Open AccessEnormous shrinkage of carbon nanotubes by supersonic stress and low-acceleration electron beam irradiation
Author(s) -
Junichi Fujita,
Teppei Takahashi,
Ryuichi Ueki,
Takeshi Hikata,
Soichiro Okubo,
Risa Utsunomiya,
Teruaki Matsuba
Publication year - 2012
Publication title -
journal of vacuum science and technology b nanotechnology and microelectronics materials processing measurement and phenomena
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.429
H-Index - 119
eISSN - 2166-2754
pISSN - 2166-2746
DOI - 10.1116/1.3694027
Subject(s) - shrinkage , supersonic speed , carbon nanotube , materials science , stress (linguistics) , composite material , deformation (meteorology) , electron beam processing , cathode ray , beam (structure) , irradiation , electron , mechanics , optics , physics , quantum mechanics , linguistics , philosophy , nuclear physics
The authors demonstrated a new method for inducing enormous shrinkage in single-walled carbon nanotube bundles by applying low energy electron beam irradiation along with supersonic vibration, and a maximum shrinkage rate of −100% cm2/C was obtained under electron acceleration of 1 keV. The characteristic feature of the shrunken single-walled carbon nanotubes was a wavy deformation that affected the entire bundle. The authors believe that a uniaxial stress induced by the supersonic vibration broke the equilibrium of the internal stress and allowed the uniform accumulation of defects under low energy electron beam excitation. The wavy deformation of the single-walled carbon nanotubes resulted in the enormous shrinkage of the bundle
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