固体氧化物燃料电池的掺杂氧化铈

Shobit Omar
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引用次数: 13

摘要

在中温范围(500-700℃)的固体氧化物燃料电池中,低价阳离子掺杂的ceo2材料作为电解质的应用引起了人们极大的关注。在这些温度下,掺镓- oli的氧化锆的氧离子电导率比钇稳定的氧化锆高一个数量级。氧离子在ceo2立方萤石结构中的扩散与掺杂阳离子的电荷价、大小、掺杂量等因素有关。在文献中,一些电导率趋势已被报道为这些参数的函数,并由原子计算模型解释。本章描述了在这方面所做的各种活动的重点,以提供对受体掺杂二氧化铈中氧离子传导过程的机制的见解。仅用临界离子半径的概念不能解释由第一性原理密度泛函理论计算得出的在Pm 3+掺杂的ceo2中观察到的最大氧离子电导率。特别值得注意的是最近对稀土掺杂铈的原子模拟研究,该研究计算了稀土掺杂ceo2中可能出现的所有可能跳变构型的迁移能。本研究解释了迁移能垒形状的重要性及其对离子电导率的影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Doped Ceria for Solid Oxide Fuel Cells
Lower valent cation-doped CeO 2 materials have attracted remarkable research interest for the electrolyte application in solid oxide fuel cells operating in the intermediate temperature range (500–700°C). At these temperatures, the oxygen-ion conductivity of gad- olinium-doped ceria is about an order of magnitude higher than that of yttria-stabilized zirconia. The oxygen-ion diffusion in the cubic fluorite structure of CeO 2 is dependent on several factors such as charge valence and size of dopant cation, doping amount, etc. In the literature, several conductivity trends have been reported as a function of these parameters and are explained by the atomistic computational models. This chapter describes the highlights of the various activities that have been done in this regard to provide insights into the mechanisms underlying the oxygen-ion conduction process in acceptor-doped ceria. the concept of critical ionic radius alone cannot explain the maximum oxygen-ion conductivity observed in Pm 3+ -doped CeO 2 as found by the first-principles density functional theory calculations. Particular attention has been to a more recent atomistic simulations study on rare-earth-doped ceria which calculates the migration energies for all the possible jump configu rations that may present in rare-earth-doped CeO 2 . This study explains the importance of the shape of migration energy barrier and its impact on the ionic conductivity.
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