Uniaxial Strain-Induced Grain Boundary Migration in Titanium

doi:10.1007/s40195-021-01225-1

Abstract

Abstract:

The mechanical response of a bi-crystal model with a 90° grain boundary under external compressive and tensile loading parallel to the boundary plane normal was investigated with molecular dynamics simulations. The grain boundary was found to migrate along two opposite directions upon compressive and tensile straining, with the formation of inter-connected coherent twin boundary and basal/prismatic boundary. The atomic details of such grain boundary migration were unraveled, which indicated the role of interface dislocations. The temperature effect was also discussed.

Key words: Grain boundary, Titanium, Migration, Dislocation, Twinning

Tao Sun, Aidong Tu, Hao Wang, Shu-Jun Li, Hui Peng, Jian-Ping Li. Uniaxial Strain-Induced Grain Boundary Migration in Titanium[J]. Acta Metallurgica Sinica (English Letters), 2021, 34(12): 1715-1720.

Figures/Tables 6

Fig. 1 Bi-crystal simulation model, in which the lower grain rotates 90° along the shared?<? a?>?direction with respect to the upper grain. The upper grain has a basal orientation with a horizontal c axis, while the lower grain has a prismatic orientation with a vertical c axis. Atoms are colored according to their coordination number to better visualize the grain boundary

Fig. 2 Migration of GB under uniaxial compression and tension. a1, b1 Initial interface; a2, b2 formation of a trapezoidal interface, which consists of CTB and BPB; a3, b3 GB migration with further expansion of the CTB and BPB

Fig. 3 a {10-12} CTB with a misorientation angle of 85°; b a general grain boundary consisting of both CTB and BPB. The misorientation angle of the latter is 90°

Fig. 4 Atomic process of interface migration. a-c Nucleation and glide of the interface steps on the BPB; d, e subsequent glide of twinning dislocations on the CTB

Fig. 5 Compressive a, tensile b stress-strain curves of Ti bi-crystals at different temperatures

Fig. 6 a Phase transformation from hcp to bcc under compressive loading. (b-d) Specific regions showing the orientation relationship. The dashed squares in b corresponding with subfigures c, d

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