Materials Research Letters (Apr 2022)

Enhanced resistance to hydrogen embrittlement in a CrCoNi-based medium-entropy alloy via grain-boundary decoration of boron

  • X. H. Chen,
  • X. Q. Zhuang,
  • J. W. Mo,
  • J. Y. He,
  • T. Yang,
  • X. Y. Zhou,
  • W. H. Liu

DOI
https://doi.org/10.1080/21663831.2022.2033865
Journal volume & issue
Vol. 10, no. 4
pp. 278 – 286

Abstract

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We found boron doping can substantially reduce the ductility-loss in the CrCoNi medium-entropy alloy after gas-hydrogen charging, from ∼71% to ∼46%, while the fracture mode transfers from predominantly intergranular to ductile transgranular dominated. The two alloys have no difference in phase-structures (single face-center-cubic), grain sizes, and grain-boundary (GB) characters. However, atom probe tomography identified apparent GB decoration of boron up to 1.5 at.% and nanometer-scaled scattered borides in boron-doped CrCoNi. Such local chemical difference leads to enhanced GB cohesion and reduced hydrogen diffusivity along GBs, resulting in improved immunity against hydrogen-embrittlement and suppressed mechanical degradation in the boron-doped CrCoNi alloy.

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