Control of Selectivity in Homogeneous Catalysis through Noncovalent Interactions

The regio-, site-, stereo- or chemoselective homogeneous catalytic transformations are extremely important for the growth/success of the current chemical industry. Based on empirical, theoretical or intuitive knowledge, several synthetic strategies, such as ligand design, transient directing group, metal node alternation, metal-ligand cooperation, pore decoration, biomimetic, have already been developed for the selective functionalization of organic substrates. In comparison to the other tactics, the use of noncovalent interactions for the control of selectivity in catalytic transformations of organic compounds may avoid multi-steps, reduce time of synthetic procedure, decrease cost of operation, and increase reactivity of catalyst. In fact, enzymes achieve a high selectivity through noncovalent interactions in biochemical processes in Nature. Guided by the impressive performance of enzymes in biosynthesis and biodegradation reactions, various types of synthetic metal complex or organocatalysts have already been developed, in which the catalyst-substrate noncovalent interactions have a pivotal impact on the distinctive stabilization of the transition states or intermediates, directing selectivity and improving efficiency of homogeneous catalytic reactions. Herein, we highlight several recent and relevant examples of selectivity directing/driving function of noncovalent interactions in the transformation of organic substrate(s) catalyzed by both organocatalysts and metal complex catalysts.

Automated summary

The regio-, site-, stereo- or chemoselective homogeneous catalytic transformations are crucial for the growth/success of the chemical industry. Noncovalent interactions have shown potential in controlling selectivity, reducing synthetic steps, and increasing the reactivity of catalyst. Inspired by enzymes, various types of synthetic metal complex and organocatalysts have been developed, where noncovalent interactions play a pivotal role in directing selectivity and improving efficiency. This article highlights recent examples of noncovalent interaction-based selectivity control in catalytic transformations of organic substrates.