Long fine single-wall carbon nanotube growth by Nano-spin-threading: model schematics and simulations

We have investigated model schematics for a long fine single-wall carbon nanotube growth inside a larger diameter nanotube. Our proposed schematics are as follows: fullerenes are encapsulated into the nano-channel connected with fullerene storage tank; and then a inner nanotube grows via fullerene coalescence under ∼1200 °C in the nano-channel. Then the grown carbon nanotube is extracted from the nano-channel by mechanical control. We have investigated fullerene mergence inside single-wall carbon nanotube using classical molecular dynamics simulations based on the Tersoff–Brenner potential and the Lennard–Jones potential. During fullerene-encapsulating, since the fullerenes naturally have the kinetic energies due to the suction force and can be also accelerated by external force fields to improve the fullerene encapsulation rate, they can be migrated toward the other side of the nano-channel with kinetic energies. Our molecular dynamics simulations showed that the structural relaxation of dynamically free atoms affected on the growth of inner carbon nanotube rather than the Stone-Wales transformations. Since the broken bonds make the structural relaxation during merging to be easily achieved from the migration of carbon atoms or carbon chains, the inner nanotube grows via the re-bonding-reactions of dynamically free carbon atoms or chains as well as the Stone-Wales transformations. We could conclude that the growth rate of the inner CNT could be increased when bond-breakings between carbon atoms of fullerenes were easily achieved.