A novel Al-13.2Zn-2.5Mg-1.2Cu-0.2Zr alloy was prepared by melt spinning and extrusion, and then further strengthened by solution at 470 degrees C and artificial aging (AA) at 120 degrees C. A bimodal grain structure, consisting of strong < 001 > and < 111 > double fiber textures along extrusion direction, was obtained by homogenization at 450 degrees C for 30min, followed by hot extrusion at 450 degrees C. Precipitate-assisted dynamic recrystallization and the pinning effect of undissolved second-phase particles on grain coarsening play a key role in forming the bimodal grain structure together. As-extruded alloy realizes strength-ductility combination mainly due to the existences of bimodal grain structure, hard-oriented < 001 > and soft-oriented < 111 > textures and high-density precipitates. Further solution treatment promotes the dissolution of most second-phase particles, and subsequent AA induces the precipitation of higher density nano-sized eta'-phase, resulting in a notable increase in strength. However, the coarsening of undissolved second-phase particles and the thickening of precipitate free zones near grain boundary lead to a notable loss in ductility. As a result, the peak-aged alloy shows a higher strength but a lower elongation as compared to the as-extruded alloy.