Isothermal short‐term oxidation behavior of MAR‐M246 nickel‐based superalloy at 800°C and 1000°C

Materials and Corrosion Pub Date : 2022-02-27 DOI:10.1002/maco.202112931

R. Baldan, L. Latu-Romain, Y. Wouters, N. Chaia, L. B. Alkmin, A. M. S. Sousa Malafaia

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引用次数: 1

Abstract

Superalloys are widely employed at high temperatures for structural applications. Hence, knowledge about the oxidation of these materials is essential. However, the literature is scanty when it comes to some families of superalloys. The purpose of this study was therefore to analyze the MAR‐M246 polycrystalline alloy in isothermal short‐term tests at 800°C and 1000°C for up to 240 h. Thermodynamic simulations were performed to evaluate the material's phase stability as a function of temperature and to assess the expected phases in response to oxygen pressure. The oxidized samples were characterized by SEM‐EDS and DRX, which revealed a tendency for scaling of oxidized material, particularly at temperatures of 1000°C. Nevertheless, protective layers of Cr2O3 and Al2O3 oxides were formed, which enabled the formation of fairly thin oxide layers, in addition to NiO and complex oxides. The region of the metallic substrate close to the oxide layer underwent aluminum depletion, causing the gamma‐prime phase to disappear, as well as formation of aluminum oxides and titanium nitrides. Last, a good correlation was found between the thermodynamic simulations and the oxides that were formed.

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MAR - M246镍基高温合金在800℃和1000℃下的等温短期氧化行为

高温合金在高温下广泛应用于结构应用。因此，关于这些材料氧化的知识是必不可少的。然而，关于某些家族的高温合金，文献很少。因此，本研究的目的是分析MAR - M246多晶合金在800°C和1000°C下长达240小时的等温短期试验。进行热力学模拟以评估材料的相稳定性作为温度的函数，并评估氧压响应的预期相。通过SEM - EDS和DRX对氧化样品进行了表征，发现氧化材料有结垢的趋势，特别是在1000℃的温度下。然而，形成了Cr2O3和Al2O3氧化物保护层，除了NiO和复合氧化物外，还形成了相当薄的氧化层。靠近氧化层的金属衬底区域发生铝耗尽，导致γ -素相消失，并形成氧化铝和氮化钛。最后，在热力学模拟和形成的氧化物之间发现了良好的相关性。

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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Materials and Corrosion

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