Dislocation Slip and Crack Nucleation Mechanism in Dual-Phase Microstructure of Titanium Alloys: A Review

doi:10.1007/s40195-022-01505-4

Abstract

Abstract:

The study on the deformation mechanism of titanium alloys is beneficial to revealing the influence of microstructure on mechanical properties, and then providing guidance for the optimization of microstructure and properties. For most near-α and α + β titanium alloys, slip is the dominant deformation mechanism. Therefore, investigating the slip initiation and slip transfer behavior, as well as crack nucleation mechanism, is essential to reveal the fundamental relationship between microstructure and mechanical properties. However, due to the coexistence of grain boundary and phase boundary in dual-phase microstructure of titanium alloys, the phase content, grain size, grain boundary misorientation and α/β orientation relationship would affect the slip initiation and transfer behavior, resulting in a very complex plastic deformation mechanism. Based on the previous investigations of deformation mechanism of near-α and α + β titanium alloys, this review first analyzed the sequence of slip initiation between α and β phases and discussed the main factors affecting the slip initiation in α phase. Secondly, the basic rule of slip transfer and the influence of different interfaces on slip transfer were reviewed. Finally, the mechanism of crack nucleation and effect of microstructure on crack nucleation were analyzed based on slip transfer behavior.

Key words: Deformation mechanism, Slip initiation, Slip transfer, Crack nucleation

Ke Wang, Honghui Li, Yu Zhou, Jingfeng Wang, Renlong Xin, Qing Liu. Dislocation Slip and Crack Nucleation Mechanism in Dual-Phase Microstructure of Titanium Alloys: A Review[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(3): 353-365.

Figures/Tables 14

Fig. 1 Schematic diagram showing the relationship among applied stress (τapp), interaction stress (△τ) and actual stress of α and β phases [51]

Fig. 2 In situ TEM observation of the dislocation emission from a αp/β interface [54]

Fig. 3 Slip traces in TA19 titanium alloy during deformation: a slip traces appear preferentially in equiaxed α phase [32], b slip traces just present in interlayer β phase [48]

Fig. 4 SF distribution of basal and prismatic slip systems of Ti-5Al-2.5Sn alloy during early deformation [78]

Fig. 5 Effect of α grain size and morphology on the deformation mechanism in TC21 titanium alloy [45]: a the localized deformation within equiaxed α and α lath, b comparison of the frequency of slip traces within equiaxed α and α lath

Fig. 6 Slip trace analysis of the deformed micropillars with β-vertical (left) and β-inclined (right) structure [86]

Fig. 7 Geometry of slip transfer across a grain boundary [87]

Fig. 8 Schematic illustration of the direct slip transfer process [95]

Fig. 9 AFM image of slip band and slip step in Ti-6Al-4V alloy during α/β slip transfer when the α and β phases satisfy the BOR [107]

Fig. 10 Slip transfer behavior of α and β phases with BOR in TC21 titanium alloy [108]: a basal slip transmission across the α/β interface, b prismatic slip transmission with an inclined angle of 10° is observed from α to β phase

Fig. 11 Continuous slip traces in TA15 titanium alloy [109]

Fig. 12 SEM observation of crack initiation in Ti-6Al alloy [46]: a initial, b 0.2 mm, c 0.3 mm, d 0.4 mm and e KAM map after loading to the displacement of 0.4 mm

Fig. 13 The Stroh model for planar slip [116,117]

Fig. 14 Crack initiation behavior in Ti-6Al-4V alloy [124]

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