Environmental pollution is one of the most severe problems facing today,including water pollution and the greenhouse effect.Therefore,developing materials with high-efficiency dyes adsorption and CO_(2)uptake is signi...Environmental pollution is one of the most severe problems facing today,including water pollution and the greenhouse effect.Therefore,developing materials with high-efficiency dyes adsorption and CO_(2)uptake is significant.Covalent organic frameworks(COFs),as a burgeoning class of crystalline porous polymers,present a promising application potential in areas related to pollution regulation due to their exciting surface properties.Herein,we report a 3D COF with a high specific surface area(BET about 2072 m^(2)/g)by utilizing tetrahedral and rectangle building blocks connected through[4+4]imine condensation reactions to synthesize.The obtained COF not only can separate dyes from water effectively but also shows a remarkable CO_(2)uptake capacity.This research thus provides a promising material to remove dyes and adsorb CO_(2)in environmental remediation.展开更多
Radioactive iodine is a notorious pollutant in gas radioactive nuclear waste due to its radiation hazard, volatility, chemical toxicity, and high mobility. Therefore, developing a material with high efficiency-specifi...Radioactive iodine is a notorious pollutant in gas radioactive nuclear waste due to its radiation hazard, volatility, chemical toxicity, and high mobility. Therefore, developing a material with high efficiency-specific iodine capture is significant. Covalent organic framework(COF) has attracted significant attention as a new crystalline porous organic material. Due to its large specific surface and high chemical stability, it is an excellent alternative to adsorbents. Herein, we report a chemically stable two-dimensional COF(termed JUC-609) with specific adsorption of iodine. Adsorption experiments show that JUC-609 has an excellent iodine adsorption capacity as high as 5.9 g/g under 353 K and normal pressure condition, and iodine adsorption after multiple cycles is still maintained. Our study thus promotes the potential application of COFs in the field of environment-related applications.展开更多
基金This work was supported by the National Natural Science Foundation of China(Nos.22025504,21621001,21390394)the“111”Project of China(Nos.BP0719036,B17020)+1 种基金the China Postdoctoral Science Foundation(Nos.2020TQ0118,2020M681034)the Program for JLU Science and Technology Innovative Research Team,China.
文摘Environmental pollution is one of the most severe problems facing today,including water pollution and the greenhouse effect.Therefore,developing materials with high-efficiency dyes adsorption and CO_(2)uptake is significant.Covalent organic frameworks(COFs),as a burgeoning class of crystalline porous polymers,present a promising application potential in areas related to pollution regulation due to their exciting surface properties.Herein,we report a 3D COF with a high specific surface area(BET about 2072 m^(2)/g)by utilizing tetrahedral and rectangle building blocks connected through[4+4]imine condensation reactions to synthesize.The obtained COF not only can separate dyes from water effectively but also shows a remarkable CO_(2)uptake capacity.This research thus provides a promising material to remove dyes and adsorb CO_(2)in environmental remediation.
基金supported by the National Natural Science Foundation of China(Nos.22025504,21621001,21390394)the″111″Project of China(Nos.BP0719036,B17020)+1 种基金the China Postdoctoral Science Foundation(Nos.2020TQ0118,2020M681034)the Program for JLU Science and Technology Innovative Research Team,China.
文摘Radioactive iodine is a notorious pollutant in gas radioactive nuclear waste due to its radiation hazard, volatility, chemical toxicity, and high mobility. Therefore, developing a material with high efficiency-specific iodine capture is significant. Covalent organic framework(COF) has attracted significant attention as a new crystalline porous organic material. Due to its large specific surface and high chemical stability, it is an excellent alternative to adsorbents. Herein, we report a chemically stable two-dimensional COF(termed JUC-609) with specific adsorption of iodine. Adsorption experiments show that JUC-609 has an excellent iodine adsorption capacity as high as 5.9 g/g under 353 K and normal pressure condition, and iodine adsorption after multiple cycles is still maintained. Our study thus promotes the potential application of COFs in the field of environment-related applications.
