Advanced nanoengineering strategies endow highperformance layered transition-metal oxide cathodes for sodium-ion batteries  被引量：3

作　　者：Jun Xiao Yang Xiao Jiayi Li Cheng Gong Xinming Nie Hong Gao Bing Sun Hao Liu Guoxiu Wang 

机构地区：[1]Joint International Laboratory on Environmental and Energy Frontier Materials,School of Environmental and Chemical Engineering,Shanghai University,Shanghai,China [2]Centre for Clean Energy Technology,School of Mathematial and Physical Sciences,Faculty of Science,University of Technology Sydney,Broadway,Sydney,New South Wales,Australia [3]school of Physics and Electronic Engineering,Jiangsu Normal University,Xuzhou,Jiangsu,China

出　　处：《SmartMat》2023年第5期30-56,共27页智能材料（英文）

基　　金：supported by the Australian Research Council(ARC)through the ARC Discovery project(No.DP180102297);Future Fellowship(No.FT180100705);J.X.is grateful for the financial support from China Scholarship Council.AIll authors thank the support from the Science and Technology Commission of Shanghai Municipality(No.22010500400);“The Joint International Laboratory on Environmental and Energy Frontier Materials,"and“Innovation Research Team of High-Level Local Universities in Shanghai"in Shanghai University.

摘　　要：Considering the abundance and low price of sodium,sodium-ion batteries(SIBs)have shown great potential as an alternative to existing lithium-based batteries in large-scale energy storage systems,including electric automobiles and smart grids.Cathode materials,which largely decide the cost and the electrochemical performance of the full SIBs,have been extensively studied.Among the reported cathodes,layered transition-metal oxides(LTMOs)are regarded as the most extremely promising candidates for the commercial application of the SIBs owing to their high specific capacity,superior redox potential,and suitable scalable preparation.Nevertheless,irreversible structural evolution,sluggish kinetics,and water sensitivity are still the critical bottlenecks for their practical utilization.Nanoengineering may offer an opportunity to address the above issues by increasing reactivity,shortening diffusion pathways,and strengthening structural stability.Herein,a comprehensive summary of the modification strategies for LTMOs is presented,emphasizing optimizing the structure,restraining detrimental phase transition,and promoting diffusion kinetics.This review intends to facilitate an in-depth understanding of structure-composition-property correlation and offer guidance to the further development of the LTMO cathodes for next-generation energy storage systems.

关 键 词：cathode materials layered transition-metal oxides modification strategies sodium-ion batteries 

分 类 号：TM912[电气工程—电力电子与电力传动]