Plasmon exchange model for superconductivity in Carbon nanotubes

TL;DR

This paper proposes a plasmon exchange mechanism to explain the higher superconducting transition temperature in carbon nanotubes, which traditional phonon models fail to account for, by calculating electron interactions mediated by plasmons.

Contribution

It introduces a plasmon exchange model for superconductivity in nanotubes and demonstrates its ability to predict observed critical temperatures.

Findings

Plasmon exchange can induce attractive electron interactions in nanotubes.

Critical temperature depends on dielectric constant, electron effective mass, and nanotube radius.

Model explains observed superconductivity at around 15 K.

Abstract

Recent investigations of superconductivity in carbon nanotubes have shown that a single-wall zigzag nanotube can become superconducting at around 15 K. Theoretical studies of superconductivity in nanotubes using the traditional phonon exchange model, however, give a superconducting transition temperature $T_c$ less than 1K. To explain the observed higher critical temperature we explo re the possibility of the plasmon exchange mechanism for superconductivity in nanotubes. We first calculate the effective interaction between electrons in a nanotube mediated by plasmon exchange and show that this interaction can become attractive. Using this attractive interaction in the modified Eliashberg theory for strong coupling superconductors, we then calculate the critical temperature $T_c$ in a nanotube. We find that $T_c$ is sensitively dependent on the dielectric constant of the medium, the effective mass of the electrons an d the radius of the nanotube. Our theoretical results can explain the observed $T_c$ in a nanotube.