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HomeMaterials Science ForumMaterials Science Forum Vol. 941Characterization of Precipitation Evolution in a...

Characterization of Precipitation Evolution in a Zn-Added Al-Mg-Si-Cu Alloy during Artificial Aging at 170 °C

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Abstract:

A Zn-added Al-Mg-Si-Cu alloy during aging at 170 °C up to 34 h exhibits an interesting age-hardening effect. Small clusters, enriched in Mg and Si, are present in the sample after 0.25 h aging. The β′′ phase is dominant with the peak hardness of 135 HV after aging of 8 h. A decrease in hardness of the alloy occurs with the aging time increasing to 34 h, due to the coarsening of β′′ phase. It is also found that the Cu-containing L phase co-exists with the β′′ phase at this aging condition. The quantitative solute concentrations of the matrix show that the formation of clusters is consistent with the slight lower contents of Mg, Si and Cu compared with the alloy chemical composition, and the present of β′′ and L phase is associated with the further partitioning of Mg, Si and Cu from the Al matrix into the precipitates. No Zn-rich clusters and precipitates are observed and the Zn concentration in matrix has no significant change during aging for up to 34 h. This result means that the major of Zn remains in the matrix as aging continues.

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THERMEC 2018

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Periodical:

Materials Science Forum (Volume 941)

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961-966

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https://doi.org/10.4028/www.scientific.net/MSF.941.961

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December 2018

Authors:

Shang Zhu, Zhi Hui Li*, Li Zhen Yan, Xi Wu Li, Shu Hui Huang, Hong Wei Yan, Yong An Zhang, Bai Qing Xiong

Keywords:

3DAP, Al-Mg-Si-Cu Alloy, Precipitation Evolution, TEM, Zn Addition

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© 2018 Trans Tech Publications Ltd. All Rights Reserved

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