Sustainable energy conversion and storage technologies are a vital prerequisite for neutral future carbon.To this end,carbon materials with attractive features,such as tunable pore architecture,good electrical conduct...Sustainable energy conversion and storage technologies are a vital prerequisite for neutral future carbon.To this end,carbon materials with attractive features,such as tunable pore architecture,good electrical conductivity,outstanding physicochemical stability,abundant resource,and low cost,have used as promising electrode materials for energy conversion and storage.Defect engineering could modulate the structures of carbon materials,thereby affecting their electronic properties.The presence of defects on carbons may lead to asymmetric charge distribution,change in geometrical configuration,and distortion of the electronic structure that may result in unexpected electrochemical performances.In this review,recent advances in defects of carbons used for energy conversion and storage were examined in terms of types,regulation strategies,and fine characterization means of defects.The applications of such carbons in supercapacitors,rechargeable batteries,and electrocatalysis were also discussed.The perspectives toward the development of defect engineering carbons were proposed.In all,novel insights related to improvement in high-performance carbon materials for future energy conversion and storage applications were provided.展开更多
Biomass is rich,renewable,sustainable,and green resources,thereby excellent raw material for the fabrication of carbon materials.The diversity in structure and morphology of biomass are relevant in obtaining carbon ma...Biomass is rich,renewable,sustainable,and green resources,thereby excellent raw material for the fabrication of carbon materials.The diversity in structure and morphology of biomass are relevant in obtaining carbon materials with dif-ferent structures and performances.The inherent ordered porous structure of biomass also benefits the activation process to yield porous carbons with ultra-high specific surface area and pore volume.Besides,obtained biomass-derived carbons(BDCs)are hard carbon with porous morphology,stable structure,supe-rior hardness/strength,and good cycling performances when used in electro-chemical capacitors(ECs).The inherent N,S,P,and O elements in biomass yield naturally self-doped N,S,P,and O BDCs with unique intrinsic structures.In this paper,the synthesis approaches and applications of BDCs in ECs are reviewed.It shows that BDCs electrochemical performances are highly determined by their pore structures,specific surface areas,heteroatoms doping,graphitization degree,defects,and morphologies.The electrochemical performances of BDCs can further be improved by compositing with other materials,such as graphene,carbon nanofibers/nanotubes,transition metal oxides or hydroxides,and con-ducting polymers.The future challenges and outlooks of BDCs are also provided.展开更多
基金the National Natural Science Foundation of China(52062012)Key Science&Technology Project of Hainan Province(ZDYF2020028)+2 种基金Key-Area Research and Development Program of Guangdong Province(2019B1102109003)the Innovation Team of Universities of Guangdong Province(2020KCXTD011)Guangdong Province Key Discipline Construction Project(2021ZDJS102).
文摘Sustainable energy conversion and storage technologies are a vital prerequisite for neutral future carbon.To this end,carbon materials with attractive features,such as tunable pore architecture,good electrical conductivity,outstanding physicochemical stability,abundant resource,and low cost,have used as promising electrode materials for energy conversion and storage.Defect engineering could modulate the structures of carbon materials,thereby affecting their electronic properties.The presence of defects on carbons may lead to asymmetric charge distribution,change in geometrical configuration,and distortion of the electronic structure that may result in unexpected electrochemical performances.In this review,recent advances in defects of carbons used for energy conversion and storage were examined in terms of types,regulation strategies,and fine characterization means of defects.The applications of such carbons in supercapacitors,rechargeable batteries,and electrocatalysis were also discussed.The perspectives toward the development of defect engineering carbons were proposed.In all,novel insights related to improvement in high-performance carbon materials for future energy conversion and storage applications were provided.
基金National Natural Science Founda-tion of China,Grant/Award Numbers:52062012,51525206,520105010,21603048Key Science&Technology Project of Hainan Province,Grant/Award Number:ZDYF2020028。
文摘Biomass is rich,renewable,sustainable,and green resources,thereby excellent raw material for the fabrication of carbon materials.The diversity in structure and morphology of biomass are relevant in obtaining carbon materials with dif-ferent structures and performances.The inherent ordered porous structure of biomass also benefits the activation process to yield porous carbons with ultra-high specific surface area and pore volume.Besides,obtained biomass-derived carbons(BDCs)are hard carbon with porous morphology,stable structure,supe-rior hardness/strength,and good cycling performances when used in electro-chemical capacitors(ECs).The inherent N,S,P,and O elements in biomass yield naturally self-doped N,S,P,and O BDCs with unique intrinsic structures.In this paper,the synthesis approaches and applications of BDCs in ECs are reviewed.It shows that BDCs electrochemical performances are highly determined by their pore structures,specific surface areas,heteroatoms doping,graphitization degree,defects,and morphologies.The electrochemical performances of BDCs can further be improved by compositing with other materials,such as graphene,carbon nanofibers/nanotubes,transition metal oxides or hydroxides,and con-ducting polymers.The future challenges and outlooks of BDCs are also provided.
