Intrinsic structural transitions of the pyramidal I < c plus a > dislocation in magnesium

The stability of a mixed < c + a > dislocation on the pyramidal I plane in magnesium is studied using molecular dynamics simulations. The dislocation is metastable and undergoes a thermally-activated transition to either a sessile, basal-dissociated < c + a > or a sessile basal-dissociated < c > dislocation plus an < a > dislocation. The transition is intrinsic to pure magnesium and occurs with an energy barrier of similar to 0.3 eV. The transformed structure is also consistent with experimental evidence in Ti and Zr, where pyramidal I slip is more prevalent. Enhancing the ductility of magnesium by stabilizing < c + a > slip on pyramidal I planes thus appears unlikely to be viable. (C) 2016 Elsevier Ltd. All rights reserved.

Intrinsic structural transitions of the pyramidal I < c plus a > dislocation in magnesium

Strengthening mechanisms in dilute and random solid solution high-entropy BCC alloys

Atomic Scale Investigations into the Origins of Ductility in Mg Alloys

Analysis of double cross-slip of pyramidal I < c plus a > screw dislocations and implications for ductility in Mg alloys

Strengthening mechanisms in dilute and random solid solution high-entropy BCC alloys

Atomic Scale Investigations into the Origins of Ductility in Mg Alloys

Analysis of double cross-slip of pyramidal I < c plus a > screw dislocations and implications for ductility in Mg alloys