Abstract:The microstructure, mechanical properties and strengthening mechanism of Mg-Li alloys processed by severe plastic deformation (equal channel angular pressing (ECAP) and rolling) and subsequent annealing were analyzed by OM, SEM, XRD and tensile testing. The results show that the initial grains of the as-cast alloy are coarse and β phase occupies the main position, while α phase distributes inside or in the boundary. Meanwhile, there are lots of precipitate phases Al₂Y and AlLi in the grain. Obvious dynamic recrystallization (DRX) does not occur during the deformation due to the significant effect of dynamic recovery (DR). After a short time annealing, the alloy is completely recrystallized with grain size refined to 27.1 μm (process of 12pra: ECAP, rolling and annealing). The tensile strength and elongation of the as-cast alloy are 131.1 MPa and 47.1%, respectively. After the process of 12pr (ECAP and rolling), the elongation of the alloy reaches 90.5%, while the tensile strength is improved slightly. This can be explained based on the effect of DR and dislocation-coordinated deformation. Subsequent annealing treatment results in an increase in tensile strength (12pra: 237.6 MPa) and a significant decrease in elongation because of the dislocation source-limited hardening and grain boundary strengthening mechanism.

Key words: Mg-Li alloy; equal channel angular pressing; rolling; annealing; microstructure; mechanical property