Inhomogeneous α-Al/Mg2Si two-phase microstructures with chemical fluctuation produced by laser-beam powder bed fusion

Inhomogeneous α-Al/Mg2Si two-phase microstructures with chemical fluctuation produced by laser-beam powder bed fusion

This study investigated the additive manufacturing of high-strength Al–Mg–Si ternary alloy with refined α-Al/Mg2Si two-phase microstructures by laser-beam powder bed fusion (PBF-LB). Although PBF-LB processing produced crack-free samples with high relative densities (>99.5 %), the scanning laser...

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Bibliographic Details
Main Authors: Yuki Otani, Naoki Takata, Asuka Suzuki, Makoto Kobashi, Junji Umeda
Format: Article
Language:English
Published: Elsevier 2025-04-01
Series:Materials & Design
Subjects:
Al–Mg–Si alloy
Powder bed fusion
Microstructure
Laser-induced vaporization
Thermodynamic calculations
Online Access:http://www.sciencedirect.com/science/article/pii/S0264127525002072
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Summary:This study investigated the additive manufacturing of high-strength Al–Mg–Si ternary alloy with refined α-Al/Mg2Si two-phase microstructures by laser-beam powder bed fusion (PBF-LB). Although PBF-LB processing produced crack-free samples with high relative densities (>99.5 %), the scanning laser irradiation caused significant Mg vaporization, reducing the Mg content of the sample from 11.3 to 7.6 %. Laser-induced vaporization caused micron-scale chemical fluctuations in the melt-pool structure, resulting in the development of inhomogeneous microstructures. Refined cellular microstructures with many columnar α-Al phases surrounded by numerous Mg2Si nano-particles were observed in most parts of the melt-pool structure, corresponding to hypo-eutectic compositions in the Al–Mg–Si ternary system. However, primary solidified Mg2Si phases were observed in some parts of the melt-pool boundaries with local Mg-rich compositions (hyper-eutectic compositions). The PBF-LB manufactured alloy specimens with a total composition of Al–7.6Mg–5.4Si (wt%) exhibited a high tensile strength, which reduced significantly with increasing testing temperature, and low ductility (529 MPa and < 2 %, respectively) at room temperature. Moreover, the specimens underwent mechanical deterioration at elevated temperatures, owing to a significant coarsening of metastable microstructural factors (nanoscale Mg2Si precipitates or their related metastable phases and atomistic clusters) that contribute towards the high room-temperature strength.
ISSN:0264-1275

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