寻找新一代镍基单晶高温合金中Re的替代元素以实现少Re甚至无Re化是当前高温合金领域的研究热点。从扩散系数角度出发寻找具有与Re相当或者更低扩散系数的元素是有效的研究策略之一。在多元合金中,互扩散系数矩阵可全面表征任一合金元素的扩散能力。因此,精确测定不同合金元素在镍基高温合金γ和γ′相中随成分和温度变化的互扩散系数矩阵是当务之急。首先,概述当前镍基高温合金互扩散系数矩阵测定的现状,以及用于多元合金互扩散系数测定的传统Matano-Kirkaldy方法和新型数值回归方法。由于传统Matano-Kirkaldy方法效率低,文献中鲜有镍基高温合金三元及更高组元体系互扩散系数矩阵的报道。本研究小组最近基于Fick第二定律和原子移动性概念发展起来的新型数值回归方法,可用于任意组元合金精准互扩散系数矩阵的高通量测定。随后以Ni-Al-Ta三元合金γ相为例详细阐述新型数值回归法用于合金互扩散系数矩阵高通量测定以及测定结果的可靠性验证过程。之后,简述本研究小组关于镍基高温合金γ和γ′相互扩散系数矩阵测定的最新进展。目前已经完成了核心三元合金体系Ni-Al-X( X=Rh, Ta, W, Re, Os和Ir)γ及γ'相互扩散系数矩阵的高通量测定,并对结果可靠性进行了细致的验证。通过对比不同元素在镍基高温合金中的互扩散系数,初步提出新一代镍基高温合金中Re的可能替代元素及合金成分设计的关键。最后,指出镍基高温合金互扩散系数矩阵测定的下一步工作和互扩散系数矩阵高通量测定的发展方向。
One of the research hotspots in the field of high-temperature alloys was to search the substitutional elements for Re in order to prepare the single-crystal Ni-based superalloys with less or even no Re addition. To find the elements with similar or even lower dif-fusion coefficients in comparison with that of Re was one of the effective strategies. In multicomponent alloys, the interdiffusivity matrix were used to comprehensively characterize the diffusion ability of any alloying elements. Therefore, accurate determination of the com-position-dependant and temperature-dependent interdiffusivities matrices of different elements in γ and γ′ phases of Ni-based superal-loys was high priority. The paper briefly introduces of the status of the interdiffusivity matrices determination in Ni-based superalloys, and the methods for determining the interdiffusivities in multicomponent alloys, including the traditional Matano-Kirkaldy method and recently proposed numerical inverse method. Because the traditional Matano-Kirkaldy method is of low efficiency, the experimental re-ports on interdiffusivity matrices in ternary and higher order sub-systems of the Ni-based superalloys were very scarce in the literature. While the numerical inverse method newly proposed in our research group based on Fick′s second law can be utilized for high-through-put measurement of accurate interdiffusivity matrices in alloys with any number of components. After that, the successful application of the numerical inverse method in the high-throughput measurement of interdiffusivity matrices in alloys is demonstrated in fcc (γ) phase of the ternary Ni-Al-Ta system. Moreover, the validation of the resulting composition-dependant and temperature-dependent interdiffu-sivity matrices is also comprehensively made. Then, this paper summarizes the recent progress in the measurement of interdiffusivity matrices in γ and γ′phases of a series of core ternary Ni-based superalloys achieved in our research group. Up to now, the interdiffu-sivity matrices inγandγ′phases of the core ternary systems including Ni-Al-X ( X=Rh, Ta, W, Re, Os and Ir) have been efficient-ly measured, and their reliability has also been carefully validated. Based on the experimental results, the interdiffusivities for different elements in Ni-based superalloys are carefully compared, from which the potential substitutional alloying elements for Re in Ni-based supperalloys as well as the points for alloy composition design are proposed. Finally, the research work of next step on the measurement of interdiffusivity matrices in Ni-based superalloys as well as the development trends of high-throughput measurement of interdiffusivities in our research group are pointed out.
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