Atomic size and local order effects on the high temperature strength of binary Mg alloys

The solid solution strengthening introduced by Ca (0.6 and 0.9at%) and Sn 0.5–2.5at%) was studied through tensile, compression and stress relaxation tests at room temperature, 373K (100°C) and 453K (180°C) on solution heat-treated and quenched specimens and compared with existing data for binary all...

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Published inMaterials science & engineering. A, Structural materials : properties, microstructure and processing Vol. 673; pp. 114 - 121
Main Authors Abaspour, Saeideh, Zambelli, Victor, Dargusch, Matthew, Cáceres, Carlos H.
Format Journal Article
LanguageEnglish
Published Elsevier B.V 15.09.2016
Subjects
Aluminum
Binary alloys
Calcium
Chemical bonds
Creep strength
Magnesium base alloys
Matching
Mg–Ca alloys
Mg–RE alloys
Short range order (SRO)
Strengthening
Stress relaxation, Solid solution hardening
Tin
Creep strength
Short range order (SRO)
Mg–RE alloys
Mg–Ca alloys
Stress relaxation, Solid solution hardening
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Summary:The solid solution strengthening introduced by Ca (0.6 and 0.9at%) and Sn 0.5–2.5at%) was studied through tensile, compression and stress relaxation tests at room temperature, 373K (100°C) and 453K (180°C) on solution heat-treated and quenched specimens and compared with existing data for binary alloys containing Ca, Sn, Y, Gd, Nd, Zn and Al as well as for AZ91 alloy. At room temperature the solution-hardening rate introduced by Ca and Sn was much higher than that of Al, matching those of Y, Gd and Zn. Calcium also reduced the tension/compression asymmetry. At high temperature Ca effectively prevented stress relaxation, nearly matching Y, Gd and Nd. Tin was less effective, but still outperformed Al and AZ91 at low stresses. The effects at room and high temperature introduced by Ca and Sn appeared consistent with the presence of short-range order, in line with those introduced by Y, Nd, Gd and Zn. The larger than Mg atom size of Ca, Nd, Gd and Y can be expected to intensify the local order by strengthening the atomic bonds through its effects on the local electron density, accounting for their greater strengthening at high temperature. For given difference in atomic size, the effects on the local order are expected to be lesser for smaller sized atoms like Sn and Zn, hence their more subdued effects.
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ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2016.07.019