Theory of phonon-drag thermopower of extrinsic semiconducting single-wall carbon nanotubes and comparison with previous experimental data

Abstract

A theoretical model for the calculation of the phonon-drag thermopower, Sg, in degenerately doped semiconducting single-wall carbon nanotubes (SWCNTs) is proposed. Detailed calculations of Sg are performed as a function of temperature, tube radius and position of the Fermi level. We derive a simple analytical expression for Sg that can be utilized to determine the free carrier density in doped nanotubes. At low temperatures Sg shows an activated behavior characteristic of the one-dimensional (1D) character of carriers. Screening effects are taken into account and it is found that they dramatically reduce the magnitude of Sg. Our results are compared with previous published experimental data in bulk p-doped SWCNT materials. Excellent agreement is obtained in the temperature range 10-200 K for a consistent set of parameters. This is a striking result in view of the complexity of these systems.