Mass-profile quantum dots in graphene

TL;DR

This paper explores the spectral properties of mass-profile quantum dots in graphene, examining effects of magnetic fields, comparing with potential-well dots, and analyzing arrays for excitonic and many-body phenomena.

Contribution

It introduces a detailed analysis of mass-profile quantum dots in graphene, highlighting advantages for optical applications and the potential for many-body states in dot arrays.

Findings

Rich spectral features depending on dot size and magnetic field

Mass confinement offers advantages for THz and infrared optics

Array analysis reveals exciton hosting and Bose-Hubbard model potential

Abstract

We analyze the bound-state spectra of mass-profile quantum dots in graphene, a system at current experimental reach. Homogeneous perpendicular magnetic fields are also considered which result in breaking the valley degeneracy. The spectra show rich features, arising from the chiral band structure of graphene and its Landau levels and we identify three different regimes depending on the ratio between the radius of the dot and the magnetic length. We further carry out a comparison with potential-well quantum dots discussed in [Recher et al, Phys. Rev. B 79, 085407 (2009)] and conclude that mass confinement may offer significant advantages for optical applications in the THz and infrared regime. Also due to experimental advances, we additionally analyze the band structure of a linear chain of mass-profile quantum dots, where overlap-assisted hopping processes play a main role for closely packed arrays. Here, the inclusion of Coulomb interactions shows that Frenkel excitons can be hosted by the system for certain values of the lattice constant. A Bose-Hubbard model can be mimicked under such a choice of the distance between the dots.