Tomonaga-Luttinger liquid correlations and Fabry-Perot interference in conductance and finite-frequency shot noise in a single-walled carbon nanotube

TL;DR

This paper provides a comprehensive theoretical analysis of electron transport, Fabry-Perot interference, and shot noise in a single-walled carbon nanotube, highlighting the effects of electron interactions and finite length on measurable electrical properties.

Contribution

It introduces a detailed inhomogeneous Tomonaga-Luttinger liquid model combined with Keldysh approach to analyze high-frequency shot noise and conductance in SWNTs, revealing new insights into mode velocities.

Findings

TLL effects cause power-law behavior in low-frequency transport.

High-frequency shot noise can distinguish charge and spin mode velocities.

Bias voltage influences the dominance of oscillation patterns.

Abstract

We present a detailed theoretical investigation of transport through a single-walled carbon nanotube (SWNT) in good contact to metal leads where weak backscattering at the interfaces between SWNT and source and drain reservoirs gives rise to electronic Fabry-Perot (FP) oscillations in conductance and shot noise. We include the electron-electron interaction and the finite length of the SWNT within the inhomogeneous Tomonaga-Luttinger liquid (TLL) model and treat the non-equilibrium effects due to an applied bias voltage within the Keldysh approach. In low-frequency transport properties, the TLL effect is apparent mainly via power-law characteristics as a function of bias voltage or temperature at energy scales above the finite level spacing of the SWNT. The FP-frequency is dominated by the non-interacting spin mode velocity due to two degenerate subbands rather than the interacting charge velocity. At higher frequencies, the excess noise is shown to be capable of resolving the splintering of the transported electrons arising from the mismatch of the TLL-parameter at the interface between metal reservoirs and SWNT. This dynamics leads to a periodic shot noise suppression as a function of frequency and with a period that is determined solely by the charge velocity. At large bias voltages, these oscillations are dominant over the ordinary FP-oscillations caused by two weak backscatterers. This makes shot noise an invaluable tool to distinguish the two mode velocities in the SWNT.