Effect of nonhomogenous dielectric background on the plasmon modes in graphene double-layer structures at finite temperatures

TL;DR

This study investigates how non-uniform dielectric backgrounds influence plasmon modes in graphene double-layer structures at finite temperatures, revealing significant effects on plasmon energies and potential experimental observability.

Contribution

It introduces a model accounting for dielectric inhomogeneity's impact on plasmon dispersion in graphene double layers at finite temperatures, highlighting new effects on plasmon energies.

Findings

Dielectric inhomogeneity causes notable shifts in plasmon energies.

Temperature amplifies the effects of dielectric inhomogeneity.

Plasmon features are detectable via spectroscopic methods.

Abstract

We have calculated the plasmon modes in graphene double layer structures at finite temperatures, taking into account the inhomogeneity of the dielectric background of the system. The effective dielectric function is obtained from the solution of the Poisson equation of three-layer dielectric medium with the graphene sheets located at the interfaces, separating the different materials. Due to the momentum dispersion of the effective dielectric function, the intra- and inter-layer bare Coulomb interactions in the graphene double layer system acquires an additional momentum dependence--an effect that is of the order of the inter-layer interaction itself. We show that the energies of the in-phase and out-of-phase plasmon modes are determined largely by different values of the spatially dependent effective dielectric function. The effect of the dielectric inhomogeneity increases with temperature and even at high temperatures the energy shift induced by the dielectric inhomogeneity and temperature itself remains larger than the broadening of the plasmon energy dispersions due to the Landau damping. The obtained new features of the plasmon dispersions can be observed in frictional drag measurements and in inelastic light scattering and electron energy-loss spectroscopies.