Laser powder bed fusion of Cu-Ti-Zr-Ni bulk metallic glasses in the Vit101 alloy system

Laser powder bed fusion (PBF-LB/M) of bulk metallic glasses (BMGs) has experienced growing scientific and industrial interest in the last years, with a special focus on application relevant systems based on zirconium. The high cooling rates and the layer-wise build-up process allow overcoming size and geometry limitations typical for conventional casting routes. Yet, the novel production approach requires different alloy characteristics than casting processes. The present work reports for the first time on the PBF-LB/M-processing of three CuTi-based bulk metallic glass formers in the Vit101 system, allowing to exceed the mechanical performance of most additively formed Zr-based BMGs. Furthermore, the influence of alloy properties like thermal stability and toughness on the PBF-LB/M applicability are systematically studied. Thermal stability plays a minor role to produce amorphous specimen, while notch toughness is found to be a more crucial aspect to achieve parts with low defect density and resulting high mechanical performance. The results suggest fundamentally different alloy development strategies adapted to the needs of the PBF-LB/M-process, leaving classical casting-based optimi-zation of glass forming ability behind and evolving towards a rather toughness-oriented optimization.

Automated summary

Laser powder bed fusion of CuTi-based bulk metallic glasses in the Vit101 system has been successfully achieved for the first time, surpassing the mechanical performance of most Zr-based BMGs. The study reveals that thermal stability has a minor role in producing amorphous specimens, while notch toughness is crucial for achieving defect-free parts with high mechanical performance. The results suggest a shift towards toughness-oriented optimization strategies for alloy development in the PBF-LB/M-process, departing from traditional casting-based glass forming ability optimization.