Intrinsic Nano-Diffusion-Couple for Studying High Temperature Diffusion in Compositionally Complex Superalloys

Y. Eggeler, D. Kubacka, P. Pichler, Mingjian Wu, E. Spiecker
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Abstract

We present a new approach for the quantitative study of high-temperature diffusion in compositionally complex superalloys on the nano-scale. As key element, the approach utilizes the γ/γ'-microstructure itself as intrinsic nano-diffusion-couple. By establishing equilibrium at one temperature followed by annealing at a different temperature, well-defined transient states are generated which are studied using analytical transmission electron microscopy (TEM). We demonstrate this approach for a high-performance multi-component superalloy. The temporal evolution of element concentrations is consistently revealed for γ- and γ'-forming elements and is compared to multi-component diffusion simulations. Excellent agreement is obtained for Ni, Co, and Cr whereas diffusion of Al and, in particular, Re lacks behind in the experiment. Finally, it is demonstrated that transient states can also be captured by in-situ TEM using chip-based heating devices. The nano-diffusion-couple approach offers great opportunities for diffusion studies in compositionally complex superalloys and might be extended to other two-phase multicomponent systems.
研究成分复杂高温合金高温扩散的本征纳米扩散偶联
我们提出了一种在纳米尺度上定量研究成分复杂高温合金高温扩散的新方法。作为关键元素,该方法利用γ/γ′-微观结构本身作为固有的纳米扩散偶。通过在一个温度下建立平衡,然后在不同温度下退火,产生了定义良好的瞬态,并使用分析透射电子显微镜(TEM)对其进行了研究。我们将这种方法应用于高性能多组分高温合金。元素浓度的时间演化一致揭示了γ-和γ'形成元素,并与多组分扩散模拟进行了比较。Ni, Co, Cr的扩散与实验结果一致,而Al,特别是Re的扩散较差。最后,利用芯片加热装置,原位透射电镜也可以捕获瞬态。纳米扩散偶方法为复杂合金的扩散研究提供了很大的机会,并可能推广到其他两相多组分体系。
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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