Abstract: Aging precipitation can effectively enhance the strength of Mg-RE alloys, but it is usually accompanied by a significant decrease in ductility, thus the strength-ductility trade-off is a longstanding challenge. In this study, we report a new strategy that coupled pre-deformation (pre-tension along the extrusion direction (ED) followed by pre-compression along transverse direction (TD)) with artificial aging to achieve an exceptional strength-ductility synergy in the WE54 alloy at RT. We analyzed the microstructure, deformation modes and mechanical properties of four samples: T6 (artificial aging), PT-T6 (pre-tension + artificial aging), PC-T6 (pre-compression + artificial aging), and PTC-T6 (coupled pre-deformation + artificial aging). The PTC-T6 sample exhibited the superior strength-plasticity synergy, showing a strength increase of 111.9 MPa over the T6 sample and only a slight decrease in elongation to fracture. The PTC-T6 sample features finer and denser precipitates, along with a higher dislocation density, particularly a significant presence of <c+a> dislocations. This microstructural configuration enhances strength and facilitates the activation of pyramidal slip, which is the primary factor underlying its superior strength-ductility synergy.

Key words: Magnesium alloy, ＜c+a＞ dislocation, Precipitation, Strength-ductility synergy, Deformation mode