Litcius/Paper detail

Upstream modes and antidots poison graphene quantum Hall effect

N. Moreau, B. Brun, S. Somanchi, K. Watanabe, T. Taniguchi, C. Stampfer, B. Hackens

2021Nature Communications24 citationsDOIOpen Access PDF

Abstract

The quantum Hall effect is the seminal example of topological protection, as charge carriers are transmitted through one-dimensional edge channels where backscattering is prohibited. Graphene has made its marks as an exceptional platform to reveal new facets of this remarkable property. However, in conventional Hall bar geometries, topological protection of graphene edge channels is found regrettably less robust than in high mobility semi-conductors. Here, we explore graphene quantum Hall regime at the local scale, using a scanning gate microscope. We reveal the detrimental influence of antidots along the graphene edges, mediating backscattering towards upstream edge channels, hence triggering topological breakdown. Combined with simulations, our experimental results provide further insights into graphene quantum Hall channels vulnerability. In turn, this may ease future developments towards precise manipulation of topologically protected edge channels hosted in various types of two-dimensional crystals.

Topics & Concepts

GrapheneQuantum Hall effectPhysicsEnhanced Data Rates for GSM EvolutionCondensed matter physicsUpstream (networking)Charge (physics)QuantumTopology (electrical circuits)Quantum spin Hall effectGraphene nanoribbonsHall effectLandau quantizationQuantum point contactScanning gate microscopyElectron mobilityQuantum computerFractional quantum Hall effectGraphene research and applicationsTopological Materials and PhenomenaQuantum and electron transport phenomena