Porosity Engineering of MOF-Based Materials for Electrochemical Energy Storage

Du Ran; Wu Yifan; Yang Yuchen; Zhai Tingting; Zhou Tao; Shang Qiyao; Zhu Lihua; Shang Congxiao; Guo Zhengxiao

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Porosity Engineering of MOF-Based Materials for Electrochemical Energy Storage

机译：基于MOF的电化学储存材料的孔隙度工程

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Metal-organic frameworks (MOFs) feature rich chemistry, ordered micro-/mesoporous structure and uniformly distributed active sites, offering great scope for electrochemical energy storage (EES) applications. Given the particular importance of porosity for charge transport and catalysis, a critical assessment of its design, formation, and engineering is needed for the development and optimization of EES devices. Such efforts can be realized via the design of reticular chemistry, multiscale pore engineering, synthesis methodologies, and postsynthesis treatment, which remarkably expand the scope of applications. By imparting conductive backbones, guest compounds, and/or redox-active centers, MOFs and their derivatives have been heavily explored for EES in the last decade. To improve the design of MOF-based materials for EES, the strategies of pore architecturing of MOFs and their derivatives are systematically analyzed and their applications reviewed for supercapacitors and metal-ion batteries. Potential challenges and future opportunities are also discussed to guide future development.

机译：金属 - 有机框架（MOFS）具有丰富的化学，有序的微/介孔结构和均匀分布的活性部位，为电化学储能（EES）应用提供了很大的范围。鉴于电荷运输和催化的孔隙度的特殊重要性，需要对EES器件的开发和优化进行设计，地层和工程的关键评估。这种努力可以通过网状化学，多尺度孔工程，合成方法和后合成处理来实现，这显着扩展了应用范围。通过赋予导电骨干，客人化合物和/或氧化还原活性中心，MOF及其衍生物在过去十年中对EES进行了大量探索。为了改善基于MOF的EES材料的设计，系统地分析了MOF和其衍生物的孔架构策略及其对超级电容器和金属离子电池的应用。还讨论了潜在的挑战和未来的机会来引导未来的发展。

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来源
《Advanced energy materials》 |2021年第20期|2100154.1-2100154.47|共47页
作者
Du Ran; Wu Yifan; Yang Yuchen; Zhai Tingting; Zhou Tao; Shang Qiyao; Zhu Lihua; Shang Congxiao; Guo Zhengxiao;
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作者单位

Univ Hong Kong Dept Mech Engn Hong Kong Peoples R China;

Univ Hong Kong Dept Chem Hong Kong Peoples R China;

Univ Hong Kong Zhejiang Inst Res & Innovat Hangzhou 311305 Peoples R China;

Univ Hong Kong Dept Mech Engn Hong Kong Peoples R China;

Univ Hong Kong Dept Chem Hong Kong Peoples R China;

Univ Hong Kong Zhejiang Inst Res & Innovat Hangzhou 311305 Peoples R China;

Univ Hong Kong Dept Chem Hong Kong Peoples R China|Univ Hong Kong Zhejiang Inst Res & Innovat Hangzhou 311305 Peoples R China|Jiangxi Univ Sci & Technol Fac Mat Met & Chem Coll Chem & Chem Engn Ganzhou 341000 Jiangxi Peoples R China;

Univ Hong Kong Dept Chem Hong Kong Peoples R China|Univ Hong Kong Zhejiang Inst Res & Innovat Hangzhou 311305 Peoples R China;

Univ Hong Kong Dept Mech Engn Hong Kong Peoples R China|Univ Hong Kong Dept Chem Hong Kong Peoples R China|Univ Hong Kong Zhejiang Inst Res & Innovat Hangzhou 311305 Peoples R China;

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原文格式 PDF
正文语种 eng
中图分类
关键词
metal#8208; ion batteries; metal#8211; organic frameworks; porosity; porous materials; supercapacitors;

机译：金属＆＃8208;离子电池;金属＆＃8211;有机框架;孔隙度;多孔材料;超级电容器;

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5. Mechanical, Biological and Electrochemical Investigations of Advanced Micro/Nano Materials for Tissue Engineering and Energy Storage. [D] . Pu, Juan. 2016

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6. Structure Engineering in Biomass-Derived Carbon Materials for Electrochemical Energy Storage [O] . Ruizi Li, Yanping Zhou, Wenbin Li, 2020

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7. Electrochemical Energy Storage: Porosity Engineering of MOF‐Based Materials for Electrochemical Energy Storage (Adv. Energy Mater. 20/2021) [O] . Ran Du, Yifan Wu, Yuchen Yang, 2021

机译：电化学储能：电化学储能基于MOF的材料孔隙率工程（ADV。能源母体。20/2021）

Porosity Engineering of MOF-Based Materials for Electrochemical Energy Storage

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