Quantitative evidence of crossover toward partial dislocation mediated plasticity in copper single crystalline nanowires

Yonghai Yue; Pan Liu; Qingsong Deng; Evan Ma; Ze Zhang; Xiaodong Han

doi:10.1021/nl3014132

Quantitative evidence of crossover toward partial dislocation mediated plasticity in copper single crystalline nanowires

Yonghai Yue
, Pan Liu
, Qingsong Deng
, Evan Ma
, Ze Zhang
, Xiaodong Han

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

116 Scopus citations

Abstract

In situ tensile tests of Cu single crystalline nanowires in a high-resolution transmission electron microscope reveal a novel effect of sample dimensions on plasticity mechanisms. When the single crystalline nanowire size was reduced to <∼150 nm, the normal full dislocation slip was taken over by partial dislocation mediated plasticity (PDMP). For the first time, we demonstrate this transition in a quantitative manner by assessing the relative contributions to plastic strain from PDMP and full dislocations. The crossover sample size is consistent, well within model predictions. This discovery represents yet another "sample size effect", beyond other reported influence of sample dimensions on the mechanical behavior of metals, such as dislocation starvation or source truncation, and the "smaller is stronger" trend.

Original language	English
Pages (from-to)	4045-4049
Number of pages	5
Journal	Nano Letters
Volume	12
Issue number	8
DOIs	https://doi.org/10.1021/nl3014132
State	Published - 8 Aug 2012
Externally published	Yes

Keywords

Plasticity mechanisms
copper nanowire
in situ TEM
quantitative plastic contribution
size dependence

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10.1021/nl3014132

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title = "Quantitative evidence of crossover toward partial dislocation mediated plasticity in copper single crystalline nanowires",

abstract = "In situ tensile tests of Cu single crystalline nanowires in a high-resolution transmission electron microscope reveal a novel effect of sample dimensions on plasticity mechanisms. When the single crystalline nanowire size was reduced to <∼150 nm, the normal full dislocation slip was taken over by partial dislocation mediated plasticity (PDMP). For the first time, we demonstrate this transition in a quantitative manner by assessing the relative contributions to plastic strain from PDMP and full dislocations. The crossover sample size is consistent, well within model predictions. This discovery represents yet another {"}sample size effect{"}, beyond other reported influence of sample dimensions on the mechanical behavior of metals, such as dislocation starvation or source truncation, and the {"}smaller is stronger{"} trend.",

keywords = "Plasticity mechanisms, copper nanowire, in situ TEM, quantitative plastic contribution, size dependence",

author = "Yonghai Yue and Pan Liu and Qingsong Deng and Evan Ma and Ze Zhang and Xiaodong Han",

year = "2012",

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doi = "10.1021/nl3014132",

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T1 - Quantitative evidence of crossover toward partial dislocation mediated plasticity in copper single crystalline nanowires

AU - Yue, Yonghai

AU - Liu, Pan

AU - Deng, Qingsong

AU - Ma, Evan

AU - Zhang, Ze

AU - Han, Xiaodong

PY - 2012/8/8

Y1 - 2012/8/8

N2 - In situ tensile tests of Cu single crystalline nanowires in a high-resolution transmission electron microscope reveal a novel effect of sample dimensions on plasticity mechanisms. When the single crystalline nanowire size was reduced to <∼150 nm, the normal full dislocation slip was taken over by partial dislocation mediated plasticity (PDMP). For the first time, we demonstrate this transition in a quantitative manner by assessing the relative contributions to plastic strain from PDMP and full dislocations. The crossover sample size is consistent, well within model predictions. This discovery represents yet another "sample size effect", beyond other reported influence of sample dimensions on the mechanical behavior of metals, such as dislocation starvation or source truncation, and the "smaller is stronger" trend.

AB - In situ tensile tests of Cu single crystalline nanowires in a high-resolution transmission electron microscope reveal a novel effect of sample dimensions on plasticity mechanisms. When the single crystalline nanowire size was reduced to <∼150 nm, the normal full dislocation slip was taken over by partial dislocation mediated plasticity (PDMP). For the first time, we demonstrate this transition in a quantitative manner by assessing the relative contributions to plastic strain from PDMP and full dislocations. The crossover sample size is consistent, well within model predictions. This discovery represents yet another "sample size effect", beyond other reported influence of sample dimensions on the mechanical behavior of metals, such as dislocation starvation or source truncation, and the "smaller is stronger" trend.

KW - Plasticity mechanisms

KW - copper nanowire

KW - in situ TEM

KW - quantitative plastic contribution

KW - size dependence

UR - https://www.scopus.com/pages/publications/84864642789

U2 - 10.1021/nl3014132

DO - 10.1021/nl3014132

M3 - 文章

AN - SCOPUS:84864642789

SN - 1530-6984

VL - 12

SP - 4045

EP - 4049

JO - Nano Letters

JF - Nano Letters

IS - 8

ER -

Quantitative evidence of crossover toward partial dislocation mediated plasticity in copper single crystalline nanowires

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Keywords

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