Fuel, Vol.85, No.3, 323-332, 2006
Catalytic steam reforming of ethane and propane over CeO2-doped Ni/Al2O3 at SOFC temperature: Improvement of resistance toward carbon formation by the redox property of doping CeO2
Ni/Al2O3 with the doping of CeO2 was found to have useful activity to reform ethane and propane with steam under Solid Oxide Fuel Cells (SOFCs) conditions, 700-900 degrees C. CeO2-doped Ni/Al2O3 with 14% ceria doping content showed the best reforming activity among those with the ceria content between 0 and 20%. The amount of carbon formation decreased with increasing Ce content. However, Ni was easily oxidized when more than 16% of ceria was doped. Compared to conventional Ni/Al2O3, 14%CeO2-doped Ni/Al2O3 provides significantly higher reforming reactivity and resistance toward carbon deposition. These enhancements are mainly due to the influence of the redox properties of doped ceria. Regarding the temperature programmed reduction experiments (TPR-1), the redox properties and the oxygen storage capacity (OSC) for the catalysts increased with increasing Cc doping content. In addition, it was also proven in the present work that the redox of these catalysts are reversible, according to the temperature programmed oxidation (TPO) and the second time temperature programmed reduction (TPR-2) results. During the reforming process, in addition to the reactions on Ni surface, the gas-solid reactions between the gaseous components presented in the system (C2H6, C3H8, C2H4, CH4, CO2, CO, H2O, and H-2) and the lattice oxygen (O-x) on ceria surface also take place. The reactions of adsorbed surface hydrocarbons with the lattice oxygen (O-x) on ceria surface (CnHm+O-x-> nCO+m/2(H-2)+Ox-n) can prevent the formation of carbon species on Ni surface froth hydrocarbons decomposition reaction (C(n)H(m)double left right arrow nC+m/2H(2)). Moreover, the formation of carbon via Boudard reaction (2CO double left right arrow CO2+C) is also reduced by the gas-solid reaction of carbon monoxide (produced from steam reforming) with the lattice oxygen (CO+O(x)double left right arrow CO2+Ox-1). (c) 2005 Elsevier Ltd. All rights reserved.