Structural and chemical engineering of metal-organic framework-derived nickel disulfide nanosheets as the compacted cathode matrix for lithium-sulfur batteries

作     者：Qi Zhang Wenxiang Shen Pengyue Li Jinshang Song Lingzhi Zhu Enshan Han Ruihu Wang Xiaoju Li Qi Zhang;Wenxiang Shen;Pengyue Li;Jinshang Song;Lingzhi Zhu;Enshan Han;Ruihu Wang;Xiaoju Li

作者机构：Hebei Key Laboratory of Functional PolymerSchool of Chemical Engineering and TechnologyHebei University of TechnologyTianjin300130China Fujian Provincial Key Laboratory of Polymer MaterialsCollege of Chemistry and Materials ScienceFujian Normal UniversityFuzhou350007China 

出 版 物：《Chinese Journal of Structural Chemistry》 (结构化学（英文）)

年 卷 期：2023年第42卷第9期

页      面：34-40页

核心收录：

学科分类：0808[工学-电气工程] 07[理学] 08[工学] 0703[理学-化学] 070301[理学-无机化学] 

基　　金：financially supported by Natural Science Foundation of Fujian Province(2019J01426) National Natural Science Foundation of China(21671039) State Key Laboratory of Structural Chemistry. 

主　　题：Lithium-sulfur batteries Metal-organic frameworks Nanosheets Nickel disulfide Shuttling effect 

摘      要：Lithium-sulfur(Li–S)batteries are recognized as promising high-energy-density storage systems.It is crucial to develop the compacted sulfur cathodes with high sulfur content and high sulfur loading for practical applications.The metal-containing nanosheets are promising cathode matrix to mediate the accompanying problems,such as low sulfur utilization,unavoidable polysulfides shuttling and poor rate performance.Herein,we develop Ni-MOF-based strategy to fabricate nickel disulfide nanosheets on the reduced graphene oxide surface(NSG).Benefiting from nanosheets structure,strong polysulfides affinity,high electronic conductivity and superior electrocatalytic effect of NSG heterostructure,the resultant electrode exhibits high electrochemical performance with 0.021%capacity decay per cycle in 1000 cycles.Remarkably,the electrode with 88 wt%sulfur content and 5.9 mg cm^(−2) sulfur loading delivers reversible capacity of 945 mA h g^(−1),areal capacity of 6.1 mA h cm^(−2) and volumetric capacity of 997 mA h cm^(−3) at 0.5 C,which is comparable with the state-of-the-art those in the reported energy storage systems.This work provides methodology guidance for the development of cathode matrix to achieve high-energy-density and long-life Li–S batteries.