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Boundary Modes from Periodic Magnetic and Pseudomagnetic Fields in Graphene

Võ Tiến Phong, E. J. Melé

2022Physical Review Letters35 citationsDOIOpen Access PDF

Abstract

Single-layer graphene subject to periodic lateral strains is an artificial crystal that can support boundary spectra with an intrinsic polarity. This is analyzed by comparing the effects of periodic magnetic fields and strain-induced pseudomagnetic fields that, respectively, break and preserve time-reversal symmetry. In the former case, a Chern classification of the superlattice minibands with zero total magnetic flux enforces single counterpropagating modes traversing each bulk gap on opposite boundaries of a nanoribbon. For the pseudomagnetic field, pairs of counterpropagating modes migrate to the same boundary where they provide well-developed valley-helical transport channels on a single zigzag edge. We discuss possible schemes for implementing this situation and their experimental signatures.

Topics & Concepts

ZigzagCondensed matter physicsPhysicsSuperlatticeGraphenePolarity (international relations)Magnetic fieldSymmetry (geometry)Periodic potentialBoundary (topology)Quantum mechanicsGeometryBiologyCellMathematicsGeneticsMathematical analysisGraphene research and applicationsTopological Materials and PhenomenaQuantum and electron transport phenomena
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