Complexity of a Co3O4 System under Ambient-Pressure CO2 Methanation: Influence of Bulk and Surface Properties on the Catalytic Performance

Although using supported noble-metal catalysts for CO2 hydrogenation is an effective solution due to their excellent catalytic properties, metal oxide supports themselves can exhibit good activity being more economically feasible. This work focuses on investigating the complexity of the Co3O4 system during the CO2 methanation reaction, which is usually accompanied by the formation of unstable dispersions of cobalt oxide and metallic Co. Herein, we have tested different types of Co3O4: synthetically prepared mesoporous m-Co3O4 (BET surface area, 95 m(2)/g) and commercial c-Co3O4 (BET surface area, 15 m(2)/g; purchased from Merck) in the CO2 methanation reaction under different reduction temperatures (273-673 K). The reduction temperature was adjusted to 573 K for both the catalysts to reach the optimal Co/cobalt oxide ratio and consequently the best catalytic performance. m-Co3O4 is more active (CO2 conversion 95%) and stable at higher temperatures compared to c-Co3O4 (CO2 conversion 63%) due to its morphology-induced similar to 66 times higher surface basicity. DRIFTS results showed differences in the detected surface species: formate was observed on m-Co3O4 and was proven to contribute to the total methane formation. It was revealed that in CO2 methanation reaction, both bulk and surface properties such as morphology, cobalt oxidation states, acid-base properties, and presence of defect sites directly affect the catalytic performance and reaction mechanism. Furthermore, 1% 5 nm Pt nanoparticles were loaded onto the Co(3)O(4)s to check the competitiveness of the catalysts. This study evidences on a cheap noble-metal-free catalyst for CO2 methanation consisting of m-Co3O4 with competitive activity and similar to 100% CH4 selectivity.

Automated summary

This study focuses on exploring the complexity of the Co3O4 system during the CO2 methanation reaction, revealing that m-Co3O4 exhibits higher activity and stability compared to c-Co3O4 due to its morphology-induced heightened surface basicity. The experiment demonstrates that both bulk and surface properties such as morphology, cobalt oxidation states, acid-base properties, and presence of defect sites directly impact the catalytic performance and reaction mechanism. Additionally, loading 1% 5 nm Pt nanoparticles onto Co(3)O(4)s shows potential for a competitive noble-metal-free catalyst for CO2 methanation with close to 100% CH4 selectivity.