Mechanical relaxation and “intramolecular plasticity” in carbon nanotubes
- 23 February 1998
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 72 (8) , 918-920
- https://doi.org/10.1063/1.120873
Abstract
The question of how carbon nanotubes (CNT)—believed to be the strongest filaments—relax under tension has been addressed. A dislocation theory applied to a two-dimensional nanocrystal such as the CNT describes the main routes of mechanical relaxation in this molecular structure: a brittle cleavage or, at high temperatures, a plastic flow. Both start with diatomic rotation, which “unlocks” the pristine wall of CNT by creating a dislocation dipole with the pentagon–heptagon cores. Under high stress, the dislocations depart from each other along helical paths, leaving behind a nanotube of smaller diameter, well-defined new symmetry, and changed electrical properties.Keywords
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