Strengthening mechanisms, hardening/softening behavior, and microstructure evolution in an LPSO magnesium alloy at elevated temperatures

Rapid degradation of the mechanical properties of conventional Mg alloys with temperature precludes their wide application in industry. The LPSO (long period stacking ordered) Mg alloys, on the other hand, show considerable potential to achieve excellent high-temperature mechanical performance. In this study, a Mg-5.1Y-2.4Zn (wt.%) extrusion alloy with the microstructure comprising of & alpha;-Mg matrix and LPSO phase was prepared. It is shown that the yield strength of the alloy at 200 & DEG;C retained -83% of the yield strength of 198 MPa at room temperature (RT). Importantly, the ductility also improved, owing to the increased non-basal slip activities at elevated temperatures. In contrast to RT and 200 & DEG;C, the alloy exhibited softening tensile behavior with an apparent loss of yield strength at 300 & DEG;C. In-situ lattice strain analysis revealed that load transfer from & alpha;-Mg to LPSO remains effective at temperatures up to 200 & DEG;C, governing the high yield strength of the alloy. The postmortem analysis by means of electron microscopy confirmed that the LPSO phase is structurally stable at 200 & DEG;C. In particular, the high strain hardenability is rationalized by the sandwiched LPSO structures together with stacking faults serving as effective obstacles to the motion of non-basal dislocations. The load transfer effect disappears at the temperature of 300 & DEG;C, resulting in the fast deterioration of strength of the alloy. The cracking of the LPSO phase along with the recrystallizing of & alpha;-Mg grains were found to be the main causes for the softening behavior of the alloy at 300 & DEG;C.