Pre-compression effect on microstructure evolution of extruded pure polycrystalline magnesium during reversed tension load

Abstract

The microstructure evolution of extruded pure polycrystalline magnesium under compression followed by subsequent tension in ambient air was investigated. Solid round dog-bone shaped specimens were compressed along the extrusion direction (ED) to −7.3% and −12.8% true strains, respectively, and then tensioned along the ED to failure. Electron backscatter diffraction (EBSD) was used to examine the microstructure evolution using companion specimens unloaded at multiple points along the deformation curves. Pre-compression along the ED resulted in 101¯2 tension twinning which increased in volume with increasing strain until exhaustion at approximately −10.5% true strain. Tensile reloading of the pre-compressed specimens led to a combination of low Schmid factor twinning, detwinning, and secondary 101¯2 tension twinning. Detwinning was more significant than secondary twinning in the −7.3% pre-compressed specimens, where only one secondary twin variant was observed. 101¯2 secondary twinning was more significant in the −12.8% pre-compressed specimens, where up to three secondary twin variants were observed. After complete detwinning of primary twins, the secondary twins were retained and appeared as sub-grains. The residual sub-grains resulted from secondary twinning may provide a strengthening mechanism for wrought Mg alloys.