Materials & Design (Feb 2024)

Machine learning assisted design of high-entropy alloys with ultra-high microhardness and unexpected low density

  • Shunli Zhao,
  • Bin Jiang,
  • Kaikai Song,
  • Xiaoming Liu,
  • Wenyu Wang,
  • Dekun Si,
  • Jilei Zhang,
  • Xiangyan Chen,
  • Changshan Zhou,
  • Pingping Liu,
  • Dong Chen,
  • Zequn Zhang,
  • Parthiban Ramasamy,
  • Junlei Tang,
  • Wenquan Lv,
  • Konda Gokuldoss Prashanth,
  • Daniel Şopu,
  • Jürgen Eckert

Journal volume & issue
Vol. 238
p. 112634

Abstract

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High-entropy alloys (HEAs) have attracted considerable attention for their exceptional microstructures and properties. Discovering new HEAs with desirable properties is crucial, but traditional design methods are laborious and time-consuming. Fortunately, the emerging Machine Learning (ML) offers an efficient solution. In this study, composition-microhardness data pairs from various alloy systems were collected and expanded using a Generative Adversarial Network (GAN). These data pairs were converted into empirical parameter-microhardness pairs. Then Active Learning (AL) was employed to screen the Al-Co-Cr-Cu-Fe-Ni system and identify the eXtreme Gradient Boosting (XGBoost) as the optimal ML master model. Millions of data training iterations employing the XGBoost sub-model and accuracy evaluations using the Expected Improvement (EI) algorithm establish the relationship between HEA compositions and microhardness. The proposed sub-model aligns well with experimental data, wherein four Al-rich compositions exhibit ultra-high microhardness (>740 HV, with a maximum of ∼780.3 HV) and low density (<5.9 g/cm3) in the as-cast bulk state. The hardening increment originates from the precipitation of disordered BCC nanoparticles in the ordered AlCo-rich B2 matrix compared to the dilute B2 AlCo intermetallics. This lightweight, high-performance alloy shows potential for engineering applications as thin films or coatings.

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