De novo construction of amine-functionalized metal-organic cages as heterogenous catalysts for microflow catalysis

• Published in: Nature communications Vol. 15; no. 1; pp. 7044 - 12
• Main Authors: Li, Yingguo, He, Jialun, Lu, Guilong, Wang, Chensheng, Fu, Mengmeng, Deng, Juan, Yang, Fu, Jiang, Danfeng, Chen, Xiao, Yu, Ziyi, Liu, Yan, Yu, Chao, Cui, Yong
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 15.08.2024; Nature Publishing Group; Nature Portfolio
• Subjects: 639/638/541/965; 639/638/549/976; 639/638/77/887; Aldehydes; Amines; Automation; Cages; Catalysis; Catalysts; Chemical bonds; Chemical synthesis; Continuous flow; Covalence; Covalent bonds; Humanities and Social Sciences; Manufacturing; Mass transfer; Microfluidics; Microreactors; multidisciplinary; Multiphase; Reactors; Recyclability; Science; Science (multidisciplinary); Substrates
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-024-51431-5

Microflow catalysis is a cutting-edge approach to advancing chemical synthesis and manufacturing, but the challenge lies in developing efficient and stable multiphase catalysts. Here we showcase incorporating amine-containing metal-organic cages into automated microfluidic reactors through covalent bonds, enabling highly continuous flow catalysis. Two Fe 4 L 4 tetrahedral cages bearing four uncoordinated amines were designed and synthesized. Post-synthetic modifications of the amine groups with 3-isocyanatopropyltriethoxysilane, introducing silane chains immobilized on the inner walls of the microfluidic reactor. The immobilized cages prove highly efficient for the reaction of anthranilamide with aldehydes, showing superior reactivity and recyclability relative to free cages. This superiority arises from the large cavity, facilitating substrate accommodation and conversion, a high mass transfer rate and stable covalent bonds between cage and microreactor. This study exemplifies the synergy of cages with microreactor technology, highlighting the benefits of heterogenous cages and the potential for future automated synthesis processes Microflow catalysis represents a cutting-edge method for advancing chemical synthesis and manufacturing, though developing efficient and stable multiphase catalysts remains challenging. Here the authors demonstrate the incorporation of amine-containing metal-organic cages into automated microfluidic reactors through covalent bonds, facilitating highly continuous flow catalysis.