Mechanism of formaldehyde and formic acid formation on (101)-TiO@Cu systems through CO hydrogenation

The decoration of a copper cluster on the anatase phase of a (101)-TiO 2 surface to increase the reduction of CO 2 has gained significant interest and potential to trigger sustainable solar-fuel-based economy. In the present work, we studied a heterogeneous surface for the reduction of CO 2 , which can produce various organic compounds such as formic acid, formaldehyde, methanol, ethanol, and methane. The density functional theory calculations were employed to study the formation of formaldehyde and methanol from CO 2 via hydrogenation by H 2 on a Cu catalyst. The copper cluster is a unique catalyst for charge separation and conversion into important organic compounds. Theoretical investigations suggest that these organic compounds can be used as feedstock or be converted into solar fuel. The decoration of a copper cluster on the anatase phase of a (101)-TiO 2 surface to increase the reduction of CO 2 has gained significant interest and potential to trigger sustainable solar-fuel-based economy.