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Magnetoconductance, Quantum Hall Effect, and Coulomb Blockade in Topological Insulator Nanocones

Raphael Kozlovsky, Ansgar Graf, Denis Kochan, Klaus Richter, Cosimo Gorini

2020Physical Review Letters22 citationsDOIOpen Access PDF

Abstract

Magnetotransport through cylindrical topological insulator (TI) nanowires is governed by the interplay between quantum confinement and geometric (Aharonov-Bohm and Berry) phases. Here, we argue that the much broader class of TI nanowires with varying radius-for which a homogeneous coaxial magnetic field induces a varying Aharonov-Bohm flux that gives rise to a nontrivial masslike potential along the wire-is accessible by studying its simplest member, a TI nanocone. Such nanocones allow us to observe intriguing mesoscopic transport phenomena: While the conductance in a perpendicular magnetic field is quantized due to higher-order topological hinge states, it shows resonant transmission through Dirac Landau levels in a coaxial magnetic field. Furthermore, it may act as a quantum magnetic bottle, confining surface Dirac electrons and leading to a largely interaction-dominated regime of Coulomb blockade type. We show numerically that the above-mentioned effects occur for experimentally accessible values of system size and magnetic field, suggesting that TI nanocone junctions may serve as building blocks for Dirac electron optics setups.

Topics & Concepts

Mesoscopic physicsPhysicsTopological insulatorCondensed matter physicsMagnetic fieldBerry connection and curvatureQuantum Hall effectLandau quantizationElectronAharonov–Bohm effectTopology (electrical circuits)Coulomb blockadeDirac (video compression format)NanowireQuantum mechanicsGeometric phaseMathematicsVoltageNeutrinoTransistorCombinatoricsTopological Materials and PhenomenaQuantum and electron transport phenomenaGraphene research and applications
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