Synergistic promotions between CO2 capture and in-situ conversion on Ni-CaO composite catalyst

The integrated CO2 capture and conversion (iCCC) technology has been booming as a promising cost-effective approach for Carbon Neutrality. However, the lack of the long-sought molecular consensus about the synergistic effect between the adsorption and in-situ catalytic reaction hinders its development. Herein, we illustrate the synergistic promotions between CO2 capture and in-situ conversion through constructing the consecutive high-temperature Calcium-looping and dry reforming of methane processes. With systematic experimental measurements and density functional theory calculations, we reveal that the pathways of the reduction of carbonate and the dehydrogenation of CH4 can be interactively facilitated by the participation of the intermediates produced in each process on the supported Ni-CaO composite catalyst. Specifically, the adsorptive/catalytic interface, which is controlled by balancing the loading density and size of Ni nanoparticles on porous CaO, plays an essential role in the ultra-high CO2 and CH4 conversions of 96.5% and 96.0% at 650 degrees C, respectively.

Automated summary

The integrated CO2 capture and conversion (iCCC) technology is a promising cost-effective approach for Carbon Neutrality. The lack of molecular consensus about the synergistic effect between adsorption and in-situ catalytic reaction hampers its development. In this study, the synergies between CO2 capture and in-situ conversion are illustrated through high-temperature Calcium-looping and dry reforming of methane processes.