Additively Manufactured High-Entropy Alloys: Exceptional Mechanical Properties and Advanced Fabrication

doi:10.1007/s40195-023-01644-2

Abstract

Abstract:

High-entropy alloys (HEA) represent a novel material class, with significant potential for research on performance and preparation in additive manufacturing (AM). Currently, FCC HEA dominates the research on AM-fabricated HEA, with a shift in focus from preparation to microstructure design and mechanical properties enhancement. Research on BCC HEA is currently primarily focused on preparation and process optimization. However, it is important to note that the biomedical potential of AM-fabricated BCC HEA should not be overlooked. This review provides a concise summary of the properties and preparation techniques of exceptional HEAs in recent years. It specifically emphasizes the novel microstructure achieved through AM techniques, which significantly enhance the mechanical properties of HEAs. Additionally, the review outlines the various preparation methods employed to mitigate defect introduction during AM processes. Finally, it offers insights into the future research directions and potential applications of additively manufactured HEA.

Key words: High-entropy alloy, Additive manufacture, Microstructure, Mechanical property

Changxi Liu, Yingchen Wang, Yintao Zhang, Liqiang Wang. Additively Manufactured High-Entropy Alloys: Exceptional Mechanical Properties and Advanced Fabrication[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(1): 3-16.

Figures/Tables 10

Fig. 1 Schematics of LPBF A and LDED B

Fig. 2 AM produces dislocation cells introduced by thermal cycling [67]. A Schematic diagram of the AM thermal cycle. B The selected area electron diffraction pattern of the dislocation wall. C Morphology of the dislocation wall. D The high-resolution image of C

Fig. 3 Morphologies of A the compressed sample and B compression annealed-773, C, D compression annealed-973, E compression annealed-1173, and F compression annealed-1373 [76]

Fig. 4 As-built sample preparation and phase diagram simulation of AM-fabricated HEA with the second phase [83,84]. A Defect-free HEA as-deposited bulk with a well-dispersed γ" phase distribution. B Phase fraction change in elevated temperature range of HEAs

Fig. 5 Microstructure of AM dual-phase nanolamellar HEA [85]. A The optical micrographs of as-printed AlCoCrFeNi2.1 HEA. B Bright-field TEM image of the bcc and the FCC nanolamellae. C Secondary electron micrograph of the nanolamellar structure. D HAADF-STEM image showing the modulated nanostructures within BCC lamellae. E Tensile stress-strain curves of as-built HEA

Fig. 6 SFs morphology observed in HEA [88,89]. A-C The TEM BF images of Si-HEA show the SF at 0% tensile strain A, 17% tensile strain B and 32% tensile strain C. D The as-built HEA microstructure. E HADDF STEM image showing planar slip trace. F BF image of the dislocation slipping in the cell structure. G Dislocation slip prevented by the cell wall and nanoprecipitate. H The activation of multiple SFs during deformation

Fig. 7 Defects in as-built HEA [16,96]. A Gas porosity defects in the original powder observed by SEM. B Magnification image of A. C, D The cracks and pores in as-built HEA

Fig. 8 SEM image of RHEA with multiple remelting [99]. A RHEA deposition. B Deposited RHEA after the second remelting step resulting in a more homogeneous and smooth fabrication. C As-built RHEA obtained after four depositions and remelting steps. D, E EDX elemental maps corresponding to SEM-images A and B

Fig. 9 Substructures in the as-built RHEA [88,89]. A the effect of grain boundary with different SFE on crack suppression. B long and straight dislocations. C dislocation jogs (the yellow arrows) and dislocation loops (the red arrows)

Fig. 10 As-built biological properties of RHEA [121,125,138,139]. A SEM images of wear scars of the Ti0.5ZrNbTaMo, TiZrNbTaMo, Ti1.5ZrNbTaMo, and Ti2ZrNbTaMo. B Visual evidence of mice thigh before and after implantation (MoTa) 0.2NbTiZr alloy. C Models of TPMS lattice with different porosity based on Schoen's gyroid unit cell and the macroscopic morphologies of the SLM-built samples. D Quantitative analysis of cell density

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