Catalytic performance of rare earth oxides in ketonization of acetic acid

A series of rare earth oxides were investigated as catalysts in the ketonization of acetic acid. High selectivity to acetone over 99% was obtained by reacting acetic acid over rare earth oxides such as La2O3, CeO2, Pr6O11, and Nd2O3. Especially, Pr6O11 showed the highest yield of 80% at 350 °C among the 14 rare earth oxides. The bulk structure of CeO2 was stable during the ketonization, while the surface acetate species were observed over CeO2 after ketonization. In contrast, the other active rare earth oxides such as La2O3, Pr6O11, and Nd2O3 were mainly basic oxides due to the formation of bulk oxyacetate such as MO(AcO), where M is La, Pr, and Nd and AcO indicates CH3COO group, in the initial period of the reaction. In any case, the catalytic ketonization proceeds over the surface of the oxyacetates and CeO2. Catalytic cycle of the ketonization is composed of two steps: the decomposition of surface M2O(AcO)4 to produce MO(AcO), acetone, and carbon dioxide and the regeneration of surface M2O(AcO)4 by reacting MO(AcO) and acetic acid to produce water.

A series of rare earth oxides were investigated as catalysts in the ketonization of acetic acid. High selectivity to acetone over 99% was obtained by reacting acetic acid over rare earth oxides such as La2O3, CeO2, Pr6O11, and Nd2O3. Catalytic cycle of the ketonization is composed of two steps: the decomposition of surface M2O(AcO)4 to produce MO(AcO), acetone, and carbon dioxide is followed by the regeneration of surface M2O(AcO)4 by reacting MO(AcO) and acetic acid to produce water.Figure optionsDownload high-quality image (61 K)Download as PowerPoint slideHighlights
► La2O3, CeO2, Pr6O11, and Nd2O3 are active in acetone formation from acetic acid.
► During the induction period, oxyacetate is formed in La2O3, Pr6O11, and Nd2O3.
► Bulk structure of CeO2 was stable during the ketonization.
► The catalytic ketonization proceeds over the surface of the oxyacetate and CeO2.
► Catalytic cycle is composed of two steps: decomposition and regeneration of surface acetates.