Heterogeneous lamella design to tune the mechanical behaviour of a new cost-effective compositionally complicated alloy

•A novel cost-effective compositionally complicated alloy was designed and fabricated.•Nanoprecipitates-decorated heterogeneous lamella structure was produced by thermomechanical process.•The alloy with heterogeneous lamella structure demonstrated a comparable tensile property.•The formation mechani...

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Bibliographic Details
Published in:Journal of materials science & technology 2022-01, Vol.96, p.113-125
Main Authors: Yin, Yu, Tan, Qiyang, Sun, Qiang, Ren, Wangrui, Zhang, Jingqi, Liu, Shiyang, Liu, Yingang, Bermingham, Michael, Chen, Houwen, Zhang, Ming-Xing
Format: Article
Language:English
Subjects:
Compositionally complicated alloys
Heterogeneous lamella structure
High entropy alloys
Mechanical properties
Nanoprecipitates
Recrystallization
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Summary:•A novel cost-effective compositionally complicated alloy was designed and fabricated.•Nanoprecipitates-decorated heterogeneous lamella structure was produced by thermomechanical process.•The alloy with heterogeneous lamella structure demonstrated a comparable tensile property.•The formation mechanism of the heterogeneous lamella structure and the associated strengthening mechanisms was revealed. A heterogeneous lamella (HL) design strategy was applied to manipulate mechanical properties of a new cost-effective Fe35Ni35Cr25Mo5 compositionally complicated alloy (CCA). The HL structure was produced by single-step heat treatment (800 °C for 1 h) after cold rolling. This HL structure consists of alternative lamellae regions of coarse-grained FCC matrix (5‒20 μm), and regions containing ultra-fine grains or subgrains (200‒500 nm) together with nanoprecipitates (20‒500 nm) and annealing twins. As compared with other cost-effective CCAs, the 800 °C annealed sample with HL structure demonstrated a comparable tensile property, with yield strength over 1.0 GPa and total elongation of ~13%. Formation of the annealing twins and nanoprecipitates decorated HL structure was a result of the concurrent partial recrystallization and precipitation of σ phase at the shear bands with a high density of lattice defects (e.g. high-density dislocation walls and deformation twins). The latter restricted the growth of recrystallized grains, leading to the formation of ultrafine subgrains within the HL structure. The high yield strength resulted from the multistage hetero-deformation induced (HDI) strengthening and precipitation strengthening associated with heterogeneous lamella structures containing nanoprecipitates. The ductility was originated from the coexistence of multiple deformation mechanisms, which started with dislocation slip and formation of stacking faults at the initial stage, followed by nano-twinning at the higher strain level. This HL design strategy, comprising composition and thermomechanical process designs, and the resultant microstructure tuning, open a broader window for the development of cost-effective CCAs with enhanced performance. [Display omitted]
ISSN:1005-0302
1941-1162
DOI:10.1016/j.jmst.2021.03.083