多硫化物
化学
硫黄
氧化还原
吸附
纳米技术
体积热力学
串联
工作(物理)
催化作用
连接器
合理设计
体积膨胀
化学工程
拓扑(电路)
土壤孔隙空间特征
法拉第效率
锂(药物)
表面改性
动力学
储能
作者
Yuqian Sun,Bohan Wang,Wangzhi Li,Zhongwen Jiang,TT Li,Haozhi Xi,Y C Yan,Qiaowei Li
摘要
Lithium–sulfur (Li–S) batteries are promising next-generation energy storage systems, yet critical challenges including severe sulfur volume expansion, uncontrolled lithium polysulfide (LiPS) shuttling, and sluggish sulfur redox kinetics impede their practical application. Herein, we develop a metal–organic framework (MOF) functionalization strategy across three distinct structural modules (MOF backbone, grafted modulators, and engineered pore space) to tackle these issues. Specifically, in the newly synthesized Zr-based spn topology FDM-221, its high surface area (1956 m 2 g –1 ) and large pore volume (1.35 cm 3 g –1 ) provide ample pore space to accommodate sulfur volume expansion even after high sulfur encapsulation. Furthermore, sulfiphilic sites (coordinatively unsaturated Zr(IV) in the framework backbone) and lithiophilic moieties (S atoms from the benzotrithiophene-based linker and F atoms from the dangling modulators) work in tandem to furnish robust binding sites for LiPS adsorption while concurrently accelerating the redox catalysis of sulfur species. Li–S batteries based on this trinity structure deliver a high capacity of 1164 mAh g –1 at 0.1C and excellent cycling stability over 1000 cycles at 2C, demonstrating the great potential of this MOF design strategy for next-generation batteries.
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