Microstructure and compressive/tensile characteristic of large size Zr-based bulk metallic glass prepared by laser solid forming

doi:10.1016/j.jmst.2018.10.033

Abstract

Abstract:

The large size, crack-free Zr₅₅Cu₃₀Al₁₀Ni₅ bulk metallic glass (BMGs) with the diameter of 54 mm and the height of 15 mm was built by laser solid forming additive manufacturing technology, whose size is larger than the critical diameter by casting. The microstructure, tensile and compressive deformation behaviors and fracture morphology of laser solid formed Zr₅₅Cu₃₀Al₁₀Ni₅ BMGs were investigated. It is found that the crystallization mainly occurs in the heat-affected zones of deposition layers, which consist of Al₅Ni₃Zr₂, NiZr₂, ZrCu, CuZr₂ phases. The content of amorphous phase in the deposit is about 63%. Under the compressive loading, the deposit presents no plasticity before fracture occurs. The fracture process is mainly controlled by the shear stress and the compressive shear fracture angles of about 39°. The compressive strength reaches 1452 MPa, which is equivalent to that of as-Cast Zr₅₅Cu₃₀Al₁₀Ni₅ BMGs, and there exist vein-like patterns, river-like patterns and smooth regions at the compressive fractography. Under the tensile loading, the deposit presents the brittle fracture pattern without plastic deformation. The fracture process exhibits normal fracture model, and the tensile shear fracture angle of about 90°. The tensile strength is only about 609 MPa, and the tensile fractography mainly consists of micro-scaled cores and vein-like patterns, dimple-like patterns, chocolate-like patterns and smooth regions. The results further verified the feasibility and large potential of laser additive manufacturing on fabrication and industrial application of large-scale BMGs parts.

Key words: Zr-based bulk metallic glass, Laser solid forming, Additive manufacturing, Microstructure, Compressive and tensile behavior

Xin Lin, Yuanyuan Zhang, Gaolin Yang, Xuehao Gao, Qiao Hu, Jun Yu, Lei Wei, Weidong Huang. Microstructure and compressive/tensile characteristic of large size Zr-based bulk metallic glass prepared by laser solid forming[J]. J. Mater. Sci. Technol., 2019, 35(2): 328-335.

Figures/Tables 7

Fig. 1. The Zr55Cu30Al10Ni5 BMG specimen produced by laser solid forming technique.

Fig. 2. XRD patterns of the Zr55Cu30Al10Ni5 powder and LSFed BMG.

Fig. 3. Cross-sectional morphology of the LSFed Zr55Cu30Al10Ni5 deposit: (a) OM image of the BMGs, (b) SEM image of nanocrystal zone at the top of HAZ, region A in Fig. 3(a), (c) SEM-BSE image of crystalline zone at the boundary of HAZ between the adjacent tracks, region B in Fig. 3(a), (d) magnified image of region C in Fig. 3(c).

Fig. 4. TEM bright-?eld images of LSFed Zr55Al10Ni5Cu30 deposit: (a) amorphous zone, (b) amorphous + nanocrystal zone, (c) dendritic-like eutectic phase, (d) the faceted phase distributed on the eutectic phase (Insets are the corresponding diffraction patterns of selected area).

Fig. 5. Stress-strain curves of Zr55 BMGs under compression loading (a) and tensile loading (b).

Fig. 6. Fractography of the Zr55 LSFed BMGs alloy under compressive loading: (a) and (b) shear fracture behavior of the compressive specimens with a shear angle of 39, (c-f) fracture surface morphology of the compressive specimens.

Fig. 7. Fractography of the Zr55 LSFed BMGs alloy under tensile loading: (a) and (b) normal fracture behavior of the tensile specimens, (c) combination of veins and some cores, (d) dimple-like patterns, (e) dimple-like patterns, (f-g) chocolate-like patterns in the dimple-like pattern and the vein-like pattern, (h) smooth regions fracture surface morphology of the tensile specimen.

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