Photothermal CO2 hydrogenation to hydrocarbons over trimetallic Co-Cu-Mn catalysts

Photocatalytic CO2 reduction is a highly vital process for converting CO2 into valuable chemicals. However, the reaction always proceeds less efficaciously at low temperature. A combination of optical and thermal conditions is one of the feasible approaches to achieve the reaction with high efficiency and has gained much attention recently. In the present work, we prepared several Co-Cu-Mn trimetallic catalysts via a simple co-precipitation method, which were used in catalyzing photothermal CO2 reduction to hydrocarbons. The metal composition and reduction temperature of the catalysts had important effects on their structural and photoelectrical characteristics and adsorption behaviors, further resulting in diverse catalytic performances. Among the prepared trimetallic catalysts, Co7Cu1Mn1Ox(200), with a Co/Cu/Mn molar ratio of 7/1/1 and reduced at 200 degrees C in H-2 for 2 h, could produce CH4 with an activity of 14.5 mmol g(cat)(-1) h(-1) in 10% CO2/30% H-2/60% N-2, and CH4 and C2+ hydrocarbons with the activities of 15.9 and 7.5 mmol g(cat)(-1) h(-1) in 25% CO2/75% H-2, respectively. The present strategy for constructing trimetallic oxide catalysts for the photothermal reaction not only provides a highly active catalyst for CO2 utilization, but also offers a potential possibility for reducing the high temperature of conventional thermal reactions.

Automated summary

The study focuses on the preparation of Co-Cu-Mn trimetallic catalysts for catalyzing photothermal CO2 reduction, highlighting the significant influence of the metal composition and reduction temperature on the catalysts' performance. Among the tested catalysts, Co7Cu1Mn1Ox(200) showed high activity for producing methane under specific conditions.