Highly Thermally Stable Microstructure in Mg Fabricated Via Powder Rolling

J. Shen; H. Imai; B. Chen; X. Ye; J. Umeda; K. Kondoh

doi:10.1007/s11837-016-2209-2

Highly Thermally Stable Microstructure in Mg Fabricated Via Powder Rolling

J. Shen, H. Imai, B. Chen, X. Ye, J. Umeda, K. Kondoh

The University of Osaka

Research output: Contribution to journal › Article › peer-review

Abstract

The purpose of this article is to demonstrate a fascinating microstructure that ensures Mg has a high thermal stability. This is achieved by fabricating the Mg sample via powder rolling followed by powder metallurgy method. It is found that after Mg powders are pretreated for 15 rolling passes at room temperature and then consolidated by using spark plasma sintering, the Mg specimen exhibits a much finer grain structure. Such a grain structure then shows a super high thermal stability. Worthy of note is that many fractions of tensile twins were presented in the Mg specimen and survived a heat treatment at 500°C. After the heat treatment, the microhardness of the sample remained almost unchanged. The finding then gives rise to the possibility of using Mg as structural material at elevated temperatures.

Original language	English
Pages (from-to)	657-662
Number of pages	6
Journal	JOM
Volume	69
Issue number	4
DOIs	https://doi.org/10.1007/s11837-016-2209-2
State	Published - 1 Apr 2017
Externally published	Yes

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abstract = "The purpose of this article is to demonstrate a fascinating microstructure that ensures Mg has a high thermal stability. This is achieved by fabricating the Mg sample via powder rolling followed by powder metallurgy method. It is found that after Mg powders are pretreated for 15 rolling passes at room temperature and then consolidated by using spark plasma sintering, the Mg specimen exhibits a much finer grain structure. Such a grain structure then shows a super high thermal stability. Worthy of note is that many fractions of tensile twins were presented in the Mg specimen and survived a heat treatment at 500°C. After the heat treatment, the microhardness of the sample remained almost unchanged. The finding then gives rise to the possibility of using Mg as structural material at elevated temperatures.",

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AU - Chen, B.

AU - Ye, X.

AU - Umeda, J.

AU - Kondoh, K.

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AB - The purpose of this article is to demonstrate a fascinating microstructure that ensures Mg has a high thermal stability. This is achieved by fabricating the Mg sample via powder rolling followed by powder metallurgy method. It is found that after Mg powders are pretreated for 15 rolling passes at room temperature and then consolidated by using spark plasma sintering, the Mg specimen exhibits a much finer grain structure. Such a grain structure then shows a super high thermal stability. Worthy of note is that many fractions of tensile twins were presented in the Mg specimen and survived a heat treatment at 500°C. After the heat treatment, the microhardness of the sample remained almost unchanged. The finding then gives rise to the possibility of using Mg as structural material at elevated temperatures.

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Highly Thermally Stable Microstructure in Mg Fabricated Via Powder Rolling

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