The effect of melt thermal-rate treatment on precipitation hardening and mechanical properties of Al–Si–Mg alloys

The effect of melt thermal-rate treatment on precipitation hardening and mechanical properties of Al–Si–Mg alloys

In this study, we investigate the age-hardening behavior and mechanical properties of direct chill (DC)-cast Al–10Si-0.35 Mg alloys subjected to melt thermal rate treatment (TRT). Our findings reveal that TRT refines the microstructure and precipitation morphology. Grain analysis indicates the preva...

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Bibliographic Details
Published in:Journal of materials research and technology Vol. 33; pp. 2704 - 2717
Main Authors: Lee, Sang-Ik, Kayani, Saif Haider, Lee, Yoon-Ho, Kim, Byung-Joo, Euh, Kwangjun, Lee, Je-In, Cho, Young-Hee
Format: Journal Article
Language:English
Published: Elsevier B.V 01-11-2024
Elsevier
Subjects:
Al-10Si-0.35 Mg alloy
Precipitation hardening
Tensile strength
Thermal rate treatment
Thermal rate treatment
T5
Al-10Si-0.35 Mg alloy
Precipitation hardening
Tensile strength
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Summary:In this study, we investigate the age-hardening behavior and mechanical properties of direct chill (DC)-cast Al–10Si-0.35 Mg alloys subjected to melt thermal rate treatment (TRT). Our findings reveal that TRT refines the microstructure and precipitation morphology. Grain analysis indicates the prevalence of twin dendritic grains in both TRT and non-TRT (NTRT) alloys during casting, with the TRT billet exhibiting smaller grains. The microstructural analysis demonstrates that TRT reduces the size of secondary dendrite arm spacing and eutectic phases while ensuring a uniform distribution of intermetallic particles. The precipitation mechanism in both alloys remains consistent, with the TRT alloy exhibiting a higher density of fine precipitates. Additionally, we observe a novel coprecipitation mechanism of Si and β″ phase, attributed to a lower misfit between (003)β″ and (011)Si compared to that between (003)β″ and (0 2‾ 0)Al. Furthermore, the TRT alloy displays slower precipitation kinetics due to homogeneous solute distribution, resulting in higher activation energy for precipitation nucleation. Consequently, a single age-hardening peak is observed in TRT alloys during aging. TRT alloys exhibit higher hardness and tensile strength after artificial aging at 190 and 210 °C, while maintaining comparable elongation to NTRT alloys. Theoretical calculations of precipitation strengthening also show higher values for TRT alloys, consistent with experimental results. Thus, our findings comprehend the underlying mechanisms of melt treatments crucial for improving precipitation hardening behavior and mechanical properties of Al–Si–Mg alloys. [Display omitted]
ISSN:2238-7854
DOI:10.1016/j.jmrt.2024.09.186