Structural Stability and Energetics of Single-Walled Carbon Nanotubes Under Uniaxial Strain
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Date
2003
Authors
Journal Title
Journal ISSN
Volume Title
Publisher
Amer Physical Soc
Open Access Color
Green Open Access
Yes
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OpenAIRE Views
Publicly Funded
No
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Impulse
Top 10%
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Top 10%
Popularity
Top 10%
Abstract
A (10x10) single-walled carbon nanotube consisting of 400 atoms with 20 layers is simulated under tensile loading using our developed O(N) parallel tight-binding molecular-dynamics algorithms. It is observed that the simulated carbon nanotube is able to carry the strain up to 122% of the relaxed tube length in elongation and up to 93% for compression. Young's modulus, tensile strength, and the Poisson ratio are calculated and the values found are 0.311 TPa, 4.92 GPa, and 0.287, respectively. The stress-strain curve is obtained. The elastic limit is observed at a strain rate of 0.09 while the breaking point is at 0.23. The frequency of vibration for the pristine (10x10) carbon nanotube in the radial direction is 4.71x10(3) GHz and it is sensitive to the strain rate.
Description
Ozdogan, Cem/0000-0002-9644-0013
ORCID
Keywords
Condensed Matter (cond-mat), FOS: Physical sciences, Condensed Matter
Fields of Science
02 engineering and technology, 0210 nano-technology
Citation
Özdoğan, Cem (2003). "Structural stability and energetics of single-walled carbon nanotubes under uniaxial strain", Physical Review B - Condensed Matter and Materials Physics, Vol. 67, No. 3.
WoS Q
Q2
Scopus Q
Q2
OpenCitations Citation Count
69
Source
Physical Review B
Volume
67
Issue
3
Start Page
End Page
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CrossRef : 67
Scopus : 89
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Mendeley Readers : 31
SCOPUS™ Citations
90
checked on Feb 24, 2026
Web of Science™ Citations
69
checked on Feb 24, 2026
Page Views
2
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