longer than 25 years are more damaging when considering the observed\nstatistical dependence compared to independence, e.g., 12 % for the\n100-year return period. However, the total compound flood risk in terms of\nexpected annual damage is only 0.55 % larger. This is explained by the\nfact that for frequent events, which contribute most to the risk, limited\nphysical interaction between flood drivers is simulated. We also assess the\neffectiveness of three measures in terms of risk reduction. For our case,\nzoning based on the 2-year return period flood plain is as effective as\nlevees with a 10-year return period protection level, while dry proofing up\nto 1 m does not reach the same effectiveness. As the framework is based on\nglobal datasets and is largely automated, it can easily be repeated for\nother regions for first-order assessments of compound flood risk. While the\nquality of the assessment will depend on the accuracy of the global models\nand data, it can readily include higher-quality (local) datasets where\navailable to further improve the assessment.\n","PeriodicalId":18922,"journal":{"name":"Natural Hazards and Earth System Sciences","volume":" ","pages":""},"PeriodicalIF":4.2000,"publicationDate":"2023-06-21","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":"{\"title\":\"Modeling compound flood risk and risk reduction using a globally applicable framework: a pilot in the Sofala province of Mozambique\",\"authors\":\"D. Eilander, A. Couasnon, F. Sperna Weiland, W. Ligtvoet, A. Bouwman, H. Winsemius, P. Ward\",\"doi\":\"10.5194/nhess-23-2251-2023\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"Abstract. In low-lying coastal areas floods occur from\\n(combinations of) fluvial, pluvial, and coastal drivers. If these flood\\ndrivers are statistically dependent, their joint probability might be\\nmisrepresented if dependence is not accounted for. However, few studies have examined flood risk and risk reduction measures while accounting for\\nso-called compound flooding. We present a globally applicable framework for\\ncompound flood risk assessments using combined hydrodynamic, impact, and\\nstatistical modeling and apply it to a case study in the Sofala province of\\nMozambique. The framework broadly consists of three steps. First, a large\\nstochastic event set is derived from reanalysis data, taking into account\\nco-occurrence of and dependence between all annual maximum flood drivers.\\nThen, both flood hazard and impact are simulated for different combinations\\nof drivers at non-flood and flood conditions. Finally, the impact of each\\nstochastic event is interpolated from the simulated events to derive a\\ncomplete flood risk profile. Our case study results show that from all\\ndrivers, coastal flooding causes the largest risk in the region despite a\\nmore widespread fluvial and pluvial flood hazard. Events with return periods longer than 25 years are more damaging when considering the observed\\nstatistical dependence compared to independence, e.g., 12 % for the\\n100-year return period. However, the total compound flood risk in terms of\\nexpected annual damage is only 0.55 % larger. This is explained by the\\nfact that for frequent events, which contribute most to the risk, limited\\nphysical interaction between flood drivers is simulated. We also assess the\\neffectiveness of three measures in terms of risk reduction. For our case,\\nzoning based on the 2-year return period flood plain is as effective as\\nlevees with a 10-year return period protection level, while dry proofing up\\nto 1 m does not reach the same effectiveness. 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Modeling compound flood risk and risk reduction using a globally applicable framework: a pilot in the Sofala province of Mozambique
Abstract. In low-lying coastal areas floods occur from
(combinations of) fluvial, pluvial, and coastal drivers. If these flood
drivers are statistically dependent, their joint probability might be
misrepresented if dependence is not accounted for. However, few studies have examined flood risk and risk reduction measures while accounting for
so-called compound flooding. We present a globally applicable framework for
compound flood risk assessments using combined hydrodynamic, impact, and
statistical modeling and apply it to a case study in the Sofala province of
Mozambique. The framework broadly consists of three steps. First, a large
stochastic event set is derived from reanalysis data, taking into account
co-occurrence of and dependence between all annual maximum flood drivers.
Then, both flood hazard and impact are simulated for different combinations
of drivers at non-flood and flood conditions. Finally, the impact of each
stochastic event is interpolated from the simulated events to derive a
complete flood risk profile. Our case study results show that from all
drivers, coastal flooding causes the largest risk in the region despite a
more widespread fluvial and pluvial flood hazard. Events with return periods longer than 25 years are more damaging when considering the observed
statistical dependence compared to independence, e.g., 12 % for the
100-year return period. However, the total compound flood risk in terms of
expected annual damage is only 0.55 % larger. This is explained by the
fact that for frequent events, which contribute most to the risk, limited
physical interaction between flood drivers is simulated. We also assess the
effectiveness of three measures in terms of risk reduction. For our case,
zoning based on the 2-year return period flood plain is as effective as
levees with a 10-year return period protection level, while dry proofing up
to 1 m does not reach the same effectiveness. As the framework is based on
global datasets and is largely automated, it can easily be repeated for
other regions for first-order assessments of compound flood risk. While the
quality of the assessment will depend on the accuracy of the global models
and data, it can readily include higher-quality (local) datasets where
available to further improve the assessment.
期刊介绍:
Natural Hazards and Earth System Sciences (NHESS) is an interdisciplinary and international journal dedicated to the public discussion and open-access publication of high-quality studies and original research on natural hazards and their consequences. Embracing a holistic Earth system science approach, NHESS serves a wide and diverse community of research scientists, practitioners, and decision makers concerned with detection of natural hazards, monitoring and modelling, vulnerability and risk assessment, and the design and implementation of mitigation and adaptation strategies, including economical, societal, and educational aspects.
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