Effects of crystallographic orientation and lamellar configuration on fatigue crack propagation in single-colony structures of Ti–6Al–4V alloy: Alternating shear crack growth vs. damage accumulation crack propagation

Shohei Ueki, Yoji Mine*, Yu-Lung Chiu, Paul Bowen, Kazuki Takashima

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

In this study, the fatigue crack propagation mechanisms in lamellar colonies of Ti–6Al–4V alloy were examined using miniature compact-tension specimens with a single-colony structure at the crack tip. Fatigue tests were performed on colonies with different α-phase crystallographic orientations and lamellar configurations with respect to the notch plane and direction, followed by post-fatigue metallographic analysis. Crack propagation occurs by three main mechanisms: 1) alternating shear due to in-plane prismatic slip, 2) damage accumulation via dislocation–dislocation interaction due to out-of-plane slip, and 3) interlamellar decohesion due to damage accumulation via lamellar interphase boundary–dislocation interaction. The slope of da/dN vs. ΔK is higher for alternating shear crack growth than for damage accumulation crack propagation via dislocation–dislocation interaction. This is due to an incubation period before substantive crack extension in the latter case, which is dominated by degree of strain accommodation associated with the activated slip systems. When the lamellar interphase boundaries are nearly perpendicular to the loading axis, the crack growth rates drastically increase by interlamellar decohesion. This is attributed to the reduced incubation period due to slip incompatibility at the interphase boundary where numerous crack nuclei were formed during damage accumulation process.
Original languageEnglish
Article number145885
Number of pages15
JournalMaterials Science and Engineering: A
Volume890
Early online date7 Nov 2023
DOIs
Publication statusPublished - Jan 2024

Bibliographical note

Acknowledgments:
The authors are indebted to Ms. Y. Ikebe, Ms. M. Fujiura, Dr. M. Tsushida and Dr. T. Yamamuro of Kumamoto University and Ms. X. Lu of University of Birmingham for their assistance in the micro-mechanical tests, TEM and 3D-EBSD studies. Funding: This work was supported by a Grant-in-Aid for Scientific Research (A) from the Japan Society for the Promotion of Science (JSPS) [grant number JP20H00311].

Keywords

  • Characterization
  • Electron microscopy
  • Fatigue
  • Titanium alloys
  • Grains and interfaces
  • Plasticity

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