Bulk scale utilization of CO2 as C1 feedstock is very demanding not only from the environmental perspective, but it is very challenging for addressing the global energy crisis, carbon recycling,… Click to show full abstract
Bulk scale utilization of CO2 as C1 feedstock is very demanding not only from the environmental perspective, but it is very challenging for addressing the global energy crisis, carbon recycling, and sustainability. Functionalized porous materials having CO2 adsorption sites and large internal surface areas are the ideal candidates for catalyzing the fixation of CO2 into fuels and commodity chemicals. In this review we have highlighted the advancements made in designing different class of microporous and mesoporous materials (zeolites, mesoporous materials, MOFs, COFs, POPs, metal phosphonates, etc.) over the years for the synthesis of cyclic carbonates, polycarbonates, carbamates, Nâformylated amines, polyhydroxyurethanes, ureas, imidazoles, and related heterocyclic compounds through CO2 fixation reactions. Further, direct CO2 reduction to methanol, dimethyl ether (DME), formic acid, ethanol, etc. are particularly important in the context of renewable energy. We have discussed the catalytic role of different class of porous nanomaterials for understanding the promotional role of the reactive sites in catalyzing these CO2 conversion reactions. Mechanistic aspects of these chemical transformations are illustrated with a major emphasis on the key factors affecting the CO2 and substrate activation processes. Finally, the challenges faced by the researchers in achieving the desired targets in these CO2 conversion reactions are highlighted, which could contribute significantly in carbon recycling in the future.
               
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