Immobilized Supramolecular Systems as Efficient Synzymes for CO2 Activation and Conversion

Supramolecular catalysis can provide distinct advantages for the catalytic conversion of CO2 into carbonates by cycloaddition to epoxides. For example, the absence of metals in the catalytic site, and the easy design for optimization. The incorporation of multiple functionalities in pseudopeptidic macrocycles with a pendant arm allows catalytic systems to be obtained where halide anions (nucleophilic activating agents for epoxides), hydrogen bond acceptor sites (activating agents for epoxides and stabilizing sites for anionic intermediates), and amine groups (Lewis basic sites for activating CO2) are in proximity. This allows a high activity in the cycloaddition of CO2 to styrene oxide under mild conditions (turnover number (TON) = 900, CO2 balloon, 100 degrees C, 5 h). The primary amino groups in the arm facilitate the immobilization of these macrocyclic structures in cross-linked polymeric matrices containing ammonium halide fragments. Such multifunctional insoluble polymers afford excellent catalytic results with high TON and turnover frequency values and remarkable productivities (>10 g(prod) g(resin)(-1) h(-1)). This activity is maintained for a variety of epoxides and is retained after several catalytic runs. Their performance is significantly higher than those reported for most heterogenous supramolecular catalytic systems for CO2 transformation into carbonates.

Automated summary

Supramolecular catalysis offers distinct advantages for the catalytic conversion of CO2 to carbonates by cycloaddition to epoxides. The incorporation of multiple functionalities in pseudopeptidic macrocycles allows the proximity of nucleophilic activating agents, hydrogen bond acceptor sites and Lewis basic sites, leading to high catalytic activity under mild conditions.