A DFT study of methanol synthesis from CO2 hydrogenation on Cu/ ZnO catalyst

The usage of CO2, a vital carbon source, is of great application value in carbon neutrality. Hydrogenation is one of the most promising approaches to convert the CO2 into high-value chemicals like methanol. The development of the hydrogenation of CO2 mainly lies in the design of safe and efficient catalysts. Focusing on the mechanism and the interface effects, the hydrogenation of CO2 to methanol over Cu/ZnO-based catalyst was investigated in this work. To study the enhancing effect of metal promoters, atomic doping was simulated on Cu/ZnO-X(Al,Mg, Ga,Pt,Pd,Au) catalyst. Based on the designed atomic doped mode, density functional theory (DFT) calculation was conducted to analyze the adsorption of intermediates, thermodynamic reaction path, and kinetics of CO2 methanolization. The results show that Cu-ZnO heterostructure improves the HCOO path of CO2 hydrogenation by metal-support interaction (MSI). A linear relationship between the adsorption energy of the intermediates via hydrogenation process was found with the correlation coefficient R-2 approximate to 0.8. The order of the highest activation barriers for the overall reaction is Cu/ZnO-Au > Cu/ZnO-Mg > Cu/ZnO-Pd > Cu/ZnO-Pt > Cu/ZnO-Ga > Cu/ZnO > Cu/ZnO-Al. The diverse performance of various metal promoters was ranked as Al > Ga > Mg, Pt > Pd > Au. Our simulation work well corresponds the previous experimental results conducted by other scholars and will provide guidance for future design of the high-efficient catalysis for CO2 hydrogenation.

Automated summary

This work investigates the hydrogenation of CO2 to methanol over Cu/ZnO-based catalyst by focusing on the mechanism and interface effects. Atomic doping of Cu/ZnO-X(Al,Mg,Ga,Pt,Pd,Au) catalyst was simulated to study the enhancing effect of metal promoters. Density functional theory (DFT) calculation was conducted to analyze the adsorption, thermodynamics, and kinetics of CO2 methanolization. The simulation results provide guidance for the design of high-efficiency catalysis for CO2 hydrogenation and are consistent with previous experimental results.