Sohrabi, NavidJhabvala, JamaspKurtuldu, GüvenStoica, MihaiParrilli, AnnapaolaBerns, SiddarthaPolatidis, EfthymiosVan Petegem, StevenHugon, SylvainNeels, AntoniaLöffler, Jörg F.Logé, Roland2020-12-222020-12-222020-12-222020-12-1010.1016/j.matdes.2020.109400https://infoscience.epfl.ch/handle/20.500.14299/174240Bulk metallic glasses (BMGs) are high-strength, highly elastic materials due to their disordered atomic structure. Because BMGs require sufficiently high cooling rates to bypass crystallization, laser-based additive manufacturing (AM) methods have recently been employed for the fabrication of BMGs. In this study, we present an optimized Laser Powder-Bed Fusion (LPBF) process on a Zr-based BMG (Zr59.3Cu28.8Al10.4Nb1.5, in at.%), with a focus on characterization, mechanical properties, and dimensional accuracy. A volumetric density of 99.82% was achieved. Although the sample was qualified as amorphous via laboratory X-ray diffraction experiments, a more meticulous study using synchrotron radiation revealed nanocrystals in the heat-affected zones (HAZs) of the melt pool. Fast differential scanning calorimetry (FDSC) and numerical simulations were then employed to illustrate the mechanism of crystallization. The LPBF-processed alloy revealed excellent mechanical properties, such as high hardness, wear resistance, compressive strength, and flexural strength. Apart from vein-like patterns, the fracture surfaces of the compression test samples showed liquid-like features, which indicate a significant local temperature increase during fracture. The dimensional accuracy was assessed with a benchmark exhibiting complex geometrical features and reached at least 40 μm. The results indicate that LPBF processing is a promising route for the manufacturing of BMGs for various applications.Additive manufacturingBulk metallic glassLaser powder-bed fusionNano-crystallizationPrecision manufacturingSelective laser meltingtext::journal::journal article::research article