Solid Oxide Fuel Cell Cathodes: Importance of Chemical Composition and Morphology

Catalysis for Sustainable Energy Pub Date : 2015-12-31 DOI:10.1515/cse-2015-0004

V. Sadykov, V. S. Muzykantov, N. Yeremeev, V. Pelipenko, E. Sadovskaya, A. Bobin, Yulia Fedorova, D. Amanbaeva, A. Smirnova

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引用次数: 16

Abstract

Abstract The main aspects of the cathode materials morphology for Intermediate Temperature Solid Oxide Fuel Cells (IT SOFC) are considered in this paper. The approaches for estimation of their basic properties, e.g. oxygen mobility and surface reactivity, are described and the results of different techniques (e.g. weight and conductivity relaxation, oxygen isotope exchange) application for studies of powders and dense ceramic materials are compared. The Ruddlesden-Popper type phases (e.g. Pr2NiO4) provide enhanced oxygen mobility due to cooperative mechanism of oxygen interstitial migration. For perovskites, the oxygen mobility is increased by doping, which generates oxygen vacancies or decreases metal-oxygen bond strength. Nonadditive increasing of the oxygen diffusion coefficients found that for perovskite-fluorite nanocomposites, it can be explained by the fast oxygen migration along perovskitefluorite interfaces. Functionally graded nanocomposite cathodes provide the highest power density, the lowest area specific polarization resistance, and the best stability to degradation caused by the surface layer carbonization/ hydroxylation, thus being the most promising for thin film IT SOFC design.

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固体氧化物燃料电池阴极:化学成分和形态的重要性

摘要本文对中温固体氧化物燃料电池(SOFC)正极材料形貌的主要方面进行了研究。描述了估计其基本性质的方法，例如氧迁移率和表面反应性，并比较了不同技术(例如重量和电导率弛豫，氧同位素交换)在粉末和致密陶瓷材料研究中的应用结果。Ruddlesden-Popper型相(如Pr2NiO4)由于氧间质迁移的协同机制而增强了氧迁移率。对于钙钛矿来说，掺杂会增加氧的迁移率，从而产生氧空位或降低金属-氧键的强度。氧扩散系数的非加性增加发现，对于钙钛矿-萤石纳米复合材料，氧沿钙钛矿-萤石界面的快速迁移可以解释。功能梯度纳米复合阴极具有最高的功率密度、最低的面积比极化电阻和对表层碳化/羟基化降解的最佳稳定性，因此在薄膜IT SOFC设计中最有前景。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Catalysis for Sustainable Energy

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