A transition from localized shear banding to homogeneous superplastic flow in nanoglass

Sara Adibi; Zhen Dong Sha; Paulo S. Branicio; Shailendra P. Joshi; Zi Shun Liu; Yong Wei Zhang

doi:10.1063/1.4833018

A transition from localized shear banding to homogeneous superplastic flow in nanoglass

Sara Adibi
, Zhen Dong Sha
, Paulo S. Branicio
, Shailendra P. Joshi
, Zi Shun Liu
, Yong Wei Zhang

School of Aerospace Engineering

Research output: Contribution to journal › Article › peer-review

117 Scopus citations

Abstract

A promising remedy to the failure of metallic glasses (MGs) by shear banding is the use of a dense network of glass-glass interfaces, i.e., a nanoglass (NG). Here we investigate the effect of grain size (d) on the failure of NG by performing molecular dynamics simulations of tensile-loading on Cu ₅₀Zr₅₀ NG with d = 5 to 15 nm. Our results reveal a drastic change in deformation mode from a single shear band (d ∼ 15 to 10 nm), to cooperative shear failure (d ∼ 10 to 5 nm), to homogeneous superplastic flow (d ≤ 5 nm). Our results suggest that grain size can be an effective design parameter to tune the mechanical properties of MGs.

Original language	English
Article number	211905
Journal	Applied Physics Letters
Volume	103
Issue number	21
DOIs	https://doi.org/10.1063/1.4833018
State	Published - 18 Nov 2013

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10.1063/1.4833018

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title = "A transition from localized shear banding to homogeneous superplastic flow in nanoglass",

abstract = "A promising remedy to the failure of metallic glasses (MGs) by shear banding is the use of a dense network of glass-glass interfaces, i.e., a nanoglass (NG). Here we investigate the effect of grain size (d) on the failure of NG by performing molecular dynamics simulations of tensile-loading on Cu 50Zr50 NG with d = 5 to 15 nm. Our results reveal a drastic change in deformation mode from a single shear band (d ∼ 15 to 10 nm), to cooperative shear failure (d ∼ 10 to 5 nm), to homogeneous superplastic flow (d ≤ 5 nm). Our results suggest that grain size can be an effective design parameter to tune the mechanical properties of MGs.",

author = "Sara Adibi and Sha, \{Zhen Dong\} and Branicio, \{Paulo S.\} and Joshi, \{Shailendra P.\} and Liu, \{Zi Shun\} and Zhang, \{Yong Wei\}",

year = "2013",

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doi = "10.1063/1.4833018",

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volume = "103",

journal = "Applied Physics Letters",

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AU - Adibi, Sara

AU - Sha, Zhen Dong

AU - Branicio, Paulo S.

AU - Joshi, Shailendra P.

AU - Liu, Zi Shun

AU - Zhang, Yong Wei

PY - 2013/11/18

Y1 - 2013/11/18

N2 - A promising remedy to the failure of metallic glasses (MGs) by shear banding is the use of a dense network of glass-glass interfaces, i.e., a nanoglass (NG). Here we investigate the effect of grain size (d) on the failure of NG by performing molecular dynamics simulations of tensile-loading on Cu 50Zr50 NG with d = 5 to 15 nm. Our results reveal a drastic change in deformation mode from a single shear band (d ∼ 15 to 10 nm), to cooperative shear failure (d ∼ 10 to 5 nm), to homogeneous superplastic flow (d ≤ 5 nm). Our results suggest that grain size can be an effective design parameter to tune the mechanical properties of MGs.

AB - A promising remedy to the failure of metallic glasses (MGs) by shear banding is the use of a dense network of glass-glass interfaces, i.e., a nanoglass (NG). Here we investigate the effect of grain size (d) on the failure of NG by performing molecular dynamics simulations of tensile-loading on Cu 50Zr50 NG with d = 5 to 15 nm. Our results reveal a drastic change in deformation mode from a single shear band (d ∼ 15 to 10 nm), to cooperative shear failure (d ∼ 10 to 5 nm), to homogeneous superplastic flow (d ≤ 5 nm). Our results suggest that grain size can be an effective design parameter to tune the mechanical properties of MGs.

UR - https://www.scopus.com/pages/publications/84888408313

U2 - 10.1063/1.4833018

DO - 10.1063/1.4833018

M3 - 文章

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SN - 0003-6951

VL - 103

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 21

M1 - 211905

ER -

A transition from localized shear banding to homogeneous superplastic flow in nanoglass

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