Please use this identifier to cite or link to this item: https://repository.cihe.edu.hk/jspui/handle/cihe/2575
Title: Critical strain of carbon nanotubes: An atomic-scale finite element study
Author(s): Leung, Andrew Yee Tak 
Author(s): Guo, X.
Jiang, H.
He, X. Q.
Huang, Y.
Issue Date: 2007
Publisher: The American Society of Mechanical Engineers
Journal: Journal of Applied Mechanics 
Volume: 74
Issue: 2
Start page: 347
End page: 351
Abstract: 
This paper employs the atomic-scale finite element method (AFEM) to study critical strain of axial buckling for carbon nanotubes (CNTs). Brenner et al. “second-generation” empirical potential is used to model covalent bonds among atoms. The computed energy curve and critical strain for (8, 0) single-walled CNT (SWNT) agree well with molecular dynamics simulations. Both local and global buckling are achieved, two corresponding buckling zones are obtained, and the global buckling behavior of SWNT with a larger aspect ratio approaches gradually to that of a column described by Euler’s formula. For double-walled CNTs with smaller ratio of length to outer diameter, the local buckling behavior can be explained by conventional shell theory very well. AFEM is an efficient way to study buckling of CNTs.
URI: https://repository.cihe.edu.hk/jspui/handle/cihe/2575
DOI: 10.1115/1.2198548
CIHE Affiliated Publication: No
Appears in Collections:CIS Publication

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