Li, M., Bai, K., Lee, J. J., Ng, S. R., Wuu, D., Du, J., Lau, K. B., Lv, L., Suo, H., Wang, P., & Ng, C. K. (2025). Engineering melt pool boundaries for strength ductility Enhancement in additive manufactured CoCrFeNiWx high entropy alloys. Materials Design, 258, 114593. https://doi.org/10.1016/j.matdes.2025.114593
Abstract:
Melt pool boundaries (MPBs) in additively manufactured (AM) alloys are often weakened by the presence of brittle phases, residual stresses, and coarsened microstructures, severely limiting tensile ductility. In this study, we propose MPB engineering as an effective strategy to mitigate these limitations by introducing nano twins at MPBs. This approach leverages enhanced W solubility in the metastable FCC matrix and localized thermal stresses during rapid solidification. CoCrFeNiWx alloys were selected and fabricated via Laser Powder Bed Fusion (LPBF) using in-situ alloying with W powder. CALPHAD simulations reveal that the stacking fault energy (SFE) of the FCC phase in W0.6 is approximately 7mJ/m2, favourable for twin formation. High-resolution microscopy confirms the presence of nano twins (∼5 nm thick) at MPBs in W0.6, attributed to the combined effects of low SFE and stress localization. These twins significantly enhance strain hardening and uniform tensile deformation, resulting in a yield strength of ∼ 906 MPa and elongation of 7 %. These properties are comparable to those of W0.3Cr0.7CoNi, one of the strongest FCC-based alloys strengthened by brittle topologically closed packed (TCP) phases but achieved without complex thermomechanical treatments. This work highlights MPB engineering as a promising route for tailoring mechanical properties in high entropy alloys through microstructural control during additive manufacturing.
License type:
Attribution-NonCommercial 4.0 International (CC BY-NC 4.0)
Funding Info:
This research / project is supported by the National Research Foundation - AI Singapore Materials Grand Challenge
Grant Reference no. : AISG2-GC-2023-010
This research / project is supported by the A*STAR - Manufacturing, Trade and Connectivity (MTC) Industry Alignment Fund Pre-Positioning (IAF-PP)
Grant Reference no. : M22K7a0047 and M22K5a0045