HYDROGENATION OF CARBON DIOXIDE ON IRON-BASED CATALYSTS FOR LIQUID FUEL SYNTHESIS

Abstract

Catalytic CO2 hydrogenation to chemicals and fuels has attracted great attention since it can reduce both CO2 emission and dependence on fossil fuels. This research, the efficient catalyst for CO2 hydrogenation to higher (C2+) hydrocarbons was developed by tailoring the adsorption properties for CO2 and H2 on the catalyst surfaces. The alumina supported monometallic and bimetallic Fe-M (M = Co, Ni, Cu, Pd) catalysts were prepared and tested for CO2 hydrogenation at 573 K and 1.1 MPa. Among the monometallic catalysts, only Fe catalyst could synthesize C2+ hydrocarbons, while Co and Ni catalysts showed high CH4 selectivity. The combination of Fe and M (M/(M + Fe) = 0.10 atom atom-1) led to significant bimetallic promotion of C2+ hydrocarbons formation. H2-TPR and H2-TPD analyses suggested that the reducibility and H2 adsorption properties of the Fe-Co/Al2O3 catalyst sensitively changed with the Co/(Co + Fe) atomic ratio. A linear relationship between the amount of moderately adsorbed H2 and the space-time yield (STY) of C2+ hydrocarbons was observed, indicating an importance of this adsorbed H2 specie on the formation of C2+ hydrocarbons. This research also discovered that potassium (K) addition to Fe-Co/Al2O3 catalyst significantly enhanced C2+ hydrocarbons formation, particularly linear olefins, while it suppressed CH4 formation. H2-TPD experiments revealed that K addition suppressed the hydrogen adsorption on metal sites, leading to an increase in the olefin content.