Characterization and Stack Testing of Solid Oxide Fuel Cells with Cathodes Prepared by Infiltration

Recently, the use of infiltration as a method for SOFC electrode preparation has gathered significant scientific interest (1-6). The results thus far have been mostly obtained on button cells with electrode active areas on the order of 1 cm 2 or less. Here, we report the physical characterization and stack testing of 12 x 12 cm 2 planar cells with cathodes prepared by infiltration of a perovskite precursor solution into a stabilized zirconia backbone. As the first step in the development of the new cell design, a stabilized zirconia backbone layer with high surface area and good mechanical compatibility with the rest of the cell was developed. After an optimized sintering procedure was introduced, batches of about 90 cells could reproducibly be manufactured with high yields. The optimized blank cells were infiltrated with a precursor solution of (La 0.8 Sr 0.2 ) 0.95 FeO 3 and the resulting cells were characterized thoroughly using XRD, van der Pauw in-plane conductivity, BET specific surface area, and electrochemical single-cell measurements. As the in-plane conductivity, the BET surface area as well as the pore-size distribution of the cathode are thought to play a key role in determining the long-term performance and stability of infiltrated cells in a stack, changes in these properties were mapped out as a function of the cathode sintering temperature. Electrochemical testing on both cell and stack level confirmed the enhanced performance of cells with cathodes prepared by infiltration. Results on degradation testing will be reported separately. This work was partly funded by EUDP project J 64012-0225, “SOFC Accelerated”. References S.P. Jiang, Mater. Sci. Eng. A , 418 , 199 (2006). J.M. Vohs, R.J. Gorte, Adv. Mater ., 21 , 943 (2009). A.J. Samson, P. Hjalmarsson, M. Søgaard, J. Hjelm, N. Bonanos, J. Power Sources , 216 , 124 (2012). D. Ding, X. Li, S.Y. Lai, K. Gerdes, M. Liu, Energy Environ. Sci. , 7 , 552 (2014). T.Z. Sholklapper, H. Kurokawa, C.P. Jacobson, S.J. Visco, L.C. De Jonghe, Nano Lett . 7 , 2136 (2007). M. Shah, S.A. Barnett, Solid State Ionics , 179 , 2059 (2008). Figure 1