Application of the Peierls-Nabarro Model to Symmetric Tilt Low-Angle Grain Boundary with Full <a> Dislocation in Pure Magnesium

doi:10.1007/s40195-016-0480-4

Abstract

Abstract:

Three types of symmetric (11\(\bar{2}\)0) tilt low-angle grain boundaries (LAGBs) with array of basal, prismatic, and pyramidal edge full <a> dislocations in pure Mg have been studied by using the improved Peierls-Nabarro model in combination with the generalized stacking fault energy curve. The results show that with decreasing distance between the dislocations in all the three types of tilt LAGBs, the stress and strain fields are gradually suppressed. The reduction extent of the stress and strain fields decreases from the prismatic to basal to pyramidal dislocations. The variation of dislocation line energy (DLE) for all tilt LAGBs is divided into three stages: DLE changes slightly and linearly when the distance is larger than 300 Å, ~10%; DLE declines exponentially and quickly when the distance goes from 300 to 100 Å, ~70%; and finally, the descent speed lowers when the distance is smaller than 100 Å and the dislocation core energy is nearly half of the DLE. The grain boundary energy (GBE) decreases when the tilt angle of LAGB increases from 1° to 2° for all cases. The tilt LAGB consists of pyramidal dislocations always has the largest GBE, while that with array of prismatic dislocations has the smallest one in the whole range. The Peierls stress of dislocation in tilt LAGB is nearly unchanged, the same as that of single dislocation. This work is useful for further study of dissociated dislocation, solute segregation, precipitate nucleation in tilt LAGB and its interaction with single dislocations.

Key words: Tilt grain boundary, Generalized stacking fault energy, Magnesium alloy, Dislocation, Peierls stress

Tou-Wen Fan,Xiu-Bo Yang,Jiang-Hua Chen,Ling-Hong Liu,Ding-Wan Yuan,Yong Zhang,Cui-Lan Wu. Application of the Peierls-Nabarro Model to Symmetric Tilt Low-Angle Grain Boundary with Full <a> Dislocation in Pure Magnesium[J]. Acta Metallurgica Sinica (English Letters), 2016, 29(11): 1053-1063.

Figures/Tables 9

Fig. 1 Illustration of symmetric (11\(\bar{2}\)0) tilt low-angle grain boundary with array of (0001) basal a, (1\(\bar{1}\)00) prismatic b, (1\(\bar{1}\)01) pyramidal c full edge <a> dislocations, respectively

Fig. 2 a Supercells used to calculate the GSF energy of (0001) basal, (1\(\bar{1}\)00) prismatic, and (1\(\bar{1}\)01) pyramidal planes in pure Mg, 0 and 0.5 representing different positions along the direction perpendicular to paper. An about 10 Å thick vacuum is added. b Corresponding GSF energies and c restoring forces

Fig. 3 Stress fields of (0001) basal a, (1\(\bar{1}\)00) prismatic b, and (1\(\bar{1}\)01) pyramidal c dislocations in symmetric (11\(\bar{2}\)0) tilt low-angle grain boundaries of Mg, and the corresponding disregistry profiles d-f, respectively. The mean distance (in Å) between dislocations in LAGB and the corresponding tilt angle are included in the inlets

Fig. 4 a Dislocation line energies of basal, prismatic and pyramidal edge full <a> dislocations as a function of distance between dislocations in symmetric (11\(\bar{2}\)0) tilt LAGBs; b grain boundary energies plotted against tilt angles; c, d corresponding values estimated from conventional theory, respectively

Fig. 5 Dislocation core energies as a function of distance between the dislocations in the (11\(\bar{2}\)0) tilt LAGBs with array of prismatic, basal and pyramidal edge full <a> dislocations, respectively

Fig. 6 Peierls stresses of basal, prismatic, and pyramidal dislocations in (11\(\bar{2}\)0) tilt LAGB as a function of distance between dislocations

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