Microstructure of Mg–In Alloy Systems and Their Room Temperature Rollability

IF 1.2 4区材料科学 Q4 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Transactions Pub Date : 2023-09-01 DOI:10.2320/matertrans.mt-l2023009

Ryota Nagata, Yoshiki Tomura, Takaomi Itoi

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Abstract

The Mg0.1In0.9 phase with FCC structure was formed in Mg–In and Mg–Al–In alloys. The LCR (Limiting Cold-Rolling ratio) at room temperature tended to increase with increasing area fraction of the Mg0.1In0.9 phase, and the LCR achieved 80% for the single Mg0.1In0.9 phase in both alloys. The hardness value of the Mg0.1In0.9 phase in the Mg–In binary alloys increased after rolling originated from grain-refinement by recrystallization and precipitation hardening due to processing heat generated by rolling at room temperature. On the other hand, the Mg0.1In0.9 phase formed in the Mg–Al–In ternary alloys was stable at room temperature and work hardened after rolling. Since the Mg0.1In0.9 phase dissolves about 5 mol% of Al, substituting Al for In in the Mg–In alloy was effective in reducing density. The density of the Mg80Al7In13 (mol%) alloy is 2.60 Mg/m3, which is lower than that of Al, and the LCR showed 49%. In Mg–In alloys, the substitution of Al is effective in developing alloys that are easy to process at room temperature and have low density, because the Mg0.1In0.9 phase has a solid solution of Al and contributes to phase stabilization at room temperature.

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Mg-In合金体系的显微组织及其室温轧制性能

在Mg-In和Mg-Al-In合金中形成具有FCC结构的Mg0.1In0.9相。随着Mg0.1In0.9相面积分数的增加，两种合金的室温极限冷轧比均有增大的趋势，其中Mg0.1In0.9相的极限冷轧比均达到80%。Mg-In二元合金中Mg0.1In0.9相的硬度值在轧制后升高，这是由于室温轧制时产生的加工热通过再结晶和析出硬化使晶粒细化所致。另一方面，Mg-Al-In三元合金中形成的Mg0.1In0.9相在室温下稳定，轧制后加工硬化。由于Mg0.1In0.9相溶出约5mol %的Al，在Mg-In合金中以Al代替In可有效降低密度。Mg80Al7In13合金的密度(mol%)为2.60 Mg/m3，低于Al合金，LCR为49%。在Mg-In合金中，由于Mg0.1In0.9相具有Al的固溶体，有助于室温下的相稳定，因此Al的替代在室温下易于加工且密度低的合金中是有效的。

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