Elucidating the Role of Surface Cesup.4+ and Oxygen Vacancies of CeOsub.2 in the Direct Synthesis of Dimethyl Carbonate from COsub.2 and Methanol

Cerium dioxide (CeO[sub.2]) was pretreated with reduction and reoxidation under different conditions in order to elucidate the role of surface Ce[sup.4+] and oxygen vacancies in the catalytic activity for direct synthesis of dimethyl carbonate (DMC) from CO[sub.2] and methanol. The corresponding catalysts were comprehensively characterized using N[sub.2] physisorption, XRD, TEM, XPS, TPD, and CO[sub.2]-FTIR. The results indicated that reduction treatment promotes the conversion of Ce[sup.4+] to Ce[sup.3+] and improves the concentration of surface oxygen vacancies, while reoxidation treatment facilitates the conversion of Ce[sup.3+] to Ce[sup.4+] and decreases the concentration of surface oxygen vacancies. The catalytic activity was linear with the number of moderate acidic/basic sites. The surface Ce[sup.4+] rather than oxygen vacancies, as Lewis acid sites, promoted the adsorption of CO[sub.2] and the formation of active bidentate carbonates. The number of moderate basic sites and the catalytic activity were positively correlated with the surface concentration of Ce[sup.4+] but negatively correlated with the surface concentration of oxygen vacancies. The surface Ce[sup.4+] and lattice oxygen were active Lewis acid and base sites respectively for CeO[sub.2] catalyst, while surface oxygen vacancy and lattice oxygen were active Lewis acid and base sites, respectively, for metal-doped CeO[sub.2] catalysts. This may result from the different natures of oxygen vacancies in CeO[sub.2] and metal-doped CeO[sub.2] catalysts.