Inelastic tunneling effects on noise properties of molecular junctions

TL;DR

This paper investigates how electron-phonon interactions influence current noise in molecular junctions, revealing inelastic effects, phonon sidebands, and potential diagnostic applications for experimental noise data.

Contribution

It introduces a simple model analyzing inelastic tunneling effects on noise, highlighting how electron-phonon coupling alters noise spectra and provides diagnostic insights.

Findings

Noise amplitude varies with inelastic channel opening.

Phonon sidebands appear in differential noise spectra under strong coupling.

Asymmetry affects the noise peak structure and can serve as a diagnostic tool.

Abstract

The effect of electron-phonon coupling on the current noise in a molecular junction is investigated within a simple model. The model comprises a 1-level bridge representing a molecular level that connects between two free electron reservoirs and is coupled to a vibrational degree of freedom representing a molecular vibrational mode. The latter in turn is coupled to a phonon bath that represents the thermal environment. We focus on the zero frequency noise spectrum and study the changes in its behavior under weak and strong electron-phonon interactions. In the weak coupling regime we find that the noise amplitude can increase or decrease as a result of opening of an inelastic channel, depending on distance from resonance and on junction asymmetry. In particular the relative Fano factor decreases with increasing off resonance distance and junction asymmetry. For resonant inelastic tunneling with strong electron-phonon coupling the differential noise spectrum can show phonon sidebands in addition to a central feature. Such sidebands can be observed when displaying the noise against the source-drain voltage, but not in noise vs. gate voltage plots obtained at low source-drain bias. A striking crossover of the central feature from double to single peak is found for increasing asymmetry in the molecule-leads coupling or increasing electron-phonon interaction. These variations provide a potential diagnostic tool. A possible use of noise data from scanning tunneling microscopy experiments for estimating the magnitude of the electron-phonon interaction on the bridge is proposed.