Multiscale defects enable synergetic improvement in yield strength of CrCoNi-based medium-entropy alloy fabricated via laser-powder bed fusion

Recently, laser-powder bed fusion (L-PBF) has overcome a shortcoming concerning the relatively modest yield strength in the face-centered cubic structure of CrCoNi medium-entropy alloy (MEA); nevertheless, further enhancement remains challenging because the as-built defects are limited to dislocation cell structures and nano -inclusions. In this study, several the types of hierarchical defect structures are explored (including stacking faults, nano-twins, Sigma phase, and nano-precipitates) with the addition of Si to reduce the stacking fault energy and promote segregation at dislocation cells with Cr. The CrCoNiSi0.3 alloy is fabricated by the L-PBF process, and the effects of the Si addition and L-PBF processing on the hierarchical multiscale defects and corresponding me-chanical responses are unraveled. The highest apparent density above 99.5 % is achieved under optimized conditions, exhibiting a high yield strength of 929 MPa owing to a synergetic effect from the generated defects comprising Sigma phase, nano-twins, and planar defects with moderate ductility of 14 %. In addition, the reduced stacking fault energy promotes deformation twinning, resulting in steady strain hardening. The alloy ultimately exhibits a tensile strength of 1264 MPa, with a moderate ductility of 14 %. A post-heat treatment induces a morphological change in the Sigma phase from a film-type at the cell walls to particulates at the cell junctions, leading to a significant increase in ductility without a loss of tensile strength, despite a loss of yield strength. This work provides insights to overcome the pre-existing limitations by imposing and adjusting multiscale defects.

Automated summary

In this study, hierarchical defect structures, including stacking faults, nano-twins, Sigma phase, and nano-precipitates, are explored by adding Si into CrCoNi alloy fabricated by the L-PBF process. The addition of Si reduces stacking fault energy and promotes segregation, resulting in improved mechanical properties. Under optimized conditions, the alloy exhibits a high yield strength of 929 MPa and moderate ductility of 14%. A post-heat treatment changes the morphology of the Sigma phase, leading to increased ductility without a loss of tensile strength.