Engineering the Cu/Mo2CTx (MXene) interface to drive CO2 hydrogenation to methanol

Development of efficient catalysts for the direct hydrogenation of CO2 to methanol is essential for the valorization of this abundant feedstock. Here we show that a silica-supported Cu/Mo2CTx (MXene) catalyst achieves a higher intrinsic methanol formation rate per mass Cu than the reference Cu/SiO2 catalyst with a similar Cu loading. The Cu/Mo2CTx interface can be engineered due to the higher affinity of Cu for the partially reduced MXene surface (in preference to the SiO2 surface) and the mobility of Cu under H-2 at 500 degrees C. With increasing reduction time, the Cu/Mo2CTx interface becomes more Lewis acidic due to the higher amount of Cu+ sites dispersed onto the reduced Mo2CTx and this correlates with an increased rate of CO2 hydrogenation to methanol. The critical role of the interface between Cu and Mo2CTx is further highlighted by density functional theory calculations that identify formate and methoxy species as stable reaction intermediates.

Automated summary

In this study, an optimized Cu/Mo2CTx interface was achieved through engineering methods, leading to higher efficiency in the catalytic conversion of CO2 to methanol. Density functional theory calculations confirmed the critical role of the interface between Cu and Mo2CTx in stabilizing reaction intermediates.