English

Machine learning predictions of superalloy microstructure

Materials Science 2021-09-29 v1

Abstract

Gaussian process regression machine learning with a physically-informed kernel is used to model the phase compositions of nickel-base superalloys. The model delivers good predictions for laboratory and commercial superalloys, with R2>0.8R^2>0.8 for all but two components of each of the γ\gamma and γ\gamma' phases, and R2=0.924R^2=0.924 (RMSE=0.063\mathrm{RMSE}=0.063) for the γ\gamma' fraction. For four benchmark SX-series alloys the methodology predicts the γ\gamma' phase composition with RMSE=0.006\mathrm{RMSE}=0.006 and the fraction with RMSE=0.020\mathrm{RMSE}=0.020, superior to the 0.0070.007 and 0.0210.021 respectively from CALPHAD. Furthermore, unlike CALPHAD Gaussian process regression quantifies the uncertainty in predictions, and can be retrained as new data becomes available.

Keywords

Cite

@article{arxiv.2109.13762,
  title  = {Machine learning predictions of superalloy microstructure},
  author = {Patrick L. Taylor and Gareth Conduit},
  journal= {arXiv preprint arXiv:2109.13762},
  year   = {2021}
}
R2 v1 2026-06-24T06:26:26.072Z