Designing highly porous materials is of great importance for liquid separation,water purification,and disinfection,such as spill oil cleaning and recycling,seawater desalting,and oil/water separation.However,a remaini...Designing highly porous materials is of great importance for liquid separation,water purification,and disinfection,such as spill oil cleaning and recycling,seawater desalting,and oil/water separation.However,a remaining challenge is to produce porous materials with the characteristics of fast absorption,continuous directional transport,and self-release of viscous liquid.Herein,a functional cellulosic composite is reported by the chemical treatment and functionalization of wood resulting in a smart wood that can thermally selfrelease and separate high viscosity oil.The smart wood has a high absorption speed of 1398 mL/(m_(2)·s)(ethylene glycol)and a maximum absorption capacity of 47.2 g/g(chloroform)due to its intrinsic vertical micro/nanoscale channel structure,low tortuosity,and high porosity.Moreover,the switchable wettability is achieved by the surface coating of poly(N-isopropylacrylamide)on the porous wood,which enables the collection and removal of oil from the oil/water mixture.The high viscosity oil can be automatically released due to the passive oil release at room temperature.The release capacity of the smart wood remains above 91%after 15 cyclic tests.We envision that this functional smart wood could be extended to a wide range of applications in smart hydrogels,microfluidics,artificial drug release,and environmental restoration.展开更多
Zinc-ion batteries(ZIBs)have garnered significant interest owing to their intrinsic safety,environmental compatibility,and low cost.However,nonuniform Zn deposition and parasitic side reactions during cycling lead to ...Zinc-ion batteries(ZIBs)have garnered significant interest owing to their intrinsic safety,environmental compatibility,and low cost.However,nonuniform Zn deposition and parasitic side reactions during cycling lead to rapid capacity decay and potential short-circuiting.To address these challenges,we developed a carboxymethyl cellulose-zinc(CMC-Zn)hydrogel electrolyte with self-release capability using a metal-ion crosslinking approach.The dynamically reversible CMC-Zn network continuously supplies active Zn^(2+)during cycling,compensating for electrode consumption in real time.Abundant carboxylate and hydroxyl groups regulate uniform zinc nucleation and growth,while the hydrogen-bonding network synergistically suppresses side reactions,as reflected by a low hydrogen-evolution potential(−0.281 V)and reduced corrosion current density(0.03 mA cm^(−2)).With these advantages,Zn||Zn symmetric cells achieve an ultralong lifespan of 6,400 h at 0.5 mA cm^(−2),and Zn||Cu half-cells deliver a stable coulombic efficiency of 99.1%over 4,200 cycles.In fullcell testing,self-released Zn^(2+)contributes 29%of the overall capacity,enabling Zn||PANI cells to retain 75%capacity after 2,000 cycles and exhibit a rate-performance recovery of 97.4%.A corresponding flexible ZIB maintains stable operation under various deformation conditions,highlighting the strong potential of CMC-Zn hydrogel electrolytes for next-generation flexible energy-storage devices.展开更多
基金National Natural Science Foundation of China,Grant/Award Numbers:22108125,21971113,22175094Independent Innovation of Agricultural Science and Technology in Jiangsu Province,Grant/Award Numbers:CX(21)3166,CX(21)3163+3 种基金the Natural Science Foundation of Jiangsu Province,Grant/Award Number:BK20210627Doctor Project of Mass Entrepreneurship and Innovation in Jiangsu Province,Grant/Award Number:JSSCBS20210549Nanjing Science&Technology Innovation Project for Personnel Studying Abroad and Research Start-up Funding of Nanjing Forestry University,Grant/Award Number:163020259partially supported by the funding from the New ZealandMinistry of Business,Innovation and Employment(MBIE)in the Framework of the Strategic Science Investment Fund(No.C04X1703,Scion Platforms Plan)。
文摘Designing highly porous materials is of great importance for liquid separation,water purification,and disinfection,such as spill oil cleaning and recycling,seawater desalting,and oil/water separation.However,a remaining challenge is to produce porous materials with the characteristics of fast absorption,continuous directional transport,and self-release of viscous liquid.Herein,a functional cellulosic composite is reported by the chemical treatment and functionalization of wood resulting in a smart wood that can thermally selfrelease and separate high viscosity oil.The smart wood has a high absorption speed of 1398 mL/(m_(2)·s)(ethylene glycol)and a maximum absorption capacity of 47.2 g/g(chloroform)due to its intrinsic vertical micro/nanoscale channel structure,low tortuosity,and high porosity.Moreover,the switchable wettability is achieved by the surface coating of poly(N-isopropylacrylamide)on the porous wood,which enables the collection and removal of oil from the oil/water mixture.The high viscosity oil can be automatically released due to the passive oil release at room temperature.The release capacity of the smart wood remains above 91%after 15 cyclic tests.We envision that this functional smart wood could be extended to a wide range of applications in smart hydrogels,microfluidics,artificial drug release,and environmental restoration.
基金supported by the China University of Petroleum(East China)Independent Innovation Research Program for Young Fund(Grant No.27RA2408006)China University of Petroleum(East China)College Students’Innovation and Entrepreneurship Training Program(Grant No.202506071CX).
文摘Zinc-ion batteries(ZIBs)have garnered significant interest owing to their intrinsic safety,environmental compatibility,and low cost.However,nonuniform Zn deposition and parasitic side reactions during cycling lead to rapid capacity decay and potential short-circuiting.To address these challenges,we developed a carboxymethyl cellulose-zinc(CMC-Zn)hydrogel electrolyte with self-release capability using a metal-ion crosslinking approach.The dynamically reversible CMC-Zn network continuously supplies active Zn^(2+)during cycling,compensating for electrode consumption in real time.Abundant carboxylate and hydroxyl groups regulate uniform zinc nucleation and growth,while the hydrogen-bonding network synergistically suppresses side reactions,as reflected by a low hydrogen-evolution potential(−0.281 V)and reduced corrosion current density(0.03 mA cm^(−2)).With these advantages,Zn||Zn symmetric cells achieve an ultralong lifespan of 6,400 h at 0.5 mA cm^(−2),and Zn||Cu half-cells deliver a stable coulombic efficiency of 99.1%over 4,200 cycles.In fullcell testing,self-released Zn^(2+)contributes 29%of the overall capacity,enabling Zn||PANI cells to retain 75%capacity after 2,000 cycles and exhibit a rate-performance recovery of 97.4%.A corresponding flexible ZIB maintains stable operation under various deformation conditions,highlighting the strong potential of CMC-Zn hydrogel electrolytes for next-generation flexible energy-storage devices.
