6533b861fe1ef96bd12c45a1
RESEARCH PRODUCT
The diffusion of carbon atoms inside carbon nanotubes
Jani KotakoskiJani KotakoskiYanjie GanFlorian BanhartArkady V. KrasheninnikovArkady V. KrasheninnikovKai Nordlundsubject
General Physics and Astronomychemistry.chemical_elementMechanical properties of carbon nanotubes02 engineering and technologyCarbon nanotube114 Physical sciences01 natural sciencesMolecular physicslaw.inventionCondensed Matter::Materials SciencePotential applications of carbon nanotubeslaw0103 physical sciencesElectron beam processingPhysics::Atomic Physics010306 general physicsCondensed Matter::Quantum GasesPhysicsCarbon nanofiber021001 nanoscience & nanotechnologyOptical properties of carbon nanotubeschemistryBallistic conduction in single-walled carbon nanotubesAtomic physics0210 nano-technologyCarbondescription
We combine electron irradiation experiments in a transmission electron microscope with kinetic Monte Carlo simulations to determine the mobility of interstitial carbon atoms in single-walled carbon nanotubes. We measure the irradiation dose necessary to cut nanotubes repeatedly with a focused electron beam as a function of the separation between the cuts and at different temperatures. As the cutting speed is related to the migration of displaced carbon atoms trapped inside the tube and to their recombination with vacancies, we obtain information about the mobility of the trapped atoms and estimate their migration barrier to be about 0.25 eV. This is an experimental confirmation of the remarkably high mobility of interstitial atoms inside carbon nanotubes, which shows that nanotubes have potential applications as pipelines for the transport of carbon atoms. We combine electron irradiation experiments in a transmission electron microscope with kinetic Monte Carlo simulations to determine the mobility of interstitial carbon atoms in single-walled carbon nanotubes. We measure the irradiation dose necessary to cut nanotubes repeatedly with a focused electron beam as a function of the separation between the cuts and at different temperatures. As the cutting speed is related to the migration of displaced carbon atoms trapped inside the tube and to their recombination with vacancies, we obtain information about the mobility of the trapped atoms and estimate their migration barrier to be about 0.25 eV. This is an experimental confirmation of the remarkably high mobility of interstitial atoms inside carbon nanotubes, which shows that nanotubes have potential applications as pipelines for the transport of carbon atoms. We combine electron irradiation experiments in a transmission electron microscope with kinetic Monte Carlo simulations to determine the mobility of interstitial carbon atoms in single-walled carbon nanotubes. We measure the irradiation dose necessary to cut nanotubes repeatedly with a focused electron beam as a function of the separation between the cuts and at different temperatures. As the cutting speed is related to the migration of displaced carbon atoms trapped inside the tube and to their recombination with vacancies, we obtain information about the mobility of the trapped atoms and estimate their migration barrier to be about 0.25 eV. This is an experimental confirmation of the remarkably high mobility of interstitial atoms inside carbon nanotubes, which shows that nanotubes have potential applications as pipelines for the transport of carbon atoms. Peer reviewed
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2008-02-15 | New Journal of Physics |