Understanding oxidation resistance of Pt-based alloys through computations of Ellingham diagrams with experimental verifications

Journal of materials informatics Pub Date : 2023-10-12 DOI:10.20517/jmi.2023.17

Xiaoyu Chong, Wei Yu, Yingxue Liang, Shun-Li Shang, Chao Li, Aimin Zhang, Yan Wei, Xingyu Gao, Yi Wang, Jing Feng, Li Chen, Haifeng Song, Zi-Kui Liu

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Abstract

Thermodynamic calculations of Ellingham diagrams and the forming oxides have been performed relevant to the Pt-based alloys Pt82Al12M6 (M = Cr, Hf, Pt, and Ta). The predicted Ellingham diagrams indicate that the elements Hf and Al are easy to oxidize, followed by Ta and Cr, while Pt is extremely difficult to oxidize. Oxidation experiments characterized by X-ray diffraction (XRD) and electron probe micro-analyzers verify the present thermodynamic predictions, showing that the best alloy with superior oxidation resistance is Pt82Al12Cr6, followed by Pt88Al12 due to the formation of the dense and continuous α-Al2O3 scale on the surface of alloys; while the worse alloy is Pt82Al12Hf6 followed by Pt82Al12Ta6 due to drastic internal oxidation and the formation of deleterious HfO2, AlTaO4, and Ta2O5. The present work, combining computations with experimental verifications, provides a fundamental understanding and knowledgebase to develop Pt-based superalloys with superior oxidation resistance that can be used in ultra-high temperatures.

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通过Ellingham图的计算和实验验证了解pt基合金的抗氧化性

对Pt基合金Pt82Al12M6 (M = Cr, Hf, Pt, Ta)的Ellingham图和形成氧化物进行了热力学计算。预测的Ellingham图表明，Hf和Al元素易氧化，其次是Ta和Cr元素，而Pt元素极难氧化。利用x射线衍射(XRD)和电子探针显微分析仪进行的氧化实验验证了上述热力学预测，结果表明:Pt82Al12Cr6是具有较好抗氧化性能的合金，其次是Pt88Al12，这是由于合金表面形成致密且连续的α-Al2O3结垢所致;由于内部氧化剧烈，形成有害的HfO2、AlTaO4和Ta2O5，合金Pt82Al12Hf6次之。本工作将计算与实验验证相结合，为开发可用于超高温的具有优异抗氧化性能的pt基高温合金提供了基本的理解和知识基础。

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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Journal of materials informatics

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