A substituent- and temperature-controllable NHC-derived zwitterionic catalyst enables CO2 upgrading for high-efficiency construction of formamides and benzimidazoles

Chemocatalytic upgrading of the greenhouse gas CO2 to valuable chemicals and biofuels has attracted broad attention in recent years. Among the reported approaches, N-formylation of CO2 with an amine is of great significance due to its versatility in the construction of N-containing linear and cyclic skeletons. Herein, a stable N-heterocyclic carbene-carboxyl adduct (NHC-CO2) was facilely prepared and could be used as a recyclable zwitterionic catalyst for efficient CO2 reductive upgrading via either N-formylation or further coupling with cyclization under mild conditions (25 degrees C, 1 atm CO2) using hydrosilane as a hydrogen source. More than 30 different alkyl and aromatic amines could be transformed into the corresponding formamides or benzimidazoles with remarkable yields (74%-98%). The electronic effect of the introduced substituent on NHC-CO2 was found to evidently affect the thermostability and nucleophilicity of the zwitterionic catalyst, which is directly correlated with its catalytic activity. Moreover, NHC-CO2 could supply CO2 by in situ decarboxylation at a specific temperature that is dependent on the introduced substituent type. Experimental and computational studies showed that the carboxyl species on NHC-CO2 was not only a nucleophilic center, but also a C1 source which rapidly captures or substitutes ambient CO2 during hydrosilylation. In addition, a simple and green conceptual process was designed for the product purification and catalyst recycling, with a good feasibility for small-scale production.

Automated summary

Chemocatalytic upgrading of CO2 to valuable chemicals and biofuels has drawn significant attention, with N-formylation of CO2 with an amine playing a crucial role in constructing N-containing linear and cyclic skeletons. A stable N-heterocyclic carbene-carboxyl adduct (NHC-CO2) was developed as a recyclable zwitterionic catalyst for efficient CO2 reductive upgrading, achieving remarkable yields of up to 98%. The introduced substituent on NHC-CO2 was found to impact its thermostability and nucleophilicity, directly influencing catalytic activity. Additionally, NHC-CO2 demonstrated the ability to supply CO2 through in situ decarboxylation at specific temperatures.