Dual mechanisms of Ni and Si sludge-derived catalyst for catalytic methanation with high CO2 conversion and CH4 selectivity

Catalytic CO2 methanation is devoted to both carbon-emission reduction and valuable-product generation. Nibased catalyst is widely investigated for its effective CO2 conversion and high CH4 selectivity. However, seldom work reported resource substitution for production of Ni-based catalyst. In this work, Ni-Si catalysts are synthesized from Ni-rich and Si-rich electroplating sludges by a simple coprecipitation method, and applied in catalytic CO2 methanation. As a result, CO2 conversion and CH4 selectivity of sludge-derived catalyst are both increased when the catalytic temperature is increased from 250 degrees C to 450 degrees C. The best catalyst converts 58.3% of CO2 together with a high CH4 selectivity of 88.6% at 450 degrees C. After detailed characterizations, the high performance is attributed to two mechanisms. On one hand, Ni0/Ni2+ couple in NiO contributes to electron and material transfers in low-temperature CO2 methanation. On the other hand, an interface (NiSi2) is formed between NiO and Si in the sludge-derived catalyst. Ni0/Ni2+, Si0/Sin+ (n = 3 and 4), and their combination in the interface play the main role in CO2 methanation at high temperature. Therefore, this work is in favor of utilizing wastes (CO2 and sludge) to produce cost-effective products (CH4 and catalyst).

Automated summary

This study synthesized Ni-Si catalysts from Ni-rich and Si-rich electroplating sludges by a simple coprecipitation method and applied them in catalytic CO2 methanation. It was found that the CO2 conversion and CH4 selectivity of the sludge-derived catalyst increased as the catalytic temperature increased from 250°C to 450°C. The best catalyst achieved a CO2 conversion of 58.3% and a CH4 selectivity of 88.6% at 450°C. Detailed characterization revealed that the high performance was attributed to the Ni0/Ni2+ couple in NiO for low-temperature CO2 methanation and the interface (NiSi2) formed between NiO and Si in the sludge-derived catalyst for high-temperature CO2 methanation. Therefore, this work contributes to utilizing wastes (CO2 and sludge) to produce cost-effective products (CH4 and catalyst).