Nonequilibrium transport and population inversion in double quantum dot systems

TL;DR

This paper develops a microscopic nonequilibrium Green's function theory to analyze transport and population inversion in double quantum dot systems, revealing conditions for current peak splitting and inversion.

Contribution

It introduces a general formula for tunneling current in DQDs and explores the effects of multi-level coupling and nonequilibrium distributions using a Hartree-Fock approach.

Findings

Resonant tunneling current peak splits when inter-dot coupling exceeds dot-lead coupling.

Population inversion can be achieved in a single dot under nonequilibrium conditions.

The theory provides insights into transport behavior in coupled quantum dot systems.

Abstract

We present a microscopic theory for both equilibrium and nonequilibrium transport properties of coupled double quantum dots (DQD). A general formula for current tunneling through the DQD is derived by the nonequilibrium Green's function method. Using a Hartree-Fock approach, effects of multi-level coupling and nonequilibrium electron distributions in resonant tunneling are considered. We find that the peak in the resonant tunneling current through two symmetric dots will split only when the inter-dot coupling is stronger than dot-lead coupling. We predict that population inversion can be achieved in one dot in the nonequilibrium regime.