Flash Spark Plasma Sintering of 3YSZ: Modified Sintering Pathway and Impact on Grain Boundary Formation

T. Hérisson de Beauvoir, Zakaria Ghomari, G. Chevallier, Andréas Flaureau, A. Weibel, C. Elissalde, F. Mauvy, R. Chaim, C. Estournès
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引用次数: 7

Abstract

We demonstrate the possibility to prepare porous 3 mol.% yttria stabilized zirconia ceramics thanks to a recently developed method called Flash-SPS, allowing extremely fast densification in just a few seconds. This method allows to reach heating rates up to 200 °C/s, which has a strong impact on sintering mechanisms, both in terms of densification and grain growth. We demonstrate the possible preparation of specimens with 5 to 15% porosity, limited grain growth (< 350 nm) and mechanical properties similar to fully dense ceramic. Through the use of sintering trajectories, but also based on microscopy, mechanical and electrical analyses, we highlight a new sintering mechanism. It appears that densification is largely advanced at grain boundary interfaces, while inter-grain porosity remains present. This phenomenon is particularly supported by the mechanical hardness and impedance spectroscopy measurements, the latter showing a very low impedance contribution from the grain boundaries despite the low density. This opens up opportunities for the fabrication of porous lightweight materials with high mechanical properties, but also presents interests in alternative sintering pathways for refractory ceramics.
3YSZ的闪光放电等离子烧结:改进的烧结途径及其对晶界形成的影响
由于最近开发的一种称为Flash-SPS的方法,我们证明了制备多孔3mol .%钇稳定的氧化锆陶瓷的可能性,该方法可以在几秒钟内实现极快的致密化。这种方法可以达到高达200°C/s的加热速率,这对烧结机制有很大的影响,无论是在致密化还是晶粒生长方面。我们演示了可能制备的孔隙率为5%至15%、晶粒生长受限(< 350 nm)、机械性能与全致密陶瓷相似的样品。通过使用烧结轨迹,也基于显微镜,力学和电学分析,我们强调了一种新的烧结机制。致密化主要发生在晶界界面处,而晶粒间孔隙仍然存在。这一现象得到了机械硬度和阻抗谱测量的特别支持,后者显示出尽管密度低,但晶界的阻抗贡献非常低。这为制造具有高机械性能的多孔轻质材料开辟了机会,但也为耐火陶瓷的替代烧结途径提供了兴趣。
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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