The interest in curtailing environmental pollution issues through physical separation processes has inspired an extensive search for novel nanoporous materials with exceptional adsorption capabilities.Covalent triazin...The interest in curtailing environmental pollution issues through physical separation processes has inspired an extensive search for novel nanoporous materials with exceptional adsorption capabilities.Covalent triazine frameworks(CTFs),emerged as a class of crystalline covalent organic frameworks(COFs),have been widely examined for various separation applications,owing to their large porosity,high stability,and rich nitrogen(N)doping.The development of CTFs for efficient adsorption of mercury(Ⅱ)(Hg^(2+))is of great importance for the field,whereas it is rarely attempted,on account of limited synthetic strategies and unknown structural-property relations of conventional CTFs derived from ionothermal approaches.Herein,we report rational synthesis of a crystalline CTF with methylthio pendant arms for efficient removal of Hg^(2+)with an exceptional capacity of 751 mg·g^(-1),ranking at the top among previously-reported adsorbents.This work may open up new possibility in the synthesis of COFs for various separations.展开更多
The adsorption isotherms of the polysulfone hollow fiber chelating membrane modified with thionrea as chelating groups for Hg^2+ were determined. The effects of mobile phase conditions and the operating parameters on...The adsorption isotherms of the polysulfone hollow fiber chelating membrane modified with thionrea as chelating groups for Hg^2+ were determined. The effects of mobile phase conditions and the operating parameters on removal performance of the chelating membrane for Hg^2+ were also investigated. The recovery of Hg^2+ decreased at low pH and the optimum range of pH was from 6 to 7. The feed concentration effected on recovery of Hg^2+ at the specified loading amount of Hg^2+. The Hg^2+ could be removed from different concentration feed solution by chelating membrane. The increase of feed flow rate led to slight decrease of recovery of Hg^2+ at the specified loading amount of Hg^2+. The chelating membrane could be operated at height feed flow rate and a large-scale removal of H^2+ could be realized. With the increase of load amount, Hg^2+ recovery decreased, but the saturation degree of chelating membrane increased. According to required recovery of H^2+ and the saturation degree of chelating membrane, the optimum loading amount of Hg^2+ should be selected in the actual removal of H^2+.展开更多
基金The National Natural Science Foundation of China(22078349,22005319,52170109)Self-deployment Program from Lanzhou Institute of Chemical Physics(E30159SQ).
文摘The interest in curtailing environmental pollution issues through physical separation processes has inspired an extensive search for novel nanoporous materials with exceptional adsorption capabilities.Covalent triazine frameworks(CTFs),emerged as a class of crystalline covalent organic frameworks(COFs),have been widely examined for various separation applications,owing to their large porosity,high stability,and rich nitrogen(N)doping.The development of CTFs for efficient adsorption of mercury(Ⅱ)(Hg^(2+))is of great importance for the field,whereas it is rarely attempted,on account of limited synthetic strategies and unknown structural-property relations of conventional CTFs derived from ionothermal approaches.Herein,we report rational synthesis of a crystalline CTF with methylthio pendant arms for efficient removal of Hg^(2+)with an exceptional capacity of 751 mg·g^(-1),ranking at the top among previously-reported adsorbents.This work may open up new possibility in the synthesis of COFs for various separations.
基金the Natural Science Foundation of Tianjin (No05YFJ MJC04200)
文摘The adsorption isotherms of the polysulfone hollow fiber chelating membrane modified with thionrea as chelating groups for Hg^2+ were determined. The effects of mobile phase conditions and the operating parameters on removal performance of the chelating membrane for Hg^2+ were also investigated. The recovery of Hg^2+ decreased at low pH and the optimum range of pH was from 6 to 7. The feed concentration effected on recovery of Hg^2+ at the specified loading amount of Hg^2+. The Hg^2+ could be removed from different concentration feed solution by chelating membrane. The increase of feed flow rate led to slight decrease of recovery of Hg^2+ at the specified loading amount of Hg^2+. The chelating membrane could be operated at height feed flow rate and a large-scale removal of H^2+ could be realized. With the increase of load amount, Hg^2+ recovery decreased, but the saturation degree of chelating membrane increased. According to required recovery of H^2+ and the saturation degree of chelating membrane, the optimum loading amount of Hg^2+ should be selected in the actual removal of H^2+.
