Pure and Zr-doped YMnO 3+δ as a YSZ-compatible SOFC cathode: a combined computational and experimental approach

A thorough study of the Y 1−x Zr x MnO 3+δ series is presented with the objective to use these materials as SOFC cathodes. These pure and Zr-doped yttrium manganites exhibit a layered hexagonal structure similar to a peculiar 5-fold bipyramidal coordination of manganese that makes them intrinsically...

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Veröffentlicht in:	Journal of materials chemistry. A, Materials for energy and sustainability Materials for energy and sustainability, 2019-08, Vol.7 (31), p.18589-18602
Hauptverfasser:	Moreno Botello, Zulma L., Montenegro, Alejandra, Grimaldos Osorio, Nicolas, Huvé, Marielle, Pirovano, Caroline, Småbråten, Didrik R., Selbach, Sverre M., Caneiro, Alberto, Roussel, Pascal, Gauthier, Gilles H.
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creator	Moreno Botello, Zulma L. Montenegro, Alejandra Grimaldos Osorio, Nicolas Huvé, Marielle Pirovano, Caroline Småbråten, Didrik R. Selbach, Sverre M. Caneiro, Alberto Roussel, Pascal Gauthier, Gilles H.
description	A thorough study of the Y 1−x Zr x MnO 3+δ series is presented with the objective to use these materials as SOFC cathodes. These pure and Zr-doped yttrium manganites exhibit a layered hexagonal structure similar to a peculiar 5-fold bipyramidal coordination of manganese that makes them intrinsically different from the traditional cube-like perovskite with [MnO 6 ] octahedra, creating the conditions conducive for oxygen uptake at a low temperature in the case of the layered manganite. Zr for Y doping enables the maintenance of oxygen excess such as interstitial oxygen atoms (O i ) located in the equatorial plane of the bi-pyramids. These over-stoichiometric interstitial oxygen sites are clearly evidenced by the maximum entropy method (MEM) applied to neutron diffraction data, and density functional theory (DFT) calculations are used to model the structural accommodation of Zr and excess oxygen. Mn reduction to Mn 2+ is found to be energetically unfavourable, as proved both experimentally and by DFT calculations. Hence, zirconium is found to both stabilize the excess oxygen compared to pure YMnO 3 and possibly provide an oxygen ion migration path with a lower energy barrier. The main consequence is a possible MIEC behaviour in Zr-doped YMnO 3 , as suggested by both the conductivity measurements and theoretical calculations. The initial EIS measurements are very promising and raise the series and its original structure to the rank of materials of interest for application as SOFC electrodes.
doi_str_mv	10.1039/C9TA04912F
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Hence, zirconium is found to both stabilize the excess oxygen compared to pure YMnO 3 and possibly provide an oxygen ion migration path with a lower energy barrier. The main consequence is a possible MIEC behaviour in Zr-doped YMnO 3 , as suggested by both the conductivity measurements and theoretical calculations. The initial EIS measurements are very promising and raise the series and its original structure to the rank of materials of interest for application as SOFC electrodes.</description><identifier>ISSN: 2050-7488</identifier><identifier>EISSN: 2050-7496</identifier><identifier>DOI: 10.1039/C9TA04912F</identifier><language>eng</language><ispartof>Journal of materials chemistry. 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A, Materials for energy and sustainability</title><description>A thorough study of the Y 1−x Zr x MnO 3+δ series is presented with the objective to use these materials as SOFC cathodes. These pure and Zr-doped yttrium manganites exhibit a layered hexagonal structure similar to a peculiar 5-fold bipyramidal coordination of manganese that makes them intrinsically different from the traditional cube-like perovskite with [MnO 6 ] octahedra, creating the conditions conducive for oxygen uptake at a low temperature in the case of the layered manganite. Zr for Y doping enables the maintenance of oxygen excess such as interstitial oxygen atoms (O i ) located in the equatorial plane of the bi-pyramids. These over-stoichiometric interstitial oxygen sites are clearly evidenced by the maximum entropy method (MEM) applied to neutron diffraction data, and density functional theory (DFT) calculations are used to model the structural accommodation of Zr and excess oxygen. Mn reduction to Mn 2+ is found to be energetically unfavourable, as proved both experimentally and by DFT calculations. Hence, zirconium is found to both stabilize the excess oxygen compared to pure YMnO 3 and possibly provide an oxygen ion migration path with a lower energy barrier. The main consequence is a possible MIEC behaviour in Zr-doped YMnO 3 , as suggested by both the conductivity measurements and theoretical calculations. 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A, Materials for energy and sustainability</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Moreno Botello, Zulma L.</au><au>Montenegro, Alejandra</au><au>Grimaldos Osorio, Nicolas</au><au>Huvé, Marielle</au><au>Pirovano, Caroline</au><au>Småbråten, Didrik R.</au><au>Selbach, Sverre M.</au><au>Caneiro, Alberto</au><au>Roussel, Pascal</au><au>Gauthier, Gilles H.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Pure and Zr-doped YMnO 3+δ as a YSZ-compatible SOFC cathode: a combined computational and experimental approach</atitle><jtitle>Journal of materials chemistry. A, Materials for energy and sustainability</jtitle><date>2019-08-06</date><risdate>2019</risdate><volume>7</volume><issue>31</issue><spage>18589</spage><epage>18602</epage><pages>18589-18602</pages><issn>2050-7488</issn><eissn>2050-7496</eissn><abstract>A thorough study of the Y 1−x Zr x MnO 3+δ series is presented with the objective to use these materials as SOFC cathodes. These pure and Zr-doped yttrium manganites exhibit a layered hexagonal structure similar to a peculiar 5-fold bipyramidal coordination of manganese that makes them intrinsically different from the traditional cube-like perovskite with [MnO 6 ] octahedra, creating the conditions conducive for oxygen uptake at a low temperature in the case of the layered manganite. Zr for Y doping enables the maintenance of oxygen excess such as interstitial oxygen atoms (O i ) located in the equatorial plane of the bi-pyramids. These over-stoichiometric interstitial oxygen sites are clearly evidenced by the maximum entropy method (MEM) applied to neutron diffraction data, and density functional theory (DFT) calculations are used to model the structural accommodation of Zr and excess oxygen. Mn reduction to Mn 2+ is found to be energetically unfavourable, as proved both experimentally and by DFT calculations. Hence, zirconium is found to both stabilize the excess oxygen compared to pure YMnO 3 and possibly provide an oxygen ion migration path with a lower energy barrier. The main consequence is a possible MIEC behaviour in Zr-doped YMnO 3 , as suggested by both the conductivity measurements and theoretical calculations. 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title	Pure and Zr-doped YMnO 3+δ as a YSZ-compatible SOFC cathode: a combined computational and experimental approach
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