High Pressure X-ray Diffraction as a Tool for Designing Doped Ceria Thin Films Electrolytes

S. Massardo, A. Cingolani, C. Artini
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引用次数: 1

Abstract

Rare earth-doped ceria thin films are currently thoroughly studied to be used in miniaturized solid oxide cells, memristive devices and gas sensors. The employment in such different application fields derives from the most remarkable property of this material, namely ionic conductivity, occurring through the mobility of oxygen ions above a certain threshold temperature. This feature is in turn limited by the association of defects, which hinders the movement of ions through the lattice. In addition to these issues, ionic conductivity in thin films is dominated by the presence of the film/substrate interface, where a strain can arise as a consequence of lattice mismatch. A tensile strain, in particular, when not released through the occurrence of dislocations, enhances ionic conduction through the reduction of activation energy. Within this complex framework, high pressure X-ray diffraction investigations performed on the bulk material are of great help in estimating the bulk modulus of the material, and hence its compressibility, namely its tolerance toward the application of a compressive/tensile stress. In this review, an overview is given about the correlation between structure and transport properties in rare earth-doped ceria films, and the role of high pressure X-ray diffraction studies in the selection of the most proper compositions for the design of thin films.
高压x射线衍射作为设计掺杂铈薄膜电解质的工具
稀土掺杂的氧化铈薄膜目前在小型化固体氧化物电池、忆阻器件和气体传感器等方面的应用得到了深入的研究。在这些不同的应用领域的就业源于这种材料最显著的特性,即离子导电性,通过氧离子在一定阈值温度以上的迁移而发生。这一特性反过来又受到缺陷的限制,缺陷阻碍了离子通过晶格的运动。除了这些问题之外,薄膜中的离子电导率主要取决于薄膜/衬底界面的存在,其中晶格不匹配会产生应变。拉伸应变,特别是当不通过位错的发生而释放时,通过降低活化能来增强离子传导。在这个复杂的框架内,对块状材料进行的高压x射线衍射研究对估计材料的块状模量有很大的帮助,因此它的可压缩性,即它对施加压缩/拉伸应力的容错性。本文综述了稀土掺杂二氧化铈薄膜的结构与输运性质之间的关系,以及高压x射线衍射研究在选择最合适的成分设计薄膜中的作用。
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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