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In response to the increasing urbanization, advances in the science of urban hydrology have improved urban water system management, creating more livable cities in which public safety and health, as well as the environment, are protected. The ultimate goal of urban water management is to mimic the hydrological cycle prior to urbanization. On top of urbanization, climate change, which has been demonstrated to alter the hydrological cycle in all respects, has introduced additional challenges to managing urban water systems. To mitigate and adapt to urbanization under a changing climate, understanding key hydrologic components should expand to include complex issues brought forth by climate change. Thus, effective and efficient measures can be formulated. This Special Issue of Water presents a variety of research papers that span a range of spatial and temporal scales of relevance in different societies’ efforts in adapting to the eminent changes in climate and the continuous changes in the landscape. From mitigating water quality in permeable pavements and bioretention swales to understanding changes in groundwater recharge in large regions, this Special Issue examines the state-of-the-art in sustainable urban design for adaptation and resiliency.

Technology: general issues --- permeable asphalt --- heavy metal --- leaching behavior --- MSWI-BAA --- stormwater --- low impact development --- sustainable urban drainage systems --- stormwater modelling --- urban development --- GIS --- SAW --- decision-making --- strategic planning --- spatial analysis --- stormwater quality --- fecal coliforms --- Vancouver Island --- nearshore areas --- bacteria loading --- multinomial logistic regression --- periodicity analysis --- land use impacts --- climate impacts --- green roof --- energy performance --- heat island effect --- bio-retention --- green infrastructure --- runoff control performance --- storm inlet hydraulics --- flow distribution hydraulics --- climate change --- urbanization --- urban runoff --- Toronto --- Montreal --- Vancouver --- flooding --- geospatial modeling --- groundwater level --- trends --- non-stationarity --- climate variability --- land use/land cover change --- developing cities --- n/a

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In response to the increasing urbanization, advances in the science of urban hydrology have improved urban water system management, creating more livable cities in which public safety and health, as well as the environment, are protected. The ultimate goal of urban water management is to mimic the hydrological cycle prior to urbanization. On top of urbanization, climate change, which has been demonstrated to alter the hydrological cycle in all respects, has introduced additional challenges to managing urban water systems. To mitigate and adapt to urbanization under a changing climate, understanding key hydrologic components should expand to include complex issues brought forth by climate change. Thus, effective and efficient measures can be formulated. This Special Issue of Water presents a variety of research papers that span a range of spatial and temporal scales of relevance in different societies’ efforts in adapting to the eminent changes in climate and the continuous changes in the landscape. From mitigating water quality in permeable pavements and bioretention swales to understanding changes in groundwater recharge in large regions, this Special Issue examines the state-of-the-art in sustainable urban design for adaptation and resiliency.

permeable asphalt --- heavy metal --- leaching behavior --- MSWI-BAA --- stormwater --- low impact development --- sustainable urban drainage systems --- stormwater modelling --- urban development --- GIS --- SAW --- decision-making --- strategic planning --- spatial analysis --- stormwater quality --- fecal coliforms --- Vancouver Island --- nearshore areas --- bacteria loading --- multinomial logistic regression --- periodicity analysis --- land use impacts --- climate impacts --- green roof --- energy performance --- heat island effect --- bio-retention --- green infrastructure --- runoff control performance --- storm inlet hydraulics --- flow distribution hydraulics --- climate change --- urbanization --- urban runoff --- Toronto --- Montreal --- Vancouver --- flooding --- geospatial modeling --- groundwater level --- trends --- non-stationarity --- climate variability --- land use/land cover change --- developing cities --- n/a

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Flooding is widely recognized as a global threat, due to the extent and magnitude of damage it causes around the world each year. Reducing flood risk and improving flood resilience are two closely related aspects of flood management. This book presents the latest advances in flood risk and resilience management on the following themes: hazard and risk analysis, flood behaviour analysis, assessment frameworks and metrics and intervention strategies. It can help the reader to understand the current challenges in flood management and the development of sustainable flood management interventions to reduce the social, economic and environmental consequences from flooding.

History of engineering & technology --- nonstationarity --- univariate model --- GAMLSS --- bivariate model --- copulas --- floodway --- optimization --- particle swarm optimization --- HEC-RAS --- flood mitigation --- hydraulic modeling --- flood risk perception --- natural flood management --- disaster mitigation --- flood-prone city --- questionnaire survey --- flood hazard --- land use --- urban growth --- Villahermosa --- architecture modelling flood resilience --- resilience engineering --- system-of-systems water systems --- multi-risk matrix --- resilience --- flood risk --- multi-hazard --- risk reduction --- flood resilience index --- flood resilience analysis --- urban floods --- flood risk assessment --- flood inundation modelling --- Artificial Intelligence --- machine learning --- flood --- preparedness --- flood resilience --- blue-green infrastructure --- flood risk management --- sustainable --- drainage systems --- systems --- flood control materials --- intelligent warehousing --- location allocation --- multi-objective optimization --- drone applications --- deployment time --- monitoring --- flood modelling --- evacuation --- rescue --- management strategy --- metrics --- nonstationarity --- univariate model --- GAMLSS --- bivariate model --- copulas --- floodway --- optimization --- particle swarm optimization --- HEC-RAS --- flood mitigation --- hydraulic modeling --- flood risk perception --- natural flood management --- disaster mitigation --- flood-prone city --- questionnaire survey --- flood hazard --- land use --- urban growth --- Villahermosa --- architecture modelling flood resilience --- resilience engineering --- system-of-systems water systems --- multi-risk matrix --- resilience --- flood risk --- multi-hazard --- risk reduction --- flood resilience index --- flood resilience analysis --- urban floods --- flood risk assessment --- flood inundation modelling --- Artificial Intelligence --- machine learning --- flood --- preparedness --- flood resilience --- blue-green infrastructure --- flood risk management --- sustainable --- drainage systems --- systems --- flood control materials --- intelligent warehousing --- location allocation --- multi-objective optimization --- drone applications --- deployment time --- monitoring --- flood modelling --- evacuation --- rescue --- management strategy --- metrics

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It is well known that 55% of the world’s population currently lives in urban areas, and this figure is predicted to grow to 68% by 2050, adding more than 2.5 billion people to urban populations. It is also projected that there will be 43 megacities worldwide by 2030, with populations of more than 10 million inhabitants. The United Nations World Water Development Report, 2018, warned that by 2030, the global demand for fresh water is likely to exceed supply by 40%. Added to population growth, climate change has the potential to lead to changes in rainfall regimes, with the potential of increased flooding and drought. Currently, 1.2 billion people are at risk from flooding, but this is predicted to increase to about 1.6 billion, i.e., nearly 20% of the total world population, by 2050. In line with this, replacing deteriorating water management infrastructure that can no longer cope is economically unfeasible, impracticable from a construction point of view, and likely to fail in the long term. To address these issues, approaches are needed that are flexible and have multiple benefits. In its World Water Development Report, 2018, the UN promotes the use of nature-based solutions to some of these problems, with the focus of Sustainable Development Goal 6 (making sure that everyone has access to a safe and affordable supply of potable water and sanitation by 2030) requiring investment in suitable infrastructure across the world. This Special Issue covers the challenges faced in managing urban water in all its forms, from potable supplies to reuse and harvesting, as well as resilient and sustainable approaches developed to address flooding and drought.

Research & information: general --- SWAT --- urbanization --- nutrient loads --- constructed wetlands --- buffer zones --- river bank stabilization --- multi-source combined water supply --- optimal allocation of water resources --- incoming water uncertainty --- guaranteed rate of water use --- groundwater --- Heckman model --- self-supply --- water demand --- water economics --- industry --- climate change --- coastal protection --- coastal flooding --- sea defence --- experimental modelling --- sustainability --- detention basins --- green roofs --- MicroDrainage --- porous pavement --- runoff reduction --- swales --- biological evolution --- ecosystem services --- low impact development (LID) --- stormwater best management practices (BMP) --- stormwater control measures (SCMs) --- sustainable drainage systems (SuDS) --- water sensitive urban design (WSUD) --- potable supplies --- groundwater level changes --- infiltration --- recharge --- climate changes --- water efficiency --- SWAT --- urbanization --- nutrient loads --- constructed wetlands --- buffer zones --- river bank stabilization --- multi-source combined water supply --- optimal allocation of water resources --- incoming water uncertainty --- guaranteed rate of water use --- groundwater --- Heckman model --- self-supply --- water demand --- water economics --- industry --- climate change --- coastal protection --- coastal flooding --- sea defence --- experimental modelling --- sustainability --- detention basins --- green roofs --- MicroDrainage --- porous pavement --- runoff reduction --- swales --- biological evolution --- ecosystem services --- low impact development (LID) --- stormwater best management practices (BMP) --- stormwater control measures (SCMs) --- sustainable drainage systems (SuDS) --- water sensitive urban design (WSUD) --- potable supplies --- groundwater level changes --- infiltration --- recharge --- climate changes --- water efficiency