Journal of Materials Research and Technology (Jul 2023)

Optimizing the mechanical properties of dual-phase Ti-6242s titanium alloy at 550°C using the boundary architecture

  • Yusong Li,
  • Pingwei Xu,
  • Yingfei Guo,
  • Tingyi Lin,
  • Xiang Li,
  • Longwei Hu,
  • Qinghua Song,
  • Yilong Liang,
  • Yu Liang

Journal volume & issue
Vol. 25
pp. 4497 – 4509

Abstract

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In this work, a desirable combination of mechanical properties is achieved at 550 °C by tailoring the boundary microstructure between the primary α phase (αp) and the transformed β structure (βtrans) in a dual-phase Ti-6242s titanium alloy. The αp/βtrans boundary is displaced by a transition region that consists of β nano-plates or nanoprecipitates gradually penetrating into the αp in a particular semi-equiaxed microstructure (S-ES). The results show that the αp/βtrans boundary, where strain concentration easily occurs during deformation in the equiaxed microstructure (ES), induces recrystallization softening in the α phase. However, the transition region in the S-ES alleviates the strain localization and thus effectively inhibits the recrystallization softening that occurred in the α phase with concentrated strain. These β plates/precipitates in this region in turn enable an appropriate accumulation of dislocations. Significant improvement in the high-temperature strength, ∼240 MPa for the yield strength, is obtained for the S-ES relative to the ES. This work provides a new strategy for achieving outstanding strength at high temperature by designing special boundary architecture in dual-phase titanium alloys.

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