Porosity Engineering of MOF-Based Materials for Electrochemical Energy Storage

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.

Automated summary

Metal-organic frameworks (MOFs) provide great potential for electrochemical energy storage (EES) applications due to their rich chemistry and uniformly distributed active sites. Through design and engineering, their scope of applications can be expanded, with potential uses in supercapacitors and metal-ion batteries.