Potassium-modified calcium-ferrate-catalyzed hydrogenation of carbon dioxide to produce light olefins.

Hydrogenating CO2 to produce light olefins is a highly promising route for olefin synthesis. However, the premise of achieving a high yield is to develop a catalyst with a high conversion rate, selectivity, and stability. This paper reports a Ca2−xKxFe2O5 catalyst with an CO2 conversion of up to 46%, a light olefin selectivity of 34.59%, and an olefin-alkane molar ratio of 8.31. Ca addition increased the oxygen vacancy concentration and strong basic sites of the catalyst, resulting in improved HCOO* intermediate formation, better CO selectivity, and higher CO2 conversion rates. Meanwhile, the addition of K further enhanced the rate of CO2 conversion while also improving the selectivity of light olefins by promoting C–C coupling. Furthermore, the Ca1.0K1.0Fe2O5 catalyst demonstrated no notable deactivation over a period of 72 h, indicating the strong industrial potential of this catalyst. [ABSTRACT FROM AUTHOR]