Excitation spectra, spin structures, and entanglement characteristics of four-electron double-quantum-dot artificial molecules

TL;DR

This study investigates the energy spectra, spin configurations, and entanglement of four electrons in double quantum dots, revealing formation of Wigner supermolecules and strongly entangled states with potential quantum information applications.

Contribution

It provides a detailed analysis of four-electron double quantum dots using exact diagonalization, highlighting the formation of Wigner supermolecules and their entanglement properties, which are novel insights.

Findings

Identification of a low-energy band of six states crossing at a specific magnetic field.

Formation of Wigner supermolecules with electrons localized at vertices of a parallelogram.

Generation of strongly entangled N-qubit Dicke states.

Abstract

Energy spectra, spin configurations, and entanglement characteristics of a system of four electrons in lateral double quantum dots are investigated using exact diagonalization (EXD), as a function of interdot separation, applied magnetic field, and strength of interelectron repulsion. A distinctly different quantum behavior is found compared to that of circular single quantum dots. As a function of the magnetic field, the energy spectra exhibit a low-energy band consisting of a group of six states, with the number six being a consequence of the conservation of the total spin of the four electrons and the ensuing spin degeneracies. These six states appear to cross at a single value of the magnetic field, with the crossing point becoming sharper for larger interdot distances. As the strength of the Coulomb repulsion increases, the six states tend to become degenerate and a well defined energy gap separates them from the higher-in-energy excited states. The appearance of the low-energy band is a consequence of the formation of a Wigner supermolecule, with the four electrons (two in each dot) being localized at the vertices of a rectangular parallelogram. Using the spin-resolved pair-correlation functions, one can map the EXD many-body wave functions onto the spin functions associated with the four localized electrons. Analogies with nanomagnets, such as finite Heisenberg clusters, are discussed. The ability to determine associated spin functions enables investigations concerning entanglement properties of the system of four electrons. In particular, the formation of Wigner supermolecules generates EXD solutions belonging to the class of strongly entangled states referred to as N-qubit Dicke states in the quantum-information literature.