Metal-organic framework based catalytic nanoreactors: synthetic challenges and applications

Catalytic nanoreactors have become hugely important in the field of heterogeneous catalysis due to their intriguing catalytic activity and the stability of the nanocatalysts inside the protective shell. Metal-organic frameworks (MOFs) are an attractive choice as the shell material for catalyst encapsulation, owing to the remarkable progress that has been made toward developing: flexible synthetic methods, diversified chemical functionalities, tunable pore structures, and low-cost, easy production methods. A porous MOF shell can be combined with in-house catalyst particles to deliver a selectively transformed product, while limiting the loss of activity and surface area of the entrapped catalysts, even under harsh reaction conditions or during recycling tests. Moreover, the rich surface chemistries of MOFs have often guided their direct or indirect participation, influencing the overall outcome of MOF-based catalytic nanoreactors. This review surveys the methods used for functionalizing MOFs with catalyst entities loaded inside. The possible complications during packaging the catalysts of different sizes, shapes, properties, or compositions are considered, and the developed footprints towards overcoming such difficulties have been discussed. Finally, the catalytic applications of MOF-based catalytic nanoreactors in different fields are summarized.

Automated summary

Metal-organic frameworks (MOFs) are attractive choices for shell materials in catalytic nanoreactors due to their tunable pore structures, rich surface chemistries, and cost-effective production methods. Combining a porous MOF shell with internal catalyst particles can enhance product selectivity and minimize loss of catalyst activity and surface area. The diverse surface chemistries of MOFs play a crucial role in influencing the overall outcome of MOF-based catalytic nanoreactors.