Cooperative Effect of Strength and Ductility Processed by Thermomechanical Treatment for Cu-Al-Ni Alloy

Cu-Al-Ni alloys are one class of typical precipitation strengthening alloy, its mechanical properties are highly sensitive to temperature and strain. In this work, the strength-ductility cooperative effect is investigated through a thermomechanical treatment, i.e., unidirectional cold rolling, Split-Hopkinson-Pressure-Bar deformation, and aging treatment . The results show that large quantity of dislocations and twin structures are introduced during Split-Hopkinson-Pressure-Bar deformation motivated by the high strain rate (2.5*10 3 s -1 ). When the treatment temperature is slightly lower than the elongation-peak (~28.66%, which almost surpassing all existing Cu-Al-Ni alloys) aging temperature, a high strength (~797.06 MPa) is also achieved.The strength-ductility optimization process mainly includes two mechanisms, twining/grain boundaries optimization and second-phase optimization, which are closely related to dislocation movement and can contribute together without conflict. In addition, a phase-field-crystal method is used to dynamically display the interaction between twins and dislocations. Finally, the typical characteristics of this kind of high strength-ductility copper alloys are proposed, namely, small grain size, high twin density, and stable grain boundary, providing more space for the cooperative improvement of strength and ductility in Cu alloys.