Space charge and screening of a supercritical impurity cluster in monolayer graphene

Abstract

Coulomb impurity of charge Ze is known to destabilize the ground state of undoped graphene with respect to creation of screening space charge if Z exceeds a critical value of 1/2α set by material's fine structure constant α. Recent experimental advances made it possible to explore this transition in a controlled manner by tuning Z across the critical point. Combined with relatively large value of α this opens a possibility to study graphene's screening response to a supercritical impurity Zα1 when the screening charge is large, and the Thomas-Fermi analysis, that we revisit, is adequate. The character of screening in this regime is controlled by the dimensionless screening parameter Zα2. Specifically, for circular impurity cluster most of the screening charge in the weak-screening regime Zα21 is found to reside outside the cluster. The strong-screening regime Zα21 provides a realization of the Thomson atom: most of the screening charge is inside the cluster nearly perfectly neutralizing the source charge with the exception of a transition layer near cluster's edge where the rest of the space charge is localized.