Influence of Shear Stress on Screw Dislocations in a Model Sodium Lattice

Citations Over TimeTop 1% of 1971 papers

Abstract

The behavior of the screw dislocation core in the presence of an external shear stress has been examined for the body-centered cubic and hexagonal close-packed phases of a model sodium lattice, using an effective ion–ion potential calculated from first principles. The Peierls stress for screw dislocations in the b.c.c. lattice at 0 °K is dependent on the orientation of the applied shear stress, and has a minimum value of 0.0105G, where G is the shear modulus, for slip in the twinning direction on {112} planes. The Peierls stress in the h.c.p. lattice is at least 25 times smaller. Dislocation movement in the model b.c.c. lattice takes place by unit translations on {110} planes, with the selection rule that no two consecutive translations can take place on the same slip plane.

Related Papers

• → Temperature dependency of slip and twinning in plane strain compressed magnesium single crystals(2011)736 cited
• → Basal slip and twinning in α-titanium single crystals(1975)177 cited
• → Influence of orientation on twin nucleation and growth at low strains in a magnesium alloy(2014)106 cited
• → Twinning and critical resolved shear stresses for twinning in single crystals of high-entropy alloys(2018)3 cited
• → Generation of fine extension twins in rolled magnesium alloy AZ31B at room temperature by simple shear(2022)