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Bias-Free Access to Orbital Angular Momentum in Two-Dimensional Quantum Materials

Jonas Erhardt, Cédric Schmitt, Philipp Eck, M. Schmitt, Philipp Keßler, Kyungchan Lee, T. K. Kim, Céphise Cacho, Iulia Cojocariu, Daniel Baranowski, Vitaliy Feyer, Louis Veyrat, Giorgio Sangiovanni, R. Claessen, Simon Moser

2024Physical Review Letters10 citationsDOI

Abstract

The demonstration of a topological band inversion constitutes the most elementary proof of a quantum spin Hall insulator (QSHI). On a fundamental level, such an inverted band gap is intrinsically related to the bulk Berry curvature, a gauge-invariant fingerprint of the wave function's quantum geometric properties in Hilbert space. Intimately tied to orbital angular momentum (OAM), the Berry curvature can be, in principle, extracted from circular dichroism in angle-resolved photoemission spectroscopy (CD-ARPES), were it not for interfering final state photoelectron emission channels that obscure the initial state OAM signature. Here, we outline a full-experimental strategy to avoid such interference artifacts and isolate the clean OAM from the CD-ARPES response. Bench-marking this strategy for the recently discovered atomic monolayer system indenene, we demonstrate its distinct QSHI character and establish CD-ARPES as a scalable bulk probe to experimentally classify the topology of two-dimensional quantum materials with time reversal symmetry.

Topics & Concepts

Angle-resolved photoemission spectroscopyPhysicsBerry connection and curvatureTopological insulatorQuantum mechanicsAngular momentumSpin (aerodynamics)Topology (electrical circuits)QuantumCondensed matter physicsElectronic structureCombinatoricsMathematicsThermodynamicsTopological Materials and PhenomenaGraphene research and applications2D Materials and Applications
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