Acetic acid decomposition for hydrogen production was investigated on Pd/SiO2, Pd/Nb2O5, Pd/La2O3 and Pd/Fe2O3 catalysts. The conversion of acetic acid started at 673 K and the products of the reaction were H-2, CO, CH4, CO2, H2O and C2H4O. Pd/Fe2O3 was the most active catalyst for conversion of acetic acid and showed high hydrogen selectivity and good catalytic stability, followed by Pd/Nb2O5 and Pd/La2O3, whereas in the case of Pd/SiO2, there was not any H-2 formation. The Pd/Fe2O3 catalysts presented reduced Pd-Fe and Pd-0/Fe2Ox sites, producing complete conversion of acetic acid and a higher level of hydrogen selectivity (73%). Additionally, acetic acid adsorption on Pd/Fe2O3, Pd/Nb2O5 and Pd/La2O3 catalysts yielded the formation of acetate surface species. However, in the case of Pd/SiO2, there was molecular adsorption of acetic acid. During the reaction, there was formation of an ordered and disordered carbon mixture on Pd/La2O3, Pd/Nb2O5 and Pd/SiO2 catalysts, while carbon of a more ordered nature was produced on Pd/Fe2O3. (C) 2015 Elsevier Inc. All rights reserved.