Materials Research Letters (Dec 2020)

Segregation-sandwiched stable interface suffocates nanoprecipitate coarsening to elevate creep resistance

  • Y. H. Gao,
  • P. F. Guan,
  • R. Su,
  • H. W. Chen,
  • C. Yang,
  • C. He,
  • L. F. Cao,
  • H. Song,
  • J. Y. Zhang,
  • X.F. Zhang,
  • G. Liu,
  • J. F. Nie,
  • J. Sun,
  • E. Ma

DOI
https://doi.org/10.1080/21663831.2020.1799447
Journal volume & issue
Vol. 8, no. 12
pp. 446 – 453

Abstract

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We demonstrate a strategy to stabilize nanoprecipitates in Al–Cu alloys, based on computational design that identifies synergistic solutes (Sc and Fe) that simultaneously segregate to the θ′-Al2Cu/Al interface and strongly bond to one another. Furthermore, Sc and Fe are predicted to each segregate into a separate atomic plane, forming a sandwiched structure reinforcing the interface. This interfacial architecture was realized through a simple heat treatment in a Sc–Fe–Si triple-microalloyed Al–Cu model alloy. Such a back-to-back layered interface, thermodynamically stable and kinetically robust, is found to suffocate nanoprecipitate coarsening at 300°C, enabling a dramatic reduction in creep rate. IMPACT STATEMENT The segregant architecture of synergistic solute at θ′-Al2Cu/Al interface was guided by computational calculations and artificially realized at atomic scale to achieve an ultra-high thermal stability of θ′-Al2Cu, leading to a high creep resistance at 300°C.

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