A Brief Review of Spall Failure in Pure and Alloyed Magnesium

The ratio of the yield strength to the density (specific strength) of magnesium and its alloys is relatively high, but cavitation-driven spall failure of these materials occurs at low threshold stresses and strains. The low failure threshold suggests a general susceptibility to catastrophic failure...

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Bibliographic Details
Published inJournal of dynamic behavior of materials Vol. 6; no. 4; pp. 423 - 431
Main Authors Mallick, D. D., Williams, C. L., Wilkerson, J. W.
Format Journal Article
LanguageEnglish
Published Cham Springer International Publishing 01.12.2020
Springer Nature B.V
Subjects
Alloying
Catastrophic events
Cavitation
Chemistry and Materials Science
Failure
Grain size
Magnesium base alloys
Materials Science
Metallic Materials
Nucleation
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Solid Mechanics
Strain rate
Strength
Threshold stress
Grain size
Spall strength
Magnesium alloys
High strain rate
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Summary:The ratio of the yield strength to the density (specific strength) of magnesium and its alloys is relatively high, but cavitation-driven spall failure of these materials occurs at low threshold stresses and strains. The low failure threshold suggests a general susceptibility to catastrophic failure under tension at high rates of deformation. Higher material strength likely prevents such failure, but processing methods to achieve these strengths can introduce potential failure nucleation sites that can make failure more likely—the interplay between matrix strength and nucleation sites remains largely unknown. Here we examine the literature regarding experimental observation of spall failure of pure and alloyed magnesium with a particular emphasis on the trends between grain size and strain rate with respect to the spall failure strength. We then apply an analytical dynamic cavitation model to better understand the role of second phase particles in spall failure. We find that the conventional polycrystalline alloys with micron sized grains have microstructures containing second phase particles that act as failure nucleation sites, diminishing the potential to design against low failure threshold stresses. Additionally, nanocrystalline grained magnesium remains largely unexplored and may potentially offer an avenue for greater dynamic strength.
ISSN:2199-7446
2199-7454
DOI:10.1007/s40870-020-00233-z