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Defects, Quasibound States, and Quantum Conductance in Metallic Carbon Nanotubes
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Abstract
The effects of impurities and local structural defects on the conductance of metallic
carbon nanotubes are calculated using an ab initio pseudopotential method within the
Landauer formalism. Substitutionally doped boron or nitrogen produces quasibound impurity
states of a definite parity and reduces the conductance by a quantum unit (2e(2)/h)
via resonant backscattering. These resonant states show strong similarity to acceptor
or donor states in semiconductors. The Stone-Wales defect also produces quasibound
states and exhibits quantized conductance reduction. In the case of a vacancy, the
conductance shows a much more complex behavior than the prediction from the widely
used pi-electron tight-binding model.