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Quantum electron transport in toroidal carbon nanotubes with metallic leads

Quantum Physics 2007-09-07 v1
Authors: Mark A. Jack , Mario R. Encinosa
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Abstract

A recursive Green's function method is employed to calculate the density-of-states, transmission function, and current through a 150 layer (3,3) armchair nanotorus (1800 atoms) with laterally attached metallic leads as functions of relative lead angle and magnetic flux. Plateaus in the transmissivity through the torus occur over wide ranges of lead placement, accompanied by enhancements in the transmissivity through the torus as magnetic flux normal to the toroidal plane is varied.

Keywords

molecular electronics carbon nanotubes

Cite

@article{arxiv.0709.0760,
  title  = {Quantum electron transport in toroidal carbon nanotubes with metallic leads},
  author = {Mark A. Jack and Mario R. Encinosa},
  journal= {arXiv preprint arXiv:0709.0760},
  year   = {2007}
}

Comments

15 pages, 11 .eps figures, 1 black and white figure, 10 color figures, uses revtex4; manuscript presented at conference NSTI07 Nanotech 2007, May 20-24, 2007, Santa Clara, CA

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