Scanning gate microscopy in graphene nanostructures

TL;DR

This paper systematically studies how scanning gate microscopy affects the conductance of graphene nanostructures, revealing perturbative and non-perturbative effects, and providing insights into conductance quantization and edge state behavior.

Contribution

It introduces a scattering approach to explicitly calculate conductance corrections due to a scanning tip in graphene nanostructures, including non-perturbative effects and resonance phenomena.

Findings

Second-order conductance correction dominates in plateaus.

Resonances appear from trapped states under strong tips.

Edge states can be destroyed by intervalley coupling.

Abstract

The conductance of graphene nanoribbons and nanoconstrictions under the effect of a scanning gate microscopy tip is systematically studied. Using a scattering approach for noninvasive probes, the first- and second-order conductance corrections caused by the tip potential disturbance are expressed explicitly in terms of the scattering states of the unperturbed structure. Numerical calculations confirm the perturbative results, showing that the second-order term prevails in the conductance plateaus, exhibiting a universal scaling law for armchair graphene strips. For stronger tips, at specific probe potential widths and strengths beyond the perturbative regime, the conductance corrections reveal the appearance of resonances originated from states trapped below the tip. The zero-transverse-energy mode of an armchair metallic strip is shown to be insensitive to the long-range electrostatic potential of the probe. For nanoconstrictions defined on a strip, scanning gate microscopy allows to get insight into the breakdown of conductance quantization. The first-order correction generically dominates at low tip strength, while for Fermi energies associated with faint conductance plateaus, the second-order correction becomes dominant for relatively small potential tip strengths. In accordance with the spatial dependence of the partial local density of states, the largest tip effect occurs in the central part of the constriction, close to the edges. Nanoribbons and nanoconstrictions with zigzag edges exhibit a similar response as in the case of armchair nanostructures, except when the intervalley coupling induced by the tip potential destroys the chiral edge states.