Controlled Dephasing of a Quantum Dot: From Coherent to Sequential Tunneling

TL;DR

This paper demonstrates how detecting electron trajectories in a quantum dot causes a transition from coherent tunneling to sequential, nearly insulating behavior, by coupling the dot to a detector channel in the quantum Hall regime.

Contribution

It introduces a method to control dephasing in quantum dots via edge channel coupling, revealing the transition from coherent to sequential tunneling.

Findings

Detecting electron paths dephases the quantum dot completely.

A small bias in the detector channel suffices for dephasing.

The derived dephasing formula matches experimental data.

Abstract

Resonant tunneling through identical potential barriers is a textbook problem in quantum mechanics. Its solution yields total transparency (100% tunneling) at discrete energies. This dramatic phenomenon results from coherent interference among many trajectories, and it is the basis of transport through periodic structures. Resonant tunneling of electrons is commonly seen in semiconducting 'quantum dots'. Here we demonstrate that detecting (distinguishing) electron trajectories in a quantum dot (QD) renders the QD nearly insulating. We couple trajectories in the QD to a 'detector' by employing edge channels in the integer quantum Hall regime. That is, we couple electrons tunneling through an inner channel to electrons in the neighboring outer, 'detector' channel. A small bias applied to the detector channel suffices to dephase (quench) the resonant tunneling completely. We derive a formula for dephasing that agrees well with our data and implies that just a few electrons passing through the detector channel suffice to dephase the QD completely. This basic experiment shows how path detection in a QD induces a transition from delocalization (due to coherent tunneling) to localization (sequential tunneling).