Abstract
Catalytic transformation of CO(2) to formate is generally realized through bicarbonate hydrogenation in an alkaline environment, while it suffers from a thermodynamic sink due to the considerable thermodynamic stability of the bicarbonate intermediate. Here, we devise a route for the direct catalytic conversion of CO(2) over a Schiff-base-modified gold nanocatalyst that is comparable to the fastest known nanocatalysts, with a turnover number (TON) of up to 14,470 over 12 h at 90 °C. Theoretical calculations and spectral analysis results demonstrate that the activation of CO(2) can be achieved through a weakly bonded carbamate zwitterion intermediate derived from a simple Lewis base adduct of CO(2). However, this can only occur with a hydrogen lacking Lewis base center in a polar solvent. This finding offers a promising avenue for the direct activation of CO(2) and is likely to have considerable implications in the fields of CO(2) conversion and gold catalytic chemistry.