Among the various morphologies of carbon-based materials,hollow carbon nanostructures are of particular interest for energy storage.They have been widely investigated as electrode materials in different types of recha...Among the various morphologies of carbon-based materials,hollow carbon nanostructures are of particular interest for energy storage.They have been widely investigated as electrode materials in different types of rechargeable batteries,owing to their high surface areas in association with the high surface-to-volume ratios,controllable pores and pore size distribution,high electrical conductivity,and excellent chemical and mechanical stability,which are beneficial for providing active sites,accelerating electrons/ions transfer,interacting with electrolytes,and giving rise to high specific capacity,rate capability,cycling ability,and overall electrochemical performance.In this overview,we look into the ongoing progresses that are being made with the nanohollow carbon materials,including nanospheres,nanopolyhedrons,and nanofibers,in relation to their applications in the main types of rechargeable batteries.The design and synthesis strategies for them and their electrochemical performance in rechargeable batteries,including lithium-ion batteries,sodium-ion batteries,potassium-ion batteries,and lithium–sulfur batteries are comprehensively reviewed and discussed,together with the challenges being faced and perspectives for them.展开更多
Engineering non-precious metals into nitrogen-doped carbon is employed to improve electrocatalyst activity towards oxygen reduction reaction(ORR). A nickel-doped Co-N/C mesoporous nanopolyhedron is successfully evolut...Engineering non-precious metals into nitrogen-doped carbon is employed to improve electrocatalyst activity towards oxygen reduction reaction(ORR). A nickel-doped Co-N/C mesoporous nanopolyhedron is successfully evoluted from a Ni-doped ZIF-67 precursor. The Ni & Co synergistic N/C catalyst exhibits a half-wave potential of 0.895 V(vs. reversible hydrogen electrode(RHE)) with a diffusion-limiting current density of 6.1 m A cm^(-2)for alkaline ORR at 1600 r min^(-1), which is competitive to commercial Pt/C in terms of cost, methanol tolerance, and long-term stability. In situ surface-enhanced Raman scattering(SERS) study reveals the formation and fast conversion of superoxide ion(O_(2)^(-)) intermediate on the catalyst surface. Density functional theory(DFT) calculations demonstrate the decrease of energy barrier for potential-determining step(O* protonation) by Co-Ni synergy as well as the reduction of adsorption energy on catalyst surface upon nickel doping. The joint results of in situ SERS study and DFT calculations suggest a favourable ORR process on nickel-doped Co-N/C.展开更多
基金This work was supported by the National Natural Science Foundation of China(U1802256,51672128,21773118,21875107,51802154)the Key Research and Development Program in Jiangsu Province(BE2018122)+3 种基金Project Funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions(PAPD).Prof.John Wang and team acknowledge the support by MOE,Singapore Ministry of Education(MOE2018-T2-2-095),for research conducted at the National University of SingaporeMr.Jiangmin Jiang would like to acknowledge the financial support from the Funding of Outstanding Doctoral Dissertation in NUAA(BCXJ19-07)Postgraduate Research&Practice Innovation Program of Jiangsu Province(KYCX19_0174)China Scholarship Council(201906830060).
文摘Among the various morphologies of carbon-based materials,hollow carbon nanostructures are of particular interest for energy storage.They have been widely investigated as electrode materials in different types of rechargeable batteries,owing to their high surface areas in association with the high surface-to-volume ratios,controllable pores and pore size distribution,high electrical conductivity,and excellent chemical and mechanical stability,which are beneficial for providing active sites,accelerating electrons/ions transfer,interacting with electrolytes,and giving rise to high specific capacity,rate capability,cycling ability,and overall electrochemical performance.In this overview,we look into the ongoing progresses that are being made with the nanohollow carbon materials,including nanospheres,nanopolyhedrons,and nanofibers,in relation to their applications in the main types of rechargeable batteries.The design and synthesis strategies for them and their electrochemical performance in rechargeable batteries,including lithium-ion batteries,sodium-ion batteries,potassium-ion batteries,and lithium–sulfur batteries are comprehensively reviewed and discussed,together with the challenges being faced and perspectives for them.
基金supported by the National Natural Science Foundation of China (No. 21874053)the Science and Technology Development Project of Jilin Province, China (No. 20180414022GH)funding from the Advanced Low Carbon Technology Research and Development Program (ALCA), specially promoted research for innovative nextgeneration batteries (SPRING)。
文摘Engineering non-precious metals into nitrogen-doped carbon is employed to improve electrocatalyst activity towards oxygen reduction reaction(ORR). A nickel-doped Co-N/C mesoporous nanopolyhedron is successfully evoluted from a Ni-doped ZIF-67 precursor. The Ni & Co synergistic N/C catalyst exhibits a half-wave potential of 0.895 V(vs. reversible hydrogen electrode(RHE)) with a diffusion-limiting current density of 6.1 m A cm^(-2)for alkaline ORR at 1600 r min^(-1), which is competitive to commercial Pt/C in terms of cost, methanol tolerance, and long-term stability. In situ surface-enhanced Raman scattering(SERS) study reveals the formation and fast conversion of superoxide ion(O_(2)^(-)) intermediate on the catalyst surface. Density functional theory(DFT) calculations demonstrate the decrease of energy barrier for potential-determining step(O* protonation) by Co-Ni synergy as well as the reduction of adsorption energy on catalyst surface upon nickel doping. The joint results of in situ SERS study and DFT calculations suggest a favourable ORR process on nickel-doped Co-N/C.