Fig. 1. Centimeter-sized bulk amorphous alloy ingots of different systems^[6]. (a) Pd-Cu-Ni-P; (b) Zr-Al-Ni-Cu; (c) Cu-Zr-Al-Ag; (d) Ni-Pd-P-B

Fig. 2. Amorphous alloy components formed by selective laser melting and the characterization of amorphous structure^[14]. (a) Amorphous alloy components formed by selective laser melting; (b) XRD patterns of as-spun ribbon, powders, and formed components

Fig. 3. Comparison of wear behavior and biocompatibility between Ti6Al4V alloy and 3D printed Zr-based bulk amorphous alloy^[25]. (a) Friction coefficient; (b) wear rate; (c) potentiodynamic polarization curves; (d) in vitro cell culture

Fig. 4. Macroscopic planar views and structural characteristics of welded Zr-based amorphous alloy at different scanning speeds^[30].(a)(b) 2m·min^-1; (c) 4m·min^-1; (d) 8m·min^-1; (e) XRD patterns of the corresponding regions

Fig. 5. Structural characteristics and corrosion resistance test results of the seventh layer, fourth layer, and first layer of multi-layer amorphoous alloy coating Zr₆₅Al_7.5Ni₁₀Cu17.5[53]. (a) XRD patterns; (b) potentiodynamic

Fig. 6. Theoretical temperature evolution in a Zr-based bulk amorphous alloys at different pulse durations and SEM images of ablation pits^[64]

Fig. 7. Comparison of wettability of surface processed by different laser currents^[68].(a) Unprocessed; (b) 28.5 A; (c) 29 A; (d) 30 A