应用于 MIEC SOC 电极的多孔复合材料的有效传输特性

IF 3.2 Q2 CHEMISTRY, PHYSICAL
Energy advances Pub Date : 2024-07-03 DOI:10.1039/D4YA00074A
Philip Marmet, Lorenz Holzer, Thomas Hocker, Gernot K. Boiger and Joseph M. Brader
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引用次数: 0

摘要

针对具有两个固相和一个孔相(即两个导电相和一个绝缘相)的多孔复合材料的情况,提出了描述拉普拉斯方程控制的传输现象(如电荷载流子或热的传导)的半解析模型,填补了现有文献在快速准确预测这种特殊情况方面的空白。与三维几何上的数值模拟相比,这些模型的计算效率要高得多,因此可以有效地筛选出有前景的概念和材料组合。此外,如果没有微观结构的全三维几何图形,半解析模型也同样适用。通过随机建模获得的包晶石-CGO 固体氧化物电池电极微观结构数据集,对三种不同的半解析模型(麦克斯韦模型、徐模型和 MST 模型)进行了比较和验证。根据数值模型和半分析模型的结果,针对这些全陶瓷电极的应用实例,讨论了由此产生的复合传输特性的影响。CGO 和所使用的 LSTN 包晶都是混合离子和电子导体 (MIEC),与 Ni-YSZ 等相比,它们的反应机制不同,对微结构设计的要求也不同。由于这两种固相都具有 MIEC 特性,电子和氧离子的传输都不局限于单相。因此,MIEC 电极固有的复合导电性为微结构优化开辟了更大的设计空间,而传统的单相导电电极则容易发生渗滤失效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effective transport properties of porous composites applied to MIEC SOC electrodes†

Effective transport properties of porous composites applied to MIEC SOC electrodes†

Semi-analytical models describing transport phenomena governed by the Laplace equation (like conduction of charge carriers or heat) are presented for the case of a porous composite with two solid phases and one pore-phase (i.e., two conducting and one insulating phase), closing the existing gap in the literature for fast and accurate predictions for this particular case. The models allow for an efficient screening of promising concepts and material combinations, as they are computationally much more efficient compared to numerical simulations on a 3D geometry. Three different semi-analytical models (Maxwell, Xu and MST models) are compared and validated using a microstructure dataset of perovskite–CGO solid oxide cell electrodes obtained by stochastic modeling. Based on the results from both numerical and semi-analytical models, the effects of the resulting composite transport properties are discussed for the application example of these fully ceramic electrodes. CGO and the used LSTN perovskite are both mixed ionic and electronic conductors (MIECs), which leads to different reaction mechanisms and associated requirements for the microstructure design compared to, e.g., Ni–YSZ. Due to the MIEC-property of both solid phases, the transport of neither electrons nor oxygen ions is limited to a single phase. Consequently, the composite conductivity, which is inherent to MIEC electrodes, opens a much larger design space for microstructure optimization compared to the single-phase conductivity of conventional electrodes, which are prone to percolation failure.

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