Accelerated design of L12-strengthened Co-base superalloys based on machine learning of experimental data

Co-base superalloys strengthened by gamma' precipitates have been regarded as a candidate for aircraft engines. However, its gamma' precipitates are not stable. Moreover, improving its properties experimentally could spend a lot of time. DFT and thermodynamic calculation also have disadvantages, which could not accelerate the designing process of Co-base superalloys significantly. Thus, a new strategy is needed to predict the properties of the superalloys rapidly and accurately. In this study, an accelerated design strategy is applied to find the Co-base superalloys with good properties. Four important properties, which are the existence of gamma' and other phases, the gamma' solvus temperature and area fraction are predicted based on machine learning-based models. Samples used in this study are experimental data collected from related references and our previous study. Afterwards, four predicting models are integrated to design the superalloys that meet the designing requirements of four properties simultaneously. Finally, six groups are chosen from 363,000 possible candidates and all of six are experimental validated. New Co-base superalloys with high gamma' solvus temperature and high gamma' area fraction are designed successfully. Our strategy is suitable for the rapid multi-properties design of other advanced materials. (C) 2020 Published by Elsevier Ltd.