Abstract
This study investigates the deformation mechanisms of β-Li micropillar prepared from a Mg–7Li dual-phase alloy with or without surface oxide layer. The β-Li micropillar with three cross-sectional sizes, 2.5 × 2.5 μm2, 4.0 × 4.0 μm2 and 5.5 × 5.5 μm2, are studied. The results show that the oxide layer improves the strength of micropillar due to the dislocation trapping effect. When increasing the micropillar size, the oxide layer having nanoporous structure becomes relatively thinner, and the strengthening effect resulting from the oxide layer decreases. Regardless of the existence of the surface oxide layer, all β-Li micropillars show continuous deformation characteristics. This is ascribed to the interactions between pre-existing dislocations and non-planar dislocations activated during compression, which induces low-angle grain boundary and effectively traps the dislocations at the central area.