Carbon mitigation technologies lead to air quality improvement and health co-benefits,while the practical effects of the technologies are dependent on the energy composition,technological advancements,and economic dev...Carbon mitigation technologies lead to air quality improvement and health co-benefits,while the practical effects of the technologies are dependent on the energy composition,technological advancements,and economic development.In China,mitigation technologies such as end-of-pipe treatment,renewable energy adoption,carbon capture and storage(CCS),and sector electrification demonstrate significant promise in meeting carbon reduction targets.However,the optimization of these technologies for maximum co-benefits remains unclear.Here,we employ an integrated assessment model(AIM/enduse,CAM-chem,IMED|HEL)to analyze air quality shifts and their corresponding health and economic impacts at the provincial level in China within the two-degree target.Our findings reveal that a combination of end-of-pipe technology,renewable energy utilization,and electrification yields the most promising results in air quality improvement,with a reduction of fine particulate matter(PM2.5)by−34.6μg m^(−3) and ozone by−18.3 ppb in 2050 compared to the reference scenario.In contrast,CCS technology demonstrates comparatively modest improvements in air quality(−9.4μg m^(−3) for PM_(2.5) and−2.4 ppb for ozone)and cumulative premature deaths reduction(−3.4 million from 2010 to 2050)compared to the end-of-pipe scenario.Notably,densely populated regions such as Henan,Hebei,Shandong,and Sichuan experience the most health and economic benefits.This study aims to project effective future mitigation technologies and climate policies on air quality improvement and carbon mitigation.Furthermore,it seeks to delineate detailed provincial-level air pollution control strategies,offering valuable guidance for policymakers and stakeholders in pursuing sustainable and health-conscious environmental management.展开更多
The presentation will give an overview over different classes of signal impairments in ultra-long-haul and high-speed optical WDM transmission systems and adequate approaches for suppression, mitigation or compensatio...The presentation will give an overview over different classes of signal impairments in ultra-long-haul and high-speed optical WDM transmission systems and adequate approaches for suppression, mitigation or compensation are discussed.展开更多
Power systems are critical to modern society,providing the backbone for all economic,industrial,and residential activities.However,these systems face significant threats from both natural and man-made disasters,such a...Power systems are critical to modern society,providing the backbone for all economic,industrial,and residential activities.However,these systems face significant threats from both natural and man-made disasters,such as earthquakes,floods,hurricanes,cyber-attacks,and equipment failures.The vulnerability of power systems to these disasters can result in prolonged outages,economic losses,safety risks,and social consequences.This paper explores various disaster prevention and mitigation technologies employed in power systems to enhance resilience and ensure reliable electricity supply during and after disasters.It discusses early warning systems for natural hazards,resilient infrastructure designs,and cybersecurity measures to defend against man-made threats.Additionally,it examines fault detection,power system restoration,and disaster-resilient control strategies that aid in quick recovery from disruptions.The integration of smart grids,renewable energy sources,and advanced control technologies is emphasized as crucial for improving disaster preparedness and minimizing recovery time.Through the application of these technologies,power systems can better withstand and recover from the growing risks posed by both natural and human-induced disasters.展开更多
基金National Key R&D Program of China(2020YFA0607804)National Natural Science Foundation of China(42375172 and 71903010)。
文摘Carbon mitigation technologies lead to air quality improvement and health co-benefits,while the practical effects of the technologies are dependent on the energy composition,technological advancements,and economic development.In China,mitigation technologies such as end-of-pipe treatment,renewable energy adoption,carbon capture and storage(CCS),and sector electrification demonstrate significant promise in meeting carbon reduction targets.However,the optimization of these technologies for maximum co-benefits remains unclear.Here,we employ an integrated assessment model(AIM/enduse,CAM-chem,IMED|HEL)to analyze air quality shifts and their corresponding health and economic impacts at the provincial level in China within the two-degree target.Our findings reveal that a combination of end-of-pipe technology,renewable energy utilization,and electrification yields the most promising results in air quality improvement,with a reduction of fine particulate matter(PM2.5)by−34.6μg m^(−3) and ozone by−18.3 ppb in 2050 compared to the reference scenario.In contrast,CCS technology demonstrates comparatively modest improvements in air quality(−9.4μg m^(−3) for PM_(2.5) and−2.4 ppb for ozone)and cumulative premature deaths reduction(−3.4 million from 2010 to 2050)compared to the end-of-pipe scenario.Notably,densely populated regions such as Henan,Hebei,Shandong,and Sichuan experience the most health and economic benefits.This study aims to project effective future mitigation technologies and climate policies on air quality improvement and carbon mitigation.Furthermore,it seeks to delineate detailed provincial-level air pollution control strategies,offering valuable guidance for policymakers and stakeholders in pursuing sustainable and health-conscious environmental management.
文摘The presentation will give an overview over different classes of signal impairments in ultra-long-haul and high-speed optical WDM transmission systems and adequate approaches for suppression, mitigation or compensation are discussed.
文摘Power systems are critical to modern society,providing the backbone for all economic,industrial,and residential activities.However,these systems face significant threats from both natural and man-made disasters,such as earthquakes,floods,hurricanes,cyber-attacks,and equipment failures.The vulnerability of power systems to these disasters can result in prolonged outages,economic losses,safety risks,and social consequences.This paper explores various disaster prevention and mitigation technologies employed in power systems to enhance resilience and ensure reliable electricity supply during and after disasters.It discusses early warning systems for natural hazards,resilient infrastructure designs,and cybersecurity measures to defend against man-made threats.Additionally,it examines fault detection,power system restoration,and disaster-resilient control strategies that aid in quick recovery from disruptions.The integration of smart grids,renewable energy sources,and advanced control technologies is emphasized as crucial for improving disaster preparedness and minimizing recovery time.Through the application of these technologies,power systems can better withstand and recover from the growing risks posed by both natural and human-induced disasters.
