Sublattice symmetry breaking and Kondo-effect enhancement in strained graphene

TL;DR

This paper proposes using mechanical strains in graphene to enhance and detect the Kondo effect by amplifying local density of states changes, making it more observable with local probes like STM.

Contribution

It introduces a method of strain engineering in graphene to amplify Kondo temperature signals, facilitating experimental detection of the Kondo effect in this material.

Findings

Strain-induced LDOS changes can exponentially affect Kondo temperature.

Top-site adsorption configurations show higher Kondo temperatures under strain.

Strain geometries like bubbles and folds produce distinctive LDOS patterns.

Abstract

Kondo physics in doped monolayer graphene is predicted to exhibit unusual features due to the linear vanishing of the pristine material's density of states at the Dirac point. Despite several attempts, conclusive experimental observation of the phenomenon remains elusive. One likely obstacle to identification is a very small Kondo temperature scale $T_K$ in situations where the chemical potential lies near the Dirac point. We propose tailored mechanical deformations of monolayer graphene as a means of revealing unique fingerprints of the Kondo effect. Inhomogeneous strains are known to produce specific alternating changes in the local density of states (LDOS) away from the Dirac point that signal sublattice symmetry breaking effects. Small LDOS changes can be amplified in an exponential increase or decrease of $T_K$ for magnetic impurities attached at different locations. We illustrate this behavior in two deformation geometries: a circular 'bubble' and a long fold, both described by Gaussian displacement profiles. We calculate the LDOS changes for modest strains and analyze the relevant Anderson impurity model describing a magnetic atom adsorbed in either a 'top-site' or a 'hollow-site' configuration. Numerical renormalization-group solutions of the impurity model suggest that higher expected $T_K$ values, combined with distinctive spatial patterns under variation of the point of graphene attachment, make the top-site configuration the more promising for experimental observation of signatures of the Kondo effect. The strong strain sensitivity of $T_K$ may lift top-site Kondo physics into the range experimentally accessible using local probes such as scanning tunneling microscopy.