Water and Cu Synergy in Selective CO Hydrogenation to Methanol over Cu-MgO-AlO Catalysts.

The CO hydrogenation reaction to produce methanol holds great significance as it contributes to achieving a CO-neutral economy. Previous research identified isolated Cu species doping the oxide surface of a Cu-MgO-AlO-mixed oxide derived from a hydrotalcite precursor as the active site in CO hydrogenation, stabilizing monodentate formate species as a crucial intermediate in methanol synthesis. In this work, we present a molecular-level understanding of how surface water and hydroxyl groups play a crucial role in facilitating spontaneous CO activation at Cu sites and the formation of monodentate formate species. Computational evidence has been experimentally validated by comparing the catalytic performance of the Cu-MgO-AlO catalyst with hydroxyl groups against that of its hydrophobic counterpart, where hydroxyl groups are blocked using an esterification method. Our work highlights the synergistic effect between doped Cu ions and adjacent hydroxyl groups, both of which serve as key parameters in regulating methanol production via CO hydrogenation. By elucidating the specific roles of these components, we contribute to advancing our understanding of the underlying mechanisms and provide valuable insights for optimizing methanol synthesis processes.