Effect of Electron Interaction on Statistics of Conductance Oscillations in Open Quantum Dots: Does the Dephasing Time Saturate?

TL;DR

This study uses self-consistent quantum transport calculations to show that electron interactions significantly influence conductance oscillations in open quantum dots at ultralow temperatures, challenging traditional noninteracting models and interpretations of dephasing saturation.

Contribution

It provides a parameter-free, quantitative analysis demonstrating the impact of electron interactions on conductance statistics at ultralow temperatures, questioning existing noninteracting theories.

Findings

Electron interactions cause smearing of conductance oscillations at ultralow temperatures.

The influence of electron interactions diminishes at higher temperatures ($2\pi k_BT extgreater\Delta$).

Results align with experimental observations, challenging conventional dephasing saturation explanations.

Abstract

We perform self-consistent quantum transport calculations in open quantum dots taking into account the effect of electron interaction. We demonstrative that in the regime of the ultralow temperatures $2\pi k_BT\lesssim\Delta$ ($\Delta $ being the mean level spacing), the electron interaction strongly affects the conductance oscillations and their statistics leading to a drastic deviation from the corresponding predictions for noninteracting electrons. In particular, it causes smearing of conductance oscillations, which is similar to the effect of temperature or inelastic scattering. For $2\pi k_BT\gtrsim\Delta$ the influence of electron interaction on the conductance becomes strongly diminished. Our calculations (that are free from phenomenological parameters of the theory) are in good quantitative agreement with the observed ultralow temperature statistics (Huibers \textit{et al.}, Phys. Rev. Lett. \textbf{81}, 1917 (1998)). Our findings question a conventional interpretation of the ultralow temperature saturation of the coherence time in open dots which is based on the noninteracting theories where the electron interaction is neglected and the agrement with the experiment is achieved by introducing additional phenomenological channels of dephasing.