Thermal treatment and properties of Ni-SDC cathode for high temperature fuel cells

Q1 Materials Science Materials Science for Energy Technologies Pub Date : 2023-01-01 DOI:10.1016/j.mset.2022.12.003

Gabriela Komorowska , Jan Jamroz , Tomasz Wejrzanowski , Kamil Dydek , Rafał Molak , Wojciech Wróbel , Shu-Yi Tsai , Kuan-Zong Fung

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Abstract

The composite Ni-SDC cathode is a key element in the formulation of the hybrid MCFC/SOFC system. It must encompass electrical and ionic conductivity, high catalytic activity to allow for the reduction of oxygen and the oxidation of carbon dioxide and provide high permeability for gaseous reactants. This requires not only a specific chemical composition but also the microstructure has to be designed and specifically manufactured.

These studies present the thermal treatment process and resultant properties of Ni-SDC cathodes with various SDC volume fractions. A new procedure for producing the Ni-SDC cathode was optimized based on the reference sintering process for pure Ni, modifying the temperature profile as well as the atmospheric gas composition (air, nitrogen, nitrogen + hydrogen mixture) and the sintering temperature (800°C, 900°C, 1000°C). This was done using thermogravimetric analysis (TGA) and electron microscopy (SEM).

The research results show that the addition of SDC, with a specific atmospheric formulation, facilitates the organic phase decomposition. It has been observed that an increase in sintering temperature enhances mechanical strength and improves electrical conductivity.

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高温燃料电池用Ni-SDC阴极的热处理及性能

复合Ni-SDC阴极是复合MCFC/SOFC体系的关键组成部分。它必须包含电导率和离子导电性，高催化活性，以允许氧气的还原和二氧化碳的氧化，并为气态反应物提供高渗透性。这不仅需要特定的化学成分，而且还需要设计和专门制造微观结构。研究了不同SDC体积分数的Ni-SDC阴极的热处理工艺和性能。在纯Ni参考烧结工艺的基础上，优化了制备Ni- sdc阴极的新工艺，改变了温度分布、大气气体组成(空气、氮气、氮+氢混合物)和烧结温度(800℃、900℃、1000℃)。这是通过热重分析(TGA)和电子显微镜(SEM)完成的。研究结果表明，在特定的大气配方下，SDC的加入有利于有机相的分解。已经观察到，提高烧结温度可以提高机械强度，改善电导率。

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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