Assessment of alpha phase evolution in deformation of two-phase Ti-alloys under the off-equilibrium condition

M. Meng, X. G. Fan, Y. G. Chen, H. K. Guo, L. G. Guo, M. Zhan

Research output: Contribution to journalArticlepeer-review

10 Scopus citations

Abstract

In this paper, the microstructure development and flow behavior in the near isothermal forming of two-phase titanium alloys were studied through designing an off-equilibrium analog experiment. The results show that deformation decreases the volume fraction of primary alpha (αp) phase significantly at high temperature. This can be ascribed to the occurrence of dynamic transformation of αp→β by calculating the Gibbs energy barrier based on solution thermodynamics and the drive force from stress difference between αp and β phases. With the decrease of temperature, αp phase fraction varies little with deformation as a result of the counteraction between dynamic transformation of αp→β and strain-induced phase transformation of β→αp. However, the deformation under the off-equilibrium condition can accelerate the precipitation kinetics of secondary alpha (αs) phase evidently. Moreover, a large amount of fine equiaxed αs phase can be formed by intragranular nucleation. Finally, it is found that, with the deformation at high temperature, the loss of Hall–Petch strengthening is principal source of flow softening. Meanwhile, the quantity of flow softening is less than that of the loss of Hall–Petch strengthening, which is associated with pronounced precipitation of αs phase. At the low temperature, flow softening by the loss of Hall–Petch strengthening is minor compared to that by αs laths rotation.

Original languageEnglish
Pages (from-to)389-398
Number of pages10
JournalMaterials Science and Engineering: A
Volume738
DOIs
StatePublished - 19 Dec 2018

Keywords

  • Microstructure morphology
  • Off-equilibrium state
  • Phase transformation
  • Titanium alloy

Fingerprint

Dive into the research topics of 'Assessment of alpha phase evolution in deformation of two-phase Ti-alloys under the off-equilibrium condition'. Together they form a unique fingerprint.

Cite this