25at电解性能的晶粒尺寸依赖性。%掺钇铈固体电解质

2005 4th International Symposium on Environmentally Conscious Design and Inverse Manufacturing Pub Date : 2005-12-12 DOI:10.1109/ECODIM.2005.1619373

D. Ou, T. Mori, F. Ye, J. Zou, J. Drennan

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引用次数: 0

摘要

晶粒尺寸对25at电解性能的影响。研究了%钇掺杂铈。采用碳酸盐共沉淀法合成Y0.25Ce0.75O1.875细粉制备烧结体。在950℃~ 1400℃的烧结温度范围内，电解液的平均晶粒尺寸为90 nm ~ 0.9 nm。采用直流三点测量法测定了不同晶粒尺寸样品在400℃-600℃的电导率。然后根据电导率数据计算活化能。在电导率与平均晶粒尺寸的关系图上观察到晶粒尺寸的依赖性。随着晶粒尺寸从0.9 μ m减小到0.3 μ m，电导率降低，活化能增大。这一结果与之前的报道一致，可以用空间电荷层模型来解释。晶粒尺寸从0.3 nm减小到90 nm，电导率增加。相应地，活化能减小。为了阐明这一现象的机理，利用透射电镜对样品的微观结构进行了观察。在高分辨率图像上观察到晶粒内部的纳米级畴。它们的尺寸和数量随着晶粒尺寸的减小而减小。细晶粒(<0.3 μ m)下电导率的异常增加可能部分归因于纳米结构域的变化

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Grain-Size Dependence of Electrolytic Properties in 25 at.% Yttrium Doped Ceria Solid Electrolytes

The grain size dependence of electrolytic properties in 25 at.% yttrium doped ceria was investigated. The sintered bodies were prepared from fine Y0.25Ce0.75O1.875 powders synthesized by carbonate co-precipitation method. By using sintering temperature in range of 950deg-1400degC, the average grain size of electrolytes varied from 90 nm to 0.9 mum. The conductivity of samples with different grain size was determined by dc three-point measurements at 400degC-600degC. Then the activation energy was calculated from the data of electrical conductivity. Grain-size dependence was observed on the plots of conductivity vs. average grain size. As the grain size decreased from 0.9 mum to 0.3 mum, the conductivity decreased and the activation energy increased. This result was consistent with previous reports and could be explained by the space-charge-layer model. However, the conductivity increased while the grain size decreased from 0.3 mum to 90 nm. Correspondingly, the activation energy decreased. To clarify the mechanism of this phenomenon, the microstructure of samples was observed using TEM. Nano-sized domains inside the grains were observed on the high resolution images. Their size and amount were reduced as the grain size decreased. It is possible that the abnormal increase in conductivity at fine grain size (<0.3 mum) was partly contributed by the changes in nano-sized domains

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2005 4th International Symposium on Environmentally Conscious Design and Inverse Manufacturing

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