Friedel oscillations in a two-dimensional electron gas and monolayer graphene with a non-Coulomb impurity potential

Abstract

We study Friedel oscillations in a two-dimensional non-interacting electron gas and in a monolayer graphene in the presence of a single impurity. The potential generated by the impurity is modeled using a non-Coulomb interaction ( r-η). The charge carrier density deviation as a function of distance from the impurity is calculated within the linear response theory. Our results show that, in both a two-dimensional non-interacting electron gas and graphene, the phase of charge carrier density oscillations remains unaffected by the parameter η, which characterizes the non-Coulomb nature of the interaction, at large distances from the impurity. The parameter η influences only the amplitude of the oscillations in this regime. The results for an impurity modeled by Coulomb-like potential (η = 1) are recovered in both cases.