Nature Communications (Nov 2023)

Quantitative three-dimensional imaging of chemical short-range order via machine learning enhanced atom probe tomography

  • Yue Li,
  • Ye Wei,
  • Zhangwei Wang,
  • Xiaochun Liu,
  • Timoteo Colnaghi,
  • Liuliu Han,
  • Ziyuan Rao,
  • Xuyang Zhou,
  • Liam Huber,
  • Raynol Dsouza,
  • Yilun Gong,
  • Jörg Neugebauer,
  • Andreas Marek,
  • Markus Rampp,
  • Stefan Bauer,
  • Hongxiang Li,
  • Ian Baker,
  • Leigh T. Stephenson,
  • Baptiste Gault

DOI
https://doi.org/10.1038/s41467-023-43314-y
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 11

Abstract

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Abstract Chemical short-range order (CSRO) refers to atoms of specific elements self-organising within a disordered crystalline matrix to form particular atomic neighbourhoods. CSRO is typically characterized indirectly, using volume-averaged or through projection microscopy techniques that fail to capture the three-dimensional atomistic architectures. Here, we present a machine-learning enhanced approach to break the inherent resolution limits of atom probe tomography enabling three-dimensional imaging of multiple CSROs. We showcase our approach by addressing a long-standing question encountered in body-centred-cubic Fe-Al alloys that see anomalous property changes upon heat treatment. We use it to evidence non-statistical B2-CSRO instead of the generally-expected D03-CSRO. We introduce quantitative correlations among annealing temperature, CSRO, and nano-hardness and electrical resistivity. Our approach is further validated on modified D03-CSRO detected in Fe-Ga. The proposed strategy can be generally employed to investigate short/medium/long-range ordering phenomena in different materials and help design future high-performance materials.