Approaching the ideal elastic limit of metallic glasses

Lin Tian; Yong Qiang Cheng; Zhi Wei Shan; Ju Li; Cheng Cai Wang; Xiao Dong Han; Jun Sun; Evan Ma

doi:10.1038/ncomms1619

Approaching the ideal elastic limit of metallic glasses

Lin Tian
, Yong Qiang Cheng
, Zhi Wei Shan
, Ju Li
, Cheng Cai Wang
, Xiao Dong Han
, Jun Sun
, Evan Ma

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

381 Scopus citations

Abstract

The ideal elastic limit is the upper bound to the stress and elastic strain a material can withstand. This intrinsic property has been widely studied for crystalline metals, both theoretically and experimentally. For metallic glasses, however, the ideal elastic limit remains poorly characterized and understood. Here we show that the elastic strain limit and the corresponding strength of submicron-sized metallic glass specimens are about twice as high as the already impressive elastic limit observed in bulk metallic glass samples, in line with model predictions of the ideal elastic limit of metallic glasses. We achieve this by employing an in situ transmission electron microscope tensile deformation technique. Furthermore, we propose an alternative mechanism for the apparent 'work hardening' behaviour observed in the tensile stress-strain curves.

Original language	English
Article number	609
Journal	Nature Communications
Volume	3
DOIs	https://doi.org/10.1038/ncomms1619
State	Published - 2012
Externally published	Yes

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10.1038/ncomms1619

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title = "Approaching the ideal elastic limit of metallic glasses",

abstract = "The ideal elastic limit is the upper bound to the stress and elastic strain a material can withstand. This intrinsic property has been widely studied for crystalline metals, both theoretically and experimentally. For metallic glasses, however, the ideal elastic limit remains poorly characterized and understood. Here we show that the elastic strain limit and the corresponding strength of submicron-sized metallic glass specimens are about twice as high as the already impressive elastic limit observed in bulk metallic glass samples, in line with model predictions of the ideal elastic limit of metallic glasses. We achieve this by employing an in situ transmission electron microscope tensile deformation technique. Furthermore, we propose an alternative mechanism for the apparent 'work hardening' behaviour observed in the tensile stress-strain curves.",

author = "Lin Tian and Cheng, \{Yong Qiang\} and Shan, \{Zhi Wei\} and Ju Li and Wang, \{Cheng Cai\} and Han, \{Xiao Dong\} and Jun Sun and Evan Ma",

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journal = "Nature Communications",

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T1 - Approaching the ideal elastic limit of metallic glasses

AU - Tian, Lin

AU - Cheng, Yong Qiang

AU - Shan, Zhi Wei

AU - Li, Ju

AU - Wang, Cheng Cai

AU - Han, Xiao Dong

AU - Sun, Jun

AU - Ma, Evan

PY - 2012

Y1 - 2012

N2 - The ideal elastic limit is the upper bound to the stress and elastic strain a material can withstand. This intrinsic property has been widely studied for crystalline metals, both theoretically and experimentally. For metallic glasses, however, the ideal elastic limit remains poorly characterized and understood. Here we show that the elastic strain limit and the corresponding strength of submicron-sized metallic glass specimens are about twice as high as the already impressive elastic limit observed in bulk metallic glass samples, in line with model predictions of the ideal elastic limit of metallic glasses. We achieve this by employing an in situ transmission electron microscope tensile deformation technique. Furthermore, we propose an alternative mechanism for the apparent 'work hardening' behaviour observed in the tensile stress-strain curves.

AB - The ideal elastic limit is the upper bound to the stress and elastic strain a material can withstand. This intrinsic property has been widely studied for crystalline metals, both theoretically and experimentally. For metallic glasses, however, the ideal elastic limit remains poorly characterized and understood. Here we show that the elastic strain limit and the corresponding strength of submicron-sized metallic glass specimens are about twice as high as the already impressive elastic limit observed in bulk metallic glass samples, in line with model predictions of the ideal elastic limit of metallic glasses. We achieve this by employing an in situ transmission electron microscope tensile deformation technique. Furthermore, we propose an alternative mechanism for the apparent 'work hardening' behaviour observed in the tensile stress-strain curves.

UR - https://www.scopus.com/pages/publications/84858708939

U2 - 10.1038/ncomms1619

DO - 10.1038/ncomms1619

M3 - Article

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SN - 2041-1723

VL - 3

JO - Nature Communications

JF - Nature Communications

M1 - 609

ER -

Approaching the ideal elastic limit of metallic glasses

Abstract

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