Abstract
Alloying is an effective strategy to tailor microstructure and mechanical properties of metallic materials to overcome the strength-ductility trade-off dilemma. In this work, we combined a novel alloy design principle, i.e. harvesting pronounced solid solution hardening (SSH) based on the misfit volumes engineering, and simultaneously, architecting the ductile matrix based on the valence electron concentrations (VEC) criterion, to fulfill an excellent strength-ductility synergy for the newly emerging high/medium-entropy alloys (HEAs/MEAs). Based on this strategy, Al/Ta co-doping within NiCoCr MEA leads to an efficient synthetic approach, that is minor Al/Ta co-doping not only renders significantly enhanced strength with notable SSH effect and ultrahigh strain-hardening capability, but also sharply refines grains and induces abnormal twinning behaviors of (NiCoCr)92Al6Ta2 MEA. Compared with the partially twinned NiCoCr MEA, the yield strength (σy) and ultimate tensile strength (σUTS) of fully twinned Al/Ta-containing MEA were increased by ∼102 % to ∼600 MPa and ∼35 % to ∼1000 MPa, respectively, along with good ductility beyond 50 %. Different from the NiCoCr MEA with deformation twins (DTs)/stacking faults (SFs) dominated plasticity, the extraordinary strain-hardening capability of the solute-hardened (NiCoCr)92Al6Ta2 MEA, deactivated deformation twinning, originates from the high density of dislocation walls, micro-bands and abundance of SFs. The abnormal twinning behaviors, i.e., prevalence of annealing twins (ATs) but absence of DTs in (NiCoCr)92Al6Ta2 MEA, are explained in terms of the relaxation of grain boundaries (for ATs) and the twinning mechanism transition (for DTs), respectively.
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