共价键
离子键合
纳米孔
表面改性
导电体
灵活性(工程)
纳米技术
金属有机骨架
离子
化学
离子液体
材料科学
钥匙(锁)
渲染(计算机图形)
储能
计算机科学
工程物理
低能
作者
Zhilin Du,Wonmi Lee,Dawei Feng
标识
DOI:10.1021/acsaem.5c01925
摘要
). This review first examines the unique structures and ion transport mechanisms, highlighting how framework flexibility and functionalization lower activation energies for bulky multivalent cations. We then outline structural design principles, including incorporation of ionic groups to maximize ionic conductivity. Key synthetic methods such as mechanical grinding, ball milling, reflux, hydrothermal/solvothermal, and interfacial synthesis are compared in terms of crystallinity, scalability, and environmental impact. Potential applications of MOF/COF as solid electrolytes, membranes, and interfacial coatings for multivalent batteries to improve cycle life. The future research directions are also proposed to enable MOF/COF materials as practical conductors in next-generation multivalent-ion energy storage systems.
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