The Polarizability and Electric Field-Induced Energy Gaps In Carbon Nanotubes

A simple method to calculate the static electric polarization of single-walled carbon nanotube (SWNT) is obtained within the second-order perturbation approximation. The results are in agreement with the previous calculation within the random-phase approximation. We also find that the low energy electronic band structure of SWNT can be affected by an external electric field perpendicular to the axis of the tube. The field-induced energy gap shows strong dependence on the electric field and the size of the tubes, and a metal-insulator transition is predicted for all $(n, n)$ tubes. Universal scaling is found for the gap as function of the electric field and the radius of SWNTs. The fact that the external field required to induce a 0.1 ${\rm eV}$ gap in SWNTs can be reached under the currently available experimental conditions indicates a possibility of further applying nanotubes to electric signal-controlled nanoscale switching devices.