Additively manufacturable high-strength aluminum alloys with thermally stable microstructures enabled by hybrid machine learning-based design

Additively manufactured (AM) structural components with complex geometries and tailored properties at voxel-size resolution will lead to significant leap in performance in various critical engineering applications. However, at each voxel, we first need to be able to design the alloy efficiently and...

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Hauptverfasser: Taheri-Mousavi, S. Mohadeseh, Xu, Michael, Hengsbach, Florian, Houser, Clay, Ge, Zhaoxuan, Glaser, Benjamin, Wei, Shaolou, Schaper, Mikro, LeBeau, James M, Olson, Greg B, Hart, A. John
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Sprache:eng
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Zusammenfassung:Additively manufactured (AM) structural components with complex geometries and tailored properties at voxel-size resolution will lead to significant leap in performance in various critical engineering applications. However, at each voxel, we first need to be able to design the alloy efficiently and reliably. We demonstrate a hybrid approach combining calculation of phase diagram (CALPHAD)-based integrated computational materials engineering (ICME) with machine learning and inverse design techniques and performed a full alloy design cycle of a novel Al alloy (Al-Er-Zr-Y-Yb-Ni) for AM from virtual predictions to experimental validation. We designed this alloy to exhibit high tensile strength at room temperature through nanoscale L1$_2$-phase precipitation which stabilizes the microstructure to maintain strength after high-temperature aging. We initially exploit a fine distribution of metastable eutectic ternary phases through rapid solidification, which serve as the source for the reactive elements enabling nanoscale precipitation of a high phase fraction of the thermally stable L1$_2$ strengthening phases. The strength of the 3D-printed samples manufactured via laser powder bed fusion (LPBF) from the designed composition is comparable to that of wrought Al 7075, and after high-temperature (400$^\circ$C) aging is 50% stronger than the best benchmark printable Al alloy1. The stable strengthening strategy is applicable to a wide range of alloys and rapid solidification processes, and our hybrid ML/CALPHAD numerical framework can be used for the efficient and robust design of alloy microstructures and properties, expanding the capabilities of additive as well as traditional manufacturing.
DOI:10.48550/arxiv.2406.17457