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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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This open-access book addresses latest Sino-German results of the joint research efforts within Major Water Program of the Chinese Government supported by German research funding. The Major Water Program aims at the restoration of polluted water environments and sustainable management of water resources in China. The joint BMBF-CLIENT project SINOWATER deals with three most significant and strongest polluted Chinese waters, the river Liao and the Dian-lake as well as Tai-lake in the area of the metropolises Shenyang, Kunming and Suzhou, respectively. The project was conducted by the Research Institute for Water and Waste Management at RWTH Aachen (FiW) e.V., Bavarian State Ministry of the Environment and Consumer Protection, Technical University of Munich, RWTH Aachen University, German and Chinese companies (Martin Membrane Systems AG, Steinhardt GmbH Wassertechnik, GuHong, JT-elektronik, bluemetric, Huawang Water, EVU Group, Atemis GmbH, i+f process GmbH) in close cooperation with Chinese Academy of Environmental Sciences, Tongji University, and the Dianchi Lake Management Authorities. Overall, the joint Sino-German research project SINOWATER provided solutions for the improvement of the water quality in the mentioned water bodies as well as development and optimization of Good Water Governance. These objectives could be achieved through the implementation of innovative German water technologies and the optimization of water management elements in the fields of industrial and municipal wastewater treatment as well as river and shallow lake management.

Water quality management --- Water --- Water reuse --- Pollution --- Factory and trade waste --- Recycling (Waste, etc.) --- Salvage (Waste, etc.) --- Sewage --- Water conservation --- Water-supply --- Water use --- Reclamation of water --- Reuse of water --- Waste water reclamation --- Wastewater reclamation --- Water reclamation --- Water renovation --- Water salvage --- Hydrology --- Management --- Sewage disposal --- Water quality --- Water quality control --- Purification --- Reuse --- Integrated Water Resources Management --- Water Governance --- Urban Drainage --- Waste Water Treatment --- Sinowater --- Open Access

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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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This Special Issue publishes the latest advances and developments concerning the modelling of flooding in urban areas and contributes to our scientific understanding of the flooding processes and the appropriate evaluation of flood impacts. This issue contains contributions of novel methodologies including flood forecasting methods, data acquisition techniques, experimental research in urban drainage systems and/or sustainable drainage systems, and new numerical and simulation approaches in nine papers with contributions from over forty authors.

machine learning --- flash flood --- GIS --- Iran --- decision trees --- ensemble techniques --- manhole flooding --- urban flooding --- grid-based modeling --- SWWM --- FIRM --- pollutant transport --- hydraulic structures --- urban drainage --- CFD --- dual drainage --- Iber --- SWMM --- hazard --- artificial neural network --- resilient backpropagation --- multistep urban flood forecast --- demographic change --- urbanization --- flooding --- drainage system --- vulnerability --- Sub-Saharan Africa --- Antananarivo --- parameterised power-linear model --- hyper concentration --- dilute concentration --- suspended sediment transport --- flood --- sediment size parameter --- rouse number --- mean concentration --- flow depth --- urban flood modeling --- porosity --- shallow-water model --- urban flood management --- flood forecasting --- weather radar --- integrated hydraulic modeling --- and evacuation lead time --- n/a