Journal
RARE METALS
Volume 42, Issue 2, Pages 651-663Publisher
NONFERROUS METALS SOC CHINA
DOI: 10.1007/s12598-022-02122-x
Keywords
Ti6Al4V; Induction nitriding; Gradient layer; High-density dislocation; Strengthening mechanism
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The vacuum electromagnetic induction nitriding technology was used to prepare a gradient nitrided layer on the surface of a Ti6Al4V alloy. The study found that there were numerous high-density stacking faults and basal stacking faults on the alloy surface, causing lattice distortion. Additionally, the hardness and compressive stress of the nitrided layer also changed.
The vacuum electromagnetic induction nitriding technology was applied to prepare a gradient nitrided layer on the surface of a Ti6Al4V alloy, which possesses TiN and alpha-Ti (N) phases. Moreover, transmission electron microscopy was conducted to confirm the presence of numerous high-density stacking faults caused by TiN and Ti2N phases distributed on the surface of the alloy, along with a large number of basal stacking faults inside. A high-density stacking fault led to serious distortion of lattice fringes. Lattice and numerous edge dislocations caused by defects were observed in the subsurface layer. For the surface layer, the Vickers hardness reached HV0.25 1211.30 and the residual compressive stress increased, while the nano-hardness increased to 14.07 from 5.31 GPa in the substrate. The micrometre scratch test results indicated that the plasticity and hardness of the nitrided layer changed in a gradient. The 50-mu m effective hardened layer depth and surface compressive stress of the Ti6Al4V alloy were enhanced by the stacking faults.
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