Urban water systems are facing various challenges against climate change,impacting cities’security and their sustainable development.Specifically,there are three major challenges:submersion risk of coastal cities as ...Urban water systems are facing various challenges against climate change,impacting cities’security and their sustainable development.Specifically,there are three major challenges:submersion risk of coastal cities as glaciers melt and sea level rises,more and severe urban flooding caused by extreme weather like intensified storm surge and heavy precipitation,and regional water resource patterns challenged by alteration of spatial distribution of precipitation.Regarding this,two strategies including proactive adaptation and positive mitigation were proposed in this article to realize the reconstruction and optimization of urban water systems,to enhance their resilience,and eventually increase their adaptability and coping ability to climate change.The proactive adaptation strategy consists of 1)construction of sponge cities to accommodate the increased regular rainfall and to balance the alterations of spatial redistribution of precipitation;2)reconstruction of excess stormwater discharge and detention system to increase capability for extreme precipitation events based on flood risk assessment under future climate change;3)deployment of forward-looking,ecological,and integrated measures to improve coastal protection capability against inundation risks caused by climate change and sea level rise.The positive mitigation strategy is to employ the systematic concept in planning and design and to adopt advanced applicable energy-saving technologies,processes,and management practices,aiming at reduction in flux of urban water systems,reinforcement in energy conservation and carbon reduction in both water supply systems and wastewater treatment systems,and thus a reduction of greenhouse gas emission from urban water systems.展开更多
基金supported by the National Key R&D Program of China(No.2022YFC3800102)the Scientific Innovation Fund of China Academy of Urban Planning&Design(No.C-201731)+2 种基金the Key Consulting Project of Chinese Academy of Engineering(No.2015-ZX-29-03)the Fundamental Research Funds for China Academy of Urban Planning&Design(No.CZ-2020009)the Major Science and Technology Program for Water Pollution Control and Treatment(No.2018ZX07110-008).
文摘Urban water systems are facing various challenges against climate change,impacting cities’security and their sustainable development.Specifically,there are three major challenges:submersion risk of coastal cities as glaciers melt and sea level rises,more and severe urban flooding caused by extreme weather like intensified storm surge and heavy precipitation,and regional water resource patterns challenged by alteration of spatial distribution of precipitation.Regarding this,two strategies including proactive adaptation and positive mitigation were proposed in this article to realize the reconstruction and optimization of urban water systems,to enhance their resilience,and eventually increase their adaptability and coping ability to climate change.The proactive adaptation strategy consists of 1)construction of sponge cities to accommodate the increased regular rainfall and to balance the alterations of spatial redistribution of precipitation;2)reconstruction of excess stormwater discharge and detention system to increase capability for extreme precipitation events based on flood risk assessment under future climate change;3)deployment of forward-looking,ecological,and integrated measures to improve coastal protection capability against inundation risks caused by climate change and sea level rise.The positive mitigation strategy is to employ the systematic concept in planning and design and to adopt advanced applicable energy-saving technologies,processes,and management practices,aiming at reduction in flux of urban water systems,reinforcement in energy conservation and carbon reduction in both water supply systems and wastewater treatment systems,and thus a reduction of greenhouse gas emission from urban water systems.
