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An Materials Informatics Approach To Ni-based Single Crystal Superalloys Lattice Misfit Prediction

Xue Jiang, Haiqing Yin, Cong Zhang, Rui-jie Zhang, Kai-qi Zhang, ZhengHua Deng, Guoquan Liu, Xuanhui Qu
Published 2018 · Materials Science
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Abstract The lattice misfit between γ and γ′ phase in Ni-based single crystal superalloys plays a critical role for microstructural stability and high-temperature creep and fatigue resistance. Making predictions of the lattice misfit rapidly and accurately is therefore of much practical importance, especially for costly and time-consuming material design by trial and error. In this study, we provide a machine learning approach to predict misfit using relevant material descriptors including the chemical composition, dendrite information and measurement temperature and so on. We perform support vector regression, sequential minimal optimization regression and multilayer perceptron algorithms with linear and poly kernels on experimental dataset for appropriate model selecting, and multilayer perceptron model works well for its distinguished prediction performance with high correlation coefficient and low error values. The approach is validated by comparing the predicted lattice misfit with a widely used empirical formula and experimental observation with respect to prediction accuracy.
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