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Influence of particle size and agglomeration in solid oxide fuel cell cathodes using manganite nanoparticles

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arxiv 1807.03816 v1 pith:JFPITFVY submitted 2018-07-10 cond-mat.mtrl-sci

Influence of particle size and agglomeration in solid oxide fuel cell cathodes using manganite nanoparticles

classification cond-mat.mtrl-sci
keywords performancesizecathodecathodesparticlefuelinfluenceoxide
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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In this work we studied the influence of particle size and agglomeration in the performance of solid oxide fuel cell cathodes made with nanoparticles of La0.8Sr0.2MnO3. We followed two synthesis routes based on the Liquid Mix method. In both procedures we introduced additional reagents in order to separated the manganite particles. We evaluated cathodic performance by Electrochemical Impedance Spectroscopy in symmetrical (CATHODE/ELECTROLYTE/CATHODE) cells. Particle size was tuned by the temperature used for cathode sintering. Our results show that deagglomeration of the particles, serves to improve the cathodes performance. However, the dependence of the performance with the size of the particles is not clear, as different trends were obtained for each synthesis route. As a common feature, the cathodes with the lowest area specific resistance are the ones sintered at the largest temperature. This result indicates that an additional factor related with the quality of the cathode/electrolyte sintering, is superimposed with the influence of particle size, however further work is needed to clarify this issue. The enhancement obtained by deagglomeration suggest that the use of this kind of methods deserved to be considered to develop high performance electrodes for solid oxide fuel cells.

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