Kink formation and motion in carbon nanotubes at high temperatures

J. Y. Huang; S. Chen; Z. F. Ren; Z. Q. Wang; D. Z. Wang; M. Vaziri; Z. Suo; G. Chen; M. S. Dresselhaus

doi:10.1103/PhysRevLett.97.075501

Kink formation and motion in carbon nanotubes at high temperatures

J. Y. Huang
, S. Chen
, Z. F. Ren
, Z. Q. Wang
, D. Z. Wang
, M. Vaziri
, Z. Suo
, G. Chen
, M. S. Dresselhaus

Boston College
University of Michigan, Flint
Harvard University
Massachusetts Institute of Technology

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

76 Scopus citations

Abstract

We report that kink motion is a universal plastic deformation mode in all carbon nanotubes when being tensile loaded at high temperatures. The kink motion, observed inside a high-resolution transmission electron microscope, is reminiscent of dislocation motion in crystalline materials: namely, it dissociates and multiplies. The kinks are nucleated from vacancy creation and aggregation, and propagate in either a longitudinal or a spiral path along the nanotube walls. The kink motion is related to dislocation glide and climb influenced by external stress and high temperatures in carbon nanotubes.

Original language	English
Article number	075501
Journal	Physical Review Letters
Volume	97
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevLett.97.075501
State	Published - 2006
Externally published	Yes

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10.1103/PhysRevLett.97.075501

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title = "Kink formation and motion in carbon nanotubes at high temperatures",

abstract = "We report that kink motion is a universal plastic deformation mode in all carbon nanotubes when being tensile loaded at high temperatures. The kink motion, observed inside a high-resolution transmission electron microscope, is reminiscent of dislocation motion in crystalline materials: namely, it dissociates and multiplies. The kinks are nucleated from vacancy creation and aggregation, and propagate in either a longitudinal or a spiral path along the nanotube walls. The kink motion is related to dislocation glide and climb influenced by external stress and high temperatures in carbon nanotubes.",

author = "Huang, \{J. Y.\} and S. Chen and Ren, \{Z. F.\} and Wang, \{Z. Q.\} and Wang, \{D. Z.\} and M. Vaziri and Z. Suo and G. Chen and Dresselhaus, \{M. S.\}",

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AU - Huang, J. Y.

AU - Chen, S.

AU - Ren, Z. F.

AU - Wang, Z. Q.

AU - Wang, D. Z.

AU - Vaziri, M.

AU - Suo, Z.

AU - Chen, G.

AU - Dresselhaus, M. S.

PY - 2006

Y1 - 2006

N2 - We report that kink motion is a universal plastic deformation mode in all carbon nanotubes when being tensile loaded at high temperatures. The kink motion, observed inside a high-resolution transmission electron microscope, is reminiscent of dislocation motion in crystalline materials: namely, it dissociates and multiplies. The kinks are nucleated from vacancy creation and aggregation, and propagate in either a longitudinal or a spiral path along the nanotube walls. The kink motion is related to dislocation glide and climb influenced by external stress and high temperatures in carbon nanotubes.

AB - We report that kink motion is a universal plastic deformation mode in all carbon nanotubes when being tensile loaded at high temperatures. The kink motion, observed inside a high-resolution transmission electron microscope, is reminiscent of dislocation motion in crystalline materials: namely, it dissociates and multiplies. The kinks are nucleated from vacancy creation and aggregation, and propagate in either a longitudinal or a spiral path along the nanotube walls. The kink motion is related to dislocation glide and climb influenced by external stress and high temperatures in carbon nanotubes.

UR - https://www.scopus.com/pages/publications/33747235381

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DO - 10.1103/PhysRevLett.97.075501

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JO - Physical Review Letters

JF - Physical Review Letters

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ER -

Kink formation and motion in carbon nanotubes at high temperatures

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