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Ultra-strong spin–orbit coupling and topological moiré engineering in twisted ZrS2 bilayers

Martin Claassen, Lede Xian, Dante M. Kennes, Ángel Rubio

2022Nature Communications36 citationsDOIOpen Access PDF

Abstract

Abstract We predict that twisted bilayers of 1T-ZrS 2 realize a novel and tunable platform to engineer two-dimensional topological quantum phases dominated by strong spin-orbit interactions. At small twist angles, ZrS 2 heterostructures give rise to an emergent and twist-controlled moiré Kagome lattice, combining geometric frustration and strong spin-orbit coupling to give rise to a moiré quantum spin Hall insulator with highly controllable and nearly-dispersionless bands. We devise a generic pseudo-spin theory for group-IV transition metal dichalcogenides that relies on the two-component character of the valence band maximum of the 1T structure at Γ, and study the emergence of a robust quantum anomalous Hall phase as well as possible fractional Chern insulating states from strong Coulomb repulsion at fractional fillings of the topological moiré Kagome bands. Our results establish group-IV transition metal dichalcogenide bilayers as a novel moiré platform to realize strongly-correlated topological phases in a twist-tunable setting.

Topics & Concepts

Condensed matter physicsTopological insulatorTopological orderPhysicsTopology (electrical circuits)QuantumQuantum mechanicsMathematicsCombinatoricsTopological Materials and Phenomena2D Materials and ApplicationsAdvanced Condensed Matter Physics
Ultra-strong spin–orbit coupling and topological moiré engineering in twisted ZrS2 bilayers | Litcius