Deformation localization in constrained layers of metallic glasses: A parametric modeling analysis

Localized plastic deformation known as shear banding is a prominent feature in metallic glasses. In this study we perform parametric three-dimensional finite element analyses, using primarily a thin layer of metallic glass on top of a cylindrical base, to study how physical constraint can affect thi...

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Bibliographic Details
Published in:Thin solid films 2014-06, Vol.561, p.108-113
Main Authors: Rogers, D.N., Shen, Y.-L.
Format: Article
Language:English
Subjects:
Amorphous materials
Deformation
Finite element analysis
Mathematical models
Metallic glass
Metallic glasses
Plastic deformation
Shear band
Slip bands
Stress-strain relationships
Thin film
Thin films
Three dimensional
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Summary:Localized plastic deformation known as shear banding is a prominent feature in metallic glasses. In this study we perform parametric three-dimensional finite element analyses, using primarily a thin layer of metallic glass on top of a cylindrical base, to study how physical constraint can affect this localized form of deformation and the corresponding macroscopic stress–strain response. Random perturbation points are added to the metallic glass model to facilitate the formation of shear bands. The modeling result suggests that the mechanical behavior of metallic glasses can be significantly influenced by the geometrical confinement. Under nominally uniaxial compressive loading, a lower thickness-to-diameter ratio results in higher plastic flow stresses. Shear bands tend to concentrate in regions away from the interface with the base material. The findings provide a mechanistic rationale for experimental observations based on the micropillar compression test. The deformation pattern in a multilayered metallic glass structure is also examined. •Localized deformation in constrained metallic-glass layers is studied numerically.•Mechanical response and shear band evolution were sensitive to specimen geometry.•Interfacial constraint similarly influences localized and homogeneous deformation.
ISSN:0040-6090
1879-2731
DOI:10.1016/j.tsf.2013.05.170