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Topological phase transition in chiral graphene nanoribbons: from edge bands to end states

Jingcheng Li, Sofia Sanz, Nestor Merino-Díez, Manuel Vilas-Varela, Aran Garcia-Lekue, Martina Corso, Dimas G. de Oteyza, Thomas Frederiksen, Diego Peña, Jose Ignacio Pascual

2021Nature Communications137 citationsDOIOpen Access PDF

Abstract

Precise control over the size and shape of graphene nanostructures allows engineering spin-polarized edge and topological states, representing a novel source of non-conventional π-magnetism with promising applications in quantum spintronics. A prerequisite for their emergence is the existence of robust gapped phases, which are difficult to find in extended graphene systems. Here we show that semi-metallic chiral GNRs (chGNRs) narrowed down to nanometer widths undergo a topological phase transition. We fabricated atomically precise chGNRs of different chirality and size by on surface synthesis using predesigned molecular precursors. Combining scanning tunneling microscopy (STM) measurements and theory simulations, we follow the evolution of topological properties and bulk band gap depending on the width, length, and chirality of chGNRs. Our findings represent a new platform for producing topologically protected spin states and demonstrate the potential of connecting chiral edge and defect structure with band engineering.

Topics & Concepts

Chirality (physics)GrapheneScanning tunneling microscopeTopology (electrical circuits)Materials sciencePhase (matter)Topological orderEnhanced Data Rates for GSM EvolutionBand gapCondensed matter physicsQuantum tunnellingNanostructureGraphene nanoribbonsTopological defectQuantumSpin (aerodynamics)PhysicsPhase transitionSurface (topology)Surface statesNanotechnologyGeometric phaseScanning tunneling spectroscopyQuantum dotSpin polarized scanning tunneling microscopyNanometreQuantum phasesElectronic band structureTopological Materials and PhenomenaGraphene research and applicationsSurface Chemistry and Catalysis
Topological phase transition in chiral graphene nanoribbons: from edge bands to end states | Litcius