The worldwide proliferation of portable electronics has resulted in a dramatic increase in the number of spent lithium-ion batteries(LIBs).However,traditional recycling methods still have limitations because of such h...The worldwide proliferation of portable electronics has resulted in a dramatic increase in the number of spent lithium-ion batteries(LIBs).However,traditional recycling methods still have limitations because of such huge amounts of spent LIBs.Therefore,we proposed an ecofriendly and sustainable double recycling strategy to concurrently reuse the cathode(LiCoO_(2))and anode(graphite)materials of spent LIBs and recycled LiCoPO_(4)/graphite(RLCPG)in Li^(+)/PF^(-)_(6) co-de/intercalation dual-ion batteries.The recycle-derived dualion batteries of Li/RLCPG show impressive electrochemical performance,with an appropriate discharge capacity of 86.2 mAh·g^(-1) at25 mA·g^(-1) and 69%capacity retention after 400 cycles.Dual recycling of the cathode and anode from spent LIBs avoids wastage of resources and yields cathode materials with excellent performance,thereby offering an ecofriendly and sustainable way to design novel secondary batteries.展开更多
The demand for large-scale energy storage is increasing due to the decreasing non-renewable resources and deteriorating environmental pollution.Developing rechargeable batteries with high energy density and long cycle...The demand for large-scale energy storage is increasing due to the decreasing non-renewable resources and deteriorating environmental pollution.Developing rechargeable batteries with high energy density and long cycle performance is an ideal choice to meet the demand of energy storage system.The development of excellent electrode particles is of great significance in the commercialization of nextgeneration batteries.The ideal electrode particles should balance raw material reserves,electrochemical performance,price and environmental protection.Among them,the development of electrode particulate materials with excellent electrochemical properties is the top priority at present.In this review,the typical researches of electrode materials are summarized in terms of crystal structure,morphology,pore structure,surface and interface regulation.Firstly,the structural characteristics and improvement methods of transition metal oxides,polyanionic compounds,Prussian blue and their analogues are introduced.Then,the different effects of particulate morphology,pore,surface and interface structure on the performance of electrode materials are discussed.For designing high-performance electrode materials,preparation route should be set according to the particle properties of the materials and the synergistic effect of various optimization methods should be adopted.At the same time,in addition to the electrode materials,other components of the rechargeable batteries,such as current collector,separator and electrolytes,should be optimized to improve the overall performance of the batteries.This review would provide important guiding principle for designing high-performance electrode particulate materials.展开更多
基金the National Natural Science Foundation of China(No.52173246)the Science and Technology Planning Project of Guangzhou City,China(No.2023B03J1278)。
文摘The worldwide proliferation of portable electronics has resulted in a dramatic increase in the number of spent lithium-ion batteries(LIBs).However,traditional recycling methods still have limitations because of such huge amounts of spent LIBs.Therefore,we proposed an ecofriendly and sustainable double recycling strategy to concurrently reuse the cathode(LiCoO_(2))and anode(graphite)materials of spent LIBs and recycled LiCoPO_(4)/graphite(RLCPG)in Li^(+)/PF^(-)_(6) co-de/intercalation dual-ion batteries.The recycle-derived dualion batteries of Li/RLCPG show impressive electrochemical performance,with an appropriate discharge capacity of 86.2 mAh·g^(-1) at25 mA·g^(-1) and 69%capacity retention after 400 cycles.Dual recycling of the cathode and anode from spent LIBs avoids wastage of resources and yields cathode materials with excellent performance,thereby offering an ecofriendly and sustainable way to design novel secondary batteries.
基金the National Key Research and Development Program of China(grant No.2023YFE0202000)National Natural Science Foundation of China(grant No.52102213)Science Technology Program of Jilin Province(grant No.20230101128JC).
文摘The demand for large-scale energy storage is increasing due to the decreasing non-renewable resources and deteriorating environmental pollution.Developing rechargeable batteries with high energy density and long cycle performance is an ideal choice to meet the demand of energy storage system.The development of excellent electrode particles is of great significance in the commercialization of nextgeneration batteries.The ideal electrode particles should balance raw material reserves,electrochemical performance,price and environmental protection.Among them,the development of electrode particulate materials with excellent electrochemical properties is the top priority at present.In this review,the typical researches of electrode materials are summarized in terms of crystal structure,morphology,pore structure,surface and interface regulation.Firstly,the structural characteristics and improvement methods of transition metal oxides,polyanionic compounds,Prussian blue and their analogues are introduced.Then,the different effects of particulate morphology,pore,surface and interface structure on the performance of electrode materials are discussed.For designing high-performance electrode materials,preparation route should be set according to the particle properties of the materials and the synergistic effect of various optimization methods should be adopted.At the same time,in addition to the electrode materials,other components of the rechargeable batteries,such as current collector,separator and electrolytes,should be optimized to improve the overall performance of the batteries.This review would provide important guiding principle for designing high-performance electrode particulate materials.