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Design and realization of topological Dirac fermions on a triangular lattice

Maximilian Bauernfeind, Jonas Erhardt, Philipp Eck, P. Thakur, Judith Gabel, Tien‐Lin Lee, J. Schäfer, Simon Moser, Domenico Di Sante, R. Claessen, Giorgio Sangiovanni

2021Nature Communications42 citationsDOIOpen Access PDF

Abstract

Abstract Large-gap quantum spin Hall insulators are promising materials for room-temperature applications based on Dirac fermions. Key to engineer the topologically non-trivial band ordering and sizable band gaps is strong spin-orbit interaction. Following Kane and Mele’s original suggestion, one approach is to synthesize monolayers of heavy atoms with honeycomb coordination accommodated on templates with hexagonal symmetry. Yet, in the majority of cases, this recipe leads to triangular lattices, typically hosting metals or trivial insulators. Here, we conceive and realize “indenene”, a triangular monolayer of indium on SiC exhibiting non-trivial valley physics driven by local spin-orbit coupling, which prevails over inversion-symmetry breaking terms. By means of tunneling microscopy of the 2D bulk we identify the quantum spin Hall phase of this triangular lattice and unveil how a hidden honeycomb connectivity emerges from interference patterns in Bloch p x ± i p y -derived wave functions.

Topics & Concepts

Hexagonal latticeDirac fermionCondensed matter physicsPoint reflectionPhysicsMonolayerFermionTopological insulatorHoneycombLattice (music)Quantum spin Hall effectQuantum Hall effectQuantum mechanicsTopology (electrical circuits)Theoretical physicsMaterials scienceNanotechnologyComposite materialAntiferromagnetismCombinatoricsMathematicsAcousticsElectronTopological Materials and PhenomenaQuantum Mechanics and Non-Hermitian PhysicsGraphene research and applications
Design and realization of topological Dirac fermions on a triangular lattice | Litcius