Transport properties of single channel quantum wires with an impurity: Influence of finite length and temperature on average current and noise

TL;DR

This paper investigates how finite length, temperature, and interactions influence current and noise in a quantum wire with an impurity, revealing oscillations, decoherence effects, and interaction-dependent noise characteristics.

Contribution

It provides a detailed analysis of non-monotonic current behavior and noise spectra in interacting quantum wires with impurities, highlighting the impact of finite size, temperature, and interactions.

Findings

Oscillations in current-voltage characteristics due to plasmon reflections.

Finite temperature washes out oscillations and decoherence effects.

Interaction-dependent features in the noise spectrum, including negative excess noise.

Abstract

The inhomogeneous Tomonaga Luttinger liquid model describing an interacting quantum wire adiabatically coupled to non-interacting leads is analyzed in the presence of a weak impurity within the wire. Due to strong electronic correlations in the wire, the effects of impurity backscattering, finite bias, finite temperature, and finite length lead to characteristic non-monotonic parameter dependencies of the average current. We discuss oscillations of the non-linear current voltage characteristics that arise due to reflections of plasmon modes at the impurity and quasi Andreev reflections at the contacts, and show how these oscillations are washed out by decoherence at finite temperature. Furthermore, the finite frequency current noise is investigated in detail. We find that the effective charge extracted in the shot noise regime in the weak backscattering limit decisively depends on the noise frequency $\omega$ relative to $v_F/gL$, where $v_F$ is the Fermi velocity, $g$ the Tomonaga Luttinger interaction parameter, and $L$ the length of the wire. The interplay of finite bias, finite temperature, and finite length yields rich structure in the noise spectrum which crucially depends on the electron-electron interaction. In particular, the excess noise, defined as the change of the noise due to the applied voltage, can become negative and is non-vanishing even for noise frequencies larger than the applied voltage, which are signatures of correlation effects.