Single-particle and collective excitations in quantum wires comprised of vertically stacked quantum dots: Finite magnetic field

TL;DR

This paper presents a theoretical study of magnetoplasmon excitations in a system of vertically stacked quantum dots under a magnetic field, highlighting their potential for quantum computing applications.

Contribution

It introduces a comprehensive theoretical framework for analyzing single-particle and collective excitations in vertically stacked quantum dot systems under magnetic fields.

Findings

Demonstrates the influence of confinement potential and magnetic field on excitations.

Highlights the significance of VSQD systems in quantum computation.

Proposes magnetoplasmon qubits for quantum information transfer.

Abstract

A theoretical investigation has been made of the magnetoplasmon excitations in a quasi-one-dimensional electron system comprised of vertically stacked, self-assembled InAs/GaAs quantum dots. The smaller length scales involved in the experiments impel us to consider a perfectly periodic system of two-dimensionally confined InAs quantum dot layers separated by GaAs spacers. Subsequent system is subjected to a two-dimensional confining (harmonic) potential in the x-y plane and an applied magnetic field (B) in the symmetric gauge. This scheme defines virtually a system of quantum wire comprised of vertically stacked quantum dots (VSQD). We derive and discuss the Dyson equation, the generalized (nonlocal and dynamic) dielectric function, and the inverse dielectric function for investigating the single-particle and collective (magnetoplasmon) excitations within the framework of (full) random-phase approximation (RPA). As an application, we study the influence of the confinement potential and the magnetic field on the component eigenfunctions, the density of states (DOS), the Fermi energy, the collective excitations, and the inverse dielectric functions. These findings demonstrate, for the very first time, the significance of investigating the system of VSQD subjected to a quantizing magnetic field. Given the edge over the planar quantum dots and the foreseen applications in the single-electron devices and quantum computation, investigating the system of VSQD is deemed vital. The results suggest exploiting magnetoplasmon qubits to be a potential option for implementing the solemn idea of quantum state transfer in devising quantum gates for the quantum computation and quantum communication networks.