The role of dwell hold on the dislocation mechanisms of fatigue in a near alpha titanium alloy

The dislocation structures appearing in highly mis-oriented soft/hard grain pairs in near-alpha titanium alloy Ti6242Si were examined with and without the application of load holds (dwell) during fatigue. Dislocation pile-up in a soft grain resulted in internal stresses in an adjacent hard grain whi...

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Bibliographic Details
Published in:International journal of plasticity 2020-08, Vol.131, p.102743, Article 102743
Main Authors: Joseph, S., Joseph, K., Lindley, T.C., Dye, D.
Format: Article
Language:English
Subjects:
Crack initiation
Crack propagation
Creep
Cross slip
Dislocations
Edge dislocations
Electron microscopy
Fatigue
Fatigue failure
Fracture mechanics
Load shedding
Low cycle fatigue
Metal fatigue
Multiplication
Nucleation
Relaxation time
Residual stress
Stress concentration
Titanium alloy
Titanium alloys
Titanium base alloys
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Summary:The dislocation structures appearing in highly mis-oriented soft/hard grain pairs in near-alpha titanium alloy Ti6242Si were examined with and without the application of load holds (dwell) during fatigue. Dislocation pile-up in a soft grain resulted in internal stresses in an adjacent hard grain which could be relaxed by dislocation multiplication at localised Frank–Read sources, a process assisted by the provision of a relaxation time during a load hold. The rate of this process is suggested to be controlled by 〈c+a〉 pyramidal cross-slip and 〈a〉 basal junction formation. A high density of 〈a〉 prism pile-ups was observed with dual slip on two prism planes, together with edge dislocations on the third prism plane in the soft grain of a highly mis-oriented grain pair, increasing the pile-up stress. The stress concentration developed by such pile-ups is found to be higher in dwell fatigue (single-ended pile-ups) than in LCF (double ended). Analytical modelling shows that the maximum normal stress produced on the hard grain in dwell fatigue by this pile-up would be near-basal, ≈2.5° to (0002). This provides support for the dominant hypothesis for the rationalisation of dwell fatigue crack nucleation in Ti alloys, which derives from the Stroh pile-up model, and elaboration of the underlying dislocation phenomena that result from load shedding and lead to basal faceting. [Display omitted] •Dislocation mechanisms related to crack initiation in Ti alloy under fatigue were explored.•Prism pile-ups in soft grains increased stress concentration near a soft/hard grain boundary.•The pile-up stress is higher in dwell fatigue due to the single ended nature of the pile-ups.•Load shedding activated pyramidal and basal dislocation sources in hard grain under dwell.•Analytical model predicts cracking plane would be near-basal in hard grain under dwell.
ISSN:0749-6419
1879-2154
DOI:10.1016/j.ijplas.2020.102743