Nanocrystalline ceria-doped scandia-stabilized zirconia (1Ce10ScSZ) powders were prepared via the co-precipitation process for solid oxide fuel cell. The effects of the calcination temperature on different properties of the as-synthesized powders, such as phase evolution, crystalline size, and specific surface area were investigated. The synthesized powders calcined at 900 °C showed a specific surface area of 5 m2 g−1 and crystalline size of 28.2 nm, and ionic conductivity of 0.07S cm1 as measured at 750 °C. An anode-supported electrolyte with a thin electrolyte layer of 6μm composed of the synthesized 1Ce10ScSZ powders was fabricated using the tape-casting and co-sintering techniques for a solid oxide fuel cell (SOFC) single cell. The open-circuit voltage of the single cell thus obtained was 1.11 V at 750 °C, indicating the dense microstructure of the electrolyte layer. A power density of 0.9W cm2 was obtained for the SOFC single cell at 1.5A cm2 and 750 °C. The SOFC single cell fabricated using the nanocrystalline 1CeScSZ electrolyte exhibited good performance because of the drastic reductions in the ohmic resistances.

Issue Section:
Research Papers
Keywords:
solid oxide fuel cell (SOFC), 1Ce10ScSZ, nanocrystalline, co-precipitation, casting, cerium, electrolytes, ionic conductivity, nanostructured materials, scandium compounds, sintering, solid oxide fuel cells, zirconium compounds
Topics:
Electrolytes, Solid oxide fuel cells, Coprecipitation, Temperature, Manufacturing

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