English

Accelerated design of Fe-based soft magnetic materials using machine learning and stochastic optimization

Materials Science 2020-06-11 v2 Data Analysis, Statistics and Probability

Abstract

Machine learning was utilized to efficiently boost the development of soft magnetic materials. The design process includes building a database composed of published experimental results, applying machine learning methods on the database, identifying the trends of magnetic properties in soft magnetic materials, and accelerating the design of next-generation soft magnetic nanocrystalline materials through the use of numerical optimization. Machine learning regression models were trained to predict magnetic saturation (BSB_S), coercivity (HCH_C) and magnetostriction (λ\lambda), with a stochastic optimization framework being used to further optimize the corresponding magnetic properties. To verify the feasibility of the machine learning model, several optimized soft magnetic materials -- specified in terms of compositions and thermomechanical treatments -- have been predicted and then prepared and tested, showing good agreement between predictions and experiments, proving the reliability of the designed model. Two rounds of optimization-testing iterations were conducted to search for better properties.

Keywords

Cite

@article{arxiv.2002.05225,
  title  = {Accelerated design of Fe-based soft magnetic materials using machine learning and stochastic optimization},
  author = {Yuhao Wang and Yefan Tian and Tanner Kirk and Omar Laris and Joseph H. Ross, and Ronald D. Noebe and Vladimir Keylin and Raymundo Arróyave},
  journal= {arXiv preprint arXiv:2002.05225},
  year   = {2020}
}
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