Revealing the Effects of χ-Fe 5 C 2 Species on CO 2 Hydrogenation to Olefins

The conversion of CO2 to olefins using iron-based catalysts has garnered significant interest due to its potential in reducing CO2 emissions. Herein, a Na-promoted ZnFe2O4 catalyst exhibits a high CO2 conversion (36.0%) and olefin selectivity (81.0%). Based on the combined results of various characterization techniques, including XPS, Mössbauer spectroscopy, XAS, and DFT calculations, the ZnFe2O4 catalyst induces a relatively electron-deficient state in the χ-Fe5C2 species compared with Zn-promoted iron oxide catalyst, thereby promoting olefin formation during CO2 hydrogenation. DFT calculations show that the ZnFe2O4 catalyst demonstrates a favorable capability for CH2 coupling to form olefins. The Na promoter enhances CO2 adsorption, thereby reducing the H/C ratio on the catalyst surface and promoting the formation of olefins. The synergistic effect between the Na promoter and the relatively electron-deficient χ-Fe5C2 species on the 0.5Na/ZnFe2O4 catalyst results in the highest observed olefin selectivity during CO2 hydrogenation.