Biomass carbon and small redox biomolecules are attractive materials for green,sustainable energy storage devices owing to their environmentally friendly,low-cost,scalable,and novel sources.However,most devices manufa...Biomass carbon and small redox biomolecules are attractive materials for green,sustainable energy storage devices owing to their environmentally friendly,low-cost,scalable,and novel sources.However,most devices manufactured using these materials have low specific capacitance,poor cycle stability,short lifetime,complexity,and low precision of device fabrication.Herein,we report the directed self-assembly of mononuclear anthraquinone(MAQ)derivatives and porous lignin-based graphene oxide(PLGO)into a renewable colloidal gel through noncovalent interactions.These self-assembled gel electrode materials exhibited high capacitance(484.8 F g^(−1) at a current density of 1 A g^(−1))and could be further printed as flexible micro-supercapacitors(FMSCs)with arbitrary patterns and a relatively high resolution on specific substrates.The FMSCs exhibited excellent areal capacitance(43.6 mF cm^(−2)),energy and power densities(6.1μWh cm^(−2) and 50μW cm^(−2),respectively),and cycle stability(>10,000 cycles).Furthermore,the printed FMSCs and integrated FMSC arrays exhibited remarkable flexibility while maintaining a stable capacitance.The proposed approach can be applied to other quinone biomolecules and biomass-based carbon materials.This study provides a basis for fabricating green and sustainable energy storage device architectures with high capacitance,long-term cycling,high scalability,and high precision.展开更多
Summary What is already known about this topic?Fine particulate matter(PM_(2.5))and ozone(O_(3))are prevalent pollutants in the atmosphere,which threaten human health,especially the respiratory system.Typically,people...Summary What is already known about this topic?Fine particulate matter(PM_(2.5))and ozone(O_(3))are prevalent pollutants in the atmosphere,which threaten human health,especially the respiratory system.Typically,people are exposed to a mixture of various pollutants in the environment.Thus,the single and combined effects of both pollutants need to be investigated.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.21905069 and U21A20307)the Shenzhen Science and Technology Innovation Committee(Grant Nos.ZDSYS20190902093220279,KQTD20170809110344233,GXWD20201230155427003-20200821181245001,GXWD20201230155427003-20200821181809001,and ZX20200151)+1 种基金the Department of Science and Technology of Guangdong Province(Grant No.2020A1515110879)University Stable Support Foundation of Shenzhen(Grant No.GXWD20201230155427003-20200821181809001).
文摘Biomass carbon and small redox biomolecules are attractive materials for green,sustainable energy storage devices owing to their environmentally friendly,low-cost,scalable,and novel sources.However,most devices manufactured using these materials have low specific capacitance,poor cycle stability,short lifetime,complexity,and low precision of device fabrication.Herein,we report the directed self-assembly of mononuclear anthraquinone(MAQ)derivatives and porous lignin-based graphene oxide(PLGO)into a renewable colloidal gel through noncovalent interactions.These self-assembled gel electrode materials exhibited high capacitance(484.8 F g^(−1) at a current density of 1 A g^(−1))and could be further printed as flexible micro-supercapacitors(FMSCs)with arbitrary patterns and a relatively high resolution on specific substrates.The FMSCs exhibited excellent areal capacitance(43.6 mF cm^(−2)),energy and power densities(6.1μWh cm^(−2) and 50μW cm^(−2),respectively),and cycle stability(>10,000 cycles).Furthermore,the printed FMSCs and integrated FMSC arrays exhibited remarkable flexibility while maintaining a stable capacitance.The proposed approach can be applied to other quinone biomolecules and biomass-based carbon materials.This study provides a basis for fabricating green and sustainable energy storage device architectures with high capacitance,long-term cycling,high scalability,and high precision.
基金Supported by the National Natural Science Foundation of China(No.82003487,42107310)the Medical Scientific Research Foundation of Guangdong Province(B2023030).
文摘Summary What is already known about this topic?Fine particulate matter(PM_(2.5))and ozone(O_(3))are prevalent pollutants in the atmosphere,which threaten human health,especially the respiratory system.Typically,people are exposed to a mixture of various pollutants in the environment.Thus,the single and combined effects of both pollutants need to be investigated.