Transport via a quantum shuttle

TL;DR

This paper studies how a quantized vibrational mode in a quantum dot system affects electron tunneling, revealing resonance phenomena and the potential for electron shuttling driven by quantum vibrations.

Contribution

It introduces a model combining quantum vibrational modes with electron tunneling in a triple quantum dot system, highlighting quantum effects on electron transport.

Findings

Current exhibits resonances at avoided-level crossings.

Quantum oscillator can shuttle electrons across the system.

Damping can enhance current by suppressing backward hopping.

Abstract

We investigate the effect of a quantised vibrational mode on electron tunneling through a chain of three quantum dots. The outer dots are coupled to voltage leads, but the position of the central dot is not rigidly fixed. Motion of the central dot modulates the size of the tunneling barriers in opposite ways so that electron tunneling is correlated with the position of the oscillator. We treat the electronic part of the problem using a simple Coulomb-blockade picture, and model the vibration of the central dot as a quantum oscillator. We calculate the eigenspectrum of the system as a function of the energy level shift between the outer dots. Using a density matrix method, we include couplings to external leads and calculate the steady-state current through the device. The current shows marked resonances which correspond to avoided-level crossings in the eigenvalue spectrum. When the tunneling length of the electrons is of order the zero-point position uncertainty of the quantum oscillator, current far from the electronic resonance is dominated by electrons hopping on and off the central dot sequentially; the oscillator can be regarded as shuttling electrons across the system [L.Y. Gorelik, et al., Phys. Rev. Lett. 80, 4526 (1998)]. Damping of the oscillator can increase the current by preventing electrons from hopping `backwards'.