Nature‐based solutions for urban pluvial flood risk management

Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in the context of a changing climate. To limit the evolving risks of urban pluvial flooding in a more environmentally friendly manner, the resea...

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Published inWiley interdisciplinary reviews. Water Vol. 7; no. 3; pp. e1421 - n/a
Main Authors Huang, Yijing, Tian, Zhan, Ke, Qian, Liu, Junguo, Irannezhad, Masoud, Fan, Dongli, Hou, Meifang, Sun, Laixiang
Format Journal Article
LanguageEnglish
Published Hoboken, USA John Wiley & Sons, Inc 01.05.2020
Wiley Subscription Services, Inc
Subjects
Adaptive management
Clean technology
Climate change
Ecological effects
Economics
Environmental engineering
Environmental risk
extreme precipitation
Extreme weather
Flood management
Flooding
Floods
Literature reviews
Mitigation
nature‐based solution
Precipitation
Risk management
Surveying
Urban areas
urban pluvial flood
Urbanization
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Abstract Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in the context of a changing climate. To limit the evolving risks of urban pluvial flooding in a more environmentally friendly manner, the research community has recently paid increasing attention to Nature‐Based Solutions (NBS), which are based on new green technologies. To meet the urgent demand for a comprehensive review of the most recent literature, this review conducts a systematic survey of the literature to characterize various NBS adopted in different regions of the world and to elaborate on the benefits and limitations of such NBS. The review highlights the role of NBS in urban flood risk management under ongoing climate change and rapid urbanization. It shows that NBS could effectively mitigate urban flooding caused by high‐frequency precipitation events, with additional economic, ecological, and social benefits. However, NBS are less effective at helping cope with pluvial flooding caused by extreme precipitation events over a short period of time, while gray infrastructures also have limitations as a mitigation measure against extreme pluvial flooding. We thus recommend identifying flood risk management strategies by evaluating the performance of alternative combinations of NBS with gray infrastructures in preventing pluvial flooding in the cities. Finally, recent advances made in the applications of NBS are presented with suggestions (e.g., long‐term monitoring) to improve urban flood adaptive management. This article is categorized under: Engineering Water > Planning Water Engineering Water > Sustainable Engineering of Water Science of Water > Water Extremes NBS infrastructures, as the components of the ecosystem, can influence the hydrological processes and benefit stormwater management through changing ecological elements after implementation.
AbstractList Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in the context of a changing climate. To limit the evolving risks of urban pluvial flooding in a more environmentally friendly manner, the research community has recently paid increasing attention to Nature‐Based Solutions (NBS), which are based on new green technologies. To meet the urgent demand for a comprehensive review of the most recent literature, this review conducts a systematic survey of the literature to characterize various NBS adopted in different regions of the world and to elaborate on the benefits and limitations of such NBS. The review highlights the role of NBS in urban flood risk management under ongoing climate change and rapid urbanization. It shows that NBS could effectively mitigate urban flooding caused by high‐frequency precipitation events, with additional economic, ecological, and social benefits. However, NBS are less effective at helping cope with pluvial flooding caused by extreme precipitation events over a short period of time, while gray infrastructures also have limitations as a mitigation measure against extreme pluvial flooding. We thus recommend identifying flood risk management strategies by evaluating the performance of alternative combinations of NBS with gray infrastructures in preventing pluvial flooding in the cities. Finally, recent advances made in the applications of NBS are presented with suggestions (e.g., long‐term monitoring) to improve urban flood adaptive management. This article is categorized under: Engineering Water > Planning Water Engineering Water > Sustainable Engineering of Water Science of Water > Water Extremes
Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in the context of a changing climate. To limit the evolving risks of urban pluvial flooding in a more environmentally friendly manner, the research community has recently paid increasing attention to Nature‐Based Solutions (NBS), which are based on new green technologies. To meet the urgent demand for a comprehensive review of the most recent literature, this review conducts a systematic survey of the literature to characterize various NBS adopted in different regions of the world and to elaborate on the benefits and limitations of such NBS. The review highlights the role of NBS in urban flood risk management under ongoing climate change and rapid urbanization. It shows that NBS could effectively mitigate urban flooding caused by high‐frequency precipitation events, with additional economic, ecological, and social benefits. However, NBS are less effective at helping cope with pluvial flooding caused by extreme precipitation events over a short period of time, while gray infrastructures also have limitations as a mitigation measure against extreme pluvial flooding. We thus recommend identifying flood risk management strategies by evaluating the performance of alternative combinations of NBS with gray infrastructures in preventing pluvial flooding in the cities. Finally, recent advances made in the applications of NBS are presented with suggestions (e.g., long‐term monitoring) to improve urban flood adaptive management. This article is categorized under: Engineering Water > Planning Water Engineering Water > Sustainable Engineering of Water Science of Water > Water Extremes NBS infrastructures, as the components of the ecosystem, can influence the hydrological processes and benefit stormwater management through changing ecological elements after implementation.
Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in the context of a changing climate. To limit the evolving risks of urban pluvial flooding in a more environmentally friendly manner, the research community has recently paid increasing attention to Nature‐Based Solutions (NBS), which are based on new green technologies. To meet the urgent demand for a comprehensive review of the most recent literature, this review conducts a systematic survey of the literature to characterize various NBS adopted in different regions of the world and to elaborate on the benefits and limitations of such NBS. The review highlights the role of NBS in urban flood risk management under ongoing climate change and rapid urbanization. It shows that NBS could effectively mitigate urban flooding caused by high‐frequency precipitation events, with additional economic, ecological, and social benefits. However, NBS are less effective at helping cope with pluvial flooding caused by extreme precipitation events over a short period of time, while gray infrastructures also have limitations as a mitigation measure against extreme pluvial flooding. We thus recommend identifying flood risk management strategies by evaluating the performance of alternative combinations of NBS with gray infrastructures in preventing pluvial flooding in the cities. Finally, recent advances made in the applications of NBS are presented with suggestions (e.g., long‐term monitoring) to improve urban flood adaptive management.This article is categorized under:Engineering Water > Planning WaterEngineering Water > Sustainable Engineering of WaterScience of Water > Water Extremes
Author Fan, Dongli
Huang, Yijing
Irannezhad, Masoud
Hou, Meifang
Sun, Laixiang
Liu, Junguo
Tian, Zhan
Ke, Qian
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  orcidid: 0000-0002-6863-3416
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  fullname: Tian, Zhan
  organization: Southern University of Science and Technology
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  surname: Ke
  fullname: Ke, Qian
  organization: Delft University of Technology
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  orcidid: 0000-0002-5745-6311
  surname: Liu
  fullname: Liu, Junguo
  email: liujg@sustech.edu.cn
  organization: Southern University of Science and Technology
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  fullname: Hou, Meifang
  organization: Shanghai Institute of Technology
– sequence: 8
  givenname: Laixiang
  surname: Sun
  fullname: Sun, Laixiang
  organization: University of Maryland
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Snippet Urban pluvial flooding now occurs more frequently than it has in past decades, mainly due to an increasing number of extreme precipitation events occurring in...
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SubjectTerms Adaptive management
Clean technology
Climate change
Ecological effects
Economics
Environmental engineering
Environmental risk
extreme precipitation
Extreme weather
Flood management
Flooding
Floods
Literature reviews
Mitigation
nature‐based solution
Precipitation
Risk management
Surveying
Urban areas
urban pluvial flood
Urbanization
Title Nature‐based solutions for urban pluvial flood risk management
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fwat2.1421
https://www.proquest.com/docview/2395148609
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