Effects of yttrium addition on microstructural stability and elevated-temperature mechanical properties of a cast Mg–Zn alloy

The effects of adding 2 wt% Yttrium (Y) element on the thermal stability, microstructural evolution, and mechanical properties of an Mg–4Zn alloy were examined. The as-cast microstructure of Mg–4Zn included α-Mg matrix and Mg7Zn3 intermetallic phase. Because of the low-thermal stability that is typi...

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Bibliographic Details
Published inJournal of alloys and compounds Vol. 820; p. 153083
Main Authors Mehrabi-Mehdiabadi, M., Mahmudi, R.
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 15.04.2020
Elsevier BV
Subjects
Annealing
Grain growth
High temperature
Intermetallic phases
Magnesium base alloys
Mechanical properties
Mg–Zn alloy
Microstructural stability
Microstructure
Shear strength
Thermal stability
Y addition
Yttrium
Zinc
Mechanical properties
Y addition
Mg–Zn alloy
Microstructural stability
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Summary:The effects of adding 2 wt% Yttrium (Y) element on the thermal stability, microstructural evolution, and mechanical properties of an Mg–4Zn alloy were examined. The as-cast microstructure of Mg–4Zn included α-Mg matrix and Mg7Zn3 intermetallic phase. Because of the low-thermal stability that is typical of this phase, there was a significant decrease in the strength of the Mg–4Zn alloy with an increase in the temperature. Addition of Y led to simultaneous refinement of the microstructure and improvement in both shear strength and microstructural stability of Mg–4Zn at high temperature. This was manifested by the retention of the initial fine microstructure and strength of the Y-containing material after a prolonged annealing at 370 °C. The decrease in the volume fraction of the unstable Mg7Zn3, and formation of the thermally stable Mg3Zn3Y2 intermetallic particles hindered the grain growth during annealing treatment, resulting in improved stability and strength at both ambient and elevated temperatures. Such behavior was in contrast to what was observed in the base material, showing substantial strength drop due to the excessive grain growth as a result of dissolved Mg7Zn3 particles at high temperature. •Microstructure of the Mg–4Zn alloy was significantly refined by addition of 2 wt% Y.•Addition of Y to Mg–4Zn alloy formed thermally stable skeleton type Mg3Zn3Y2 phase.•Mg3Zn3Y2 particles improved thermal stability by hindering grain growth.•Y-contained alloy showed higher strength at both ambient and elevated temperatures.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2019.153083