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The rapid urbanization, sometimes lacking adequate planning and design, has led to worsening city syndrome situations, such as urban flooding, water pollution, heat island effects, and ecologic deterioration. Sponge city construction have become the new paradigm for a sustainable urban stormwater management strategy. Deviating from the traditional rapid draining approach, the new paradigm calls for the use of natural systems, such as soil and vegetation, as part of the urban runoff control strategy. It has become a widespread focus in urban water management research and practices globally. In this Special Issue reprint, there are 13 original scientific articles that address the different related urban runoff control issues. We are happy to see that all papers presented findings characterized as innovative and methodologically new. We hope that the readers can enjoy and learn deeply about urban runoff control and sponge city construction using the published material, and we hope that sharing of the researches results with the scientific community, policymakers and stakeholders can prompt the urban runoff control and sponge city construction globally.

Technology: general issues --- History of engineering & technology --- urban runoff remediation --- Talipariti tiliaceum --- modular bioretention tree --- field study --- tree-pit --- Green-Ampt method --- infiltration --- overland flow --- urban flood modelling --- 1D/2D coupled modelling --- dual drainage modelling --- extreme rainfall --- flooding --- safety criteria --- urban drainage --- uncertainty --- combined sewer overflows --- optimization --- SWMM --- NSGA-III --- sponge city --- bioretention facility --- rain infiltration --- slope stability --- urban water management --- drainage function --- permeable pavement --- biological retention --- control-oriented model --- urban drainage system --- real-time optimization --- Simuwater --- Sponge City --- aquifer recharge --- urban stormwater --- green infrastructure --- low impact development --- Sustainable Development Goals --- non-point source pollution --- enhanced dephosphorization bioretention --- modified bioretention facility --- road stormwater runoff --- combined soil filter media --- soil moisture conservation rope --- microbial diversity --- urban stormwater runoff management --- field monitoring --- ABC Waters design features --- water quality --- bioretention --- swales --- low-impact development --- pilot exploration --- systematic demonstration --- construction scale --- stakeholders --- multifunctional decision-making framework --- cost-effectiveness --- site suitability --- stakeholders’ preference --- n/a --- stakeholders' preference

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The rapid urbanization, sometimes lacking adequate planning and design, has led to worsening city syndrome situations, such as urban flooding, water pollution, heat island effects, and ecologic deterioration. Sponge city construction have become the new paradigm for a sustainable urban stormwater management strategy. Deviating from the traditional rapid draining approach, the new paradigm calls for the use of natural systems, such as soil and vegetation, as part of the urban runoff control strategy. It has become a widespread focus in urban water management research and practices globally. In this Special Issue reprint, there are 13 original scientific articles that address the different related urban runoff control issues. We are happy to see that all papers presented findings characterized as innovative and methodologically new. We hope that the readers can enjoy and learn deeply about urban runoff control and sponge city construction using the published material, and we hope that sharing of the researches results with the scientific community, policymakers and stakeholders can prompt the urban runoff control and sponge city construction globally.

Technology: general issues --- History of engineering & technology --- urban runoff remediation --- Talipariti tiliaceum --- modular bioretention tree --- field study --- tree-pit --- Green-Ampt method --- infiltration --- overland flow --- urban flood modelling --- 1D/2D coupled modelling --- dual drainage modelling --- extreme rainfall --- flooding --- safety criteria --- urban drainage --- uncertainty --- combined sewer overflows --- optimization --- SWMM --- NSGA-III --- sponge city --- bioretention facility --- rain infiltration --- slope stability --- urban water management --- drainage function --- permeable pavement --- biological retention --- control-oriented model --- urban drainage system --- real-time optimization --- Simuwater --- Sponge City --- aquifer recharge --- urban stormwater --- green infrastructure --- low impact development --- Sustainable Development Goals --- non-point source pollution --- enhanced dephosphorization bioretention --- modified bioretention facility --- road stormwater runoff --- combined soil filter media --- soil moisture conservation rope --- microbial diversity --- urban stormwater runoff management --- field monitoring --- ABC Waters design features --- water quality --- bioretention --- swales --- low-impact development --- pilot exploration --- systematic demonstration --- construction scale --- stakeholders --- multifunctional decision-making framework --- cost-effectiveness --- site suitability --- stakeholders' preference

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Remotely sensed geophysical datasets are being produced at increasingly fast rates to monitor various aspects of the Earth system in a rapidly changing world. The efficient and innovative use of these datasets to understand hydrological processes in various climatic and vegetation regimes under anthropogenic impacts has become an important challenge, but with a wide range of research opportunities. The ten contributions in this Special Issue have addressed the following four research topics: (1) Evapotranspiration estimation; (2) rainfall monitoring and prediction; (3) flood simulations and predictions; and (4) monitoring of ecohydrological processes using remote sensing techniques. Moreover, the authors have provided broader discussions on how to capitalize on state-of-the-art remote sensing techniques to improve hydrological model simulations and predictions, to enhance their skills in reproducing processes for the fast-changing world.

rainfall monitoring --- remote sensing --- rain rate estimation --- 5G --- millimeter-wave --- E-band --- LOS-MIMO --- UAV remote sensing --- Ephemeral rivers --- flood peak discharge --- incipient motion --- arid ungauged regions --- flash flood --- Integrated Multi-Satellite Retrievals for Global Precipitation Measurement --- Rainfall Triggering Index --- Yunnan --- ecological water transfer --- wetland vegetation ecosystem --- surface and groundwater interaction --- northwestern China --- WRF-3DVar data assimilation --- coupled atmospheric-hydrologic system --- rainfall-runoff prediction --- lumped Hebei model --- grid-based Hebei model --- WRF-Hydro modeling system --- evapotranspiration --- model --- SWAT --- calibration --- regression --- Sierra Nevada --- flux tower --- water limitation --- vapor pressure deficit --- double-mass analysis --- coefficient of variability --- seasonal ARIMA --- MK-S trend analysis --- evaporation --- LAI --- NDVI --- urban ecosystem --- sponge city --- PML-V2 --- Penman–Monteith equation --- Sentinel-2 --- assimilation frequency --- data assimilation --- WRF-3DAVR --- radar reflectivity --- rainfall forecast --- urban flood --- design rainfall --- ungauged drainage basin --- RainyDay --- IDF formula --- hydrological prediction --- climate change --- land use change

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Global population growth is urban growth and, therefore, most of the water-related challenges and solutions reside in cities. Unless water management and water governance processes are significantly improved within the next decade or so, cities are likely to face serious and prolonged water insecurity, urban floods, and/or heat stress, which may result in social instability and, ultimately, massive migration. Aging water infrastructure, one of the most expensive infrastructures in cities, is a relevant challenge in order to address Sustainable Development Goal (SDG) 6: clean water and sanitation, SDG 11: sustainable cities and communities, and SDG 13: climate action. The choice of good governance arrangements has important consequences for economic performance, for the well-being of citizens, and for the quality of life in urban areas. The better governance arrangements work in coordinating policies across jurisdictions and policy fields, the better the outcomes. Rapidly-changing global conditions will make future water governance more complex than ever before in human history, and expectations are that water governance and water management will change more during the next 20 years compared to the past 100 years. In this Special Issue of Water, the focus will be on practical concepts and tools for water management and water governance, with a focus on cities.

flood resilience --- flood risk --- Cape Town --- Sustainable Development Goals (SDGs) --- sustainable development goals --- urban planning --- coordination --- IHP --- storm water management --- stakeholder involvement --- flood risk management --- water management sustainability --- Generalized Likelihood Uncertainty Estimation (GLUE) --- climate change --- urban water cycle --- wastewater management --- water policy --- governance capacity --- greenhouse gas emissions --- intergovernmental --- Urban Water Management Programme --- indicators --- sustainability --- city networks --- water sensitive cities --- water scarcity --- ICLEI --- flood damage assessment --- stakeholder participation --- SuDS --- climate change mitigation --- social network analysis --- water ecology --- SDGs --- urban resilience --- design rainfall event --- cost of inaction --- rainwater harvesting --- co-design --- UNESCO --- rainfall-runoff --- storm water control measure --- decentralized water reclamation with resource recovery --- baseline assessment --- City Blueprint Approach --- urban water management --- urban landscape --- governance strategies --- science and technology --- drinking water --- Integrated Water Resources Management --- resilience --- Sponge City --- stormwater reservoir --- use-attainment --- sustainability assessment --- water security --- Water-Energy-Food Nexus --- water management --- water supply --- Storm Water Management Model (SWMM) --- urban drainage --- lifecycle analysis --- social infrastructure --- urban pluvial flooding --- assessment framework --- footprint --- climate change adaptation --- infrastructure --- total cost of ownership --- water governance --- flood control --- water-reuse --- governance

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This book is a compilation of original research articles that apply a variety of techniques to identify and evaluate water resource management policies. These papers cover a wide range of topics and methodologies applied across the world, from a local to a continental scope. They illustrate open challenges in water resource management, such as the quantitative assessment of policy impacts, trade-off analyses, understanding the water–energy–food–environment nexus, collaborative model development, stakeholder engagement, formalizing social interactions, or improving the theoretical understanding of complex adaptive systems. Therefore, this book is a representation of research areas that have emerged from the origins of water resource systems analysis, seeking to improve the way in which water policy is formulated and implemented.

Technology: general issues --- History of engineering & technology --- climate change --- water resources --- water availability --- uncertainty --- WAAPA model --- Western Europe --- water quality --- background pollutants --- export coefficient model --- chemical oxygen demand --- ammonia nitrogen --- water resource accessibility --- spatial pattern --- coupling coordination degree --- water resource management --- Southwest China --- pump efficiency --- water distribution systems --- water supply systems --- optimization --- design policies --- design --- BMPs --- Revised GWLF --- NSGAII --- hydrological dam safety --- initial reservoir level --- maximum conservation level --- water conservation volume --- flood control volume --- yield reliability --- regular operation --- stochastic methodology --- water management --- resources --- system dynamics --- drought management --- drought impacts --- urban public services --- inter-administrative cooperation --- border studies --- internal borders --- river municipalities --- freshwater health --- river chief system --- ecological integrity --- social services --- water governance --- national standard --- risk assessment --- water-saving --- set pair analysis --- China --- fluvial ecosystems --- hydropeaking --- InSTHAn tool --- short-term flow regimes --- subdaily flows --- sustainable river management --- droughts --- hydrological risk --- agri-food sector --- event study --- financial markets --- BOVESPA --- stormwater --- industrial facilities --- run off --- self-reported data --- multifunctional water source area --- ecotourism, people with different stakeholders --- balanced decision-making --- sponge city --- fuzzy comprehensive evaluation method --- water resource carrying capacity --- gray correlation analysis --- multiple linear regression models --- water environment capacity --- reservoir performance --- water resources systems --- participatory modeling --- river basin planning --- watershed management --- water scarcity --- water conflicts --- Robust Decision Support --- WEAP --- Integrated Water Resources Management --- Bolivia