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Quantum Simulation for Three-Dimensional Chiral Topological Insulator

Wentao Ji, Lin Zhang, Mengqi Wang, Long Zhang, Yuhang Guo, Zihua Chai, Xing Rong, Fazhan Shi, Xiong-Jun Liu, Ya Wang, Jiangfeng Du

2020Physical Review Letters54 citationsDOIOpen Access PDF

Abstract

Quantum simulation, as a state-of-the-art technique, provides a powerful way to explore topological quantum phases beyond natural limits. Nevertheless, it is usually hard to simulate both the bulk and surface topological physics at the same time to reveal their correspondence. Here we build up a quantum simulator using nitrogen-vacancy center to investigate a three-dimensional (3D) chiral topological insulator, and demonstrate the study of both the bulk and surface topological physics by quantum quenches. First, a dynamical bulk-surface correspondence in momentum space is observed, showing that the bulk topology of the 3D phase uniquely corresponds to the nontrivial quench dynamics emerging on 2D momentum hypersurfaces called band inversion surfaces (BISs). This is the momentum-space counterpart of the bulk-boundary correspondence in real space. Further, the symmetry protection of the 3D chiral phase is uncovered by measuring dynamical spin textures on BISs, which exhibit perfect (broken) topology when the chiral symmetry is preserved (broken). Finally, we measure the topological charges to characterize directly the bulk topology and identify an emergent dynamical topological transition when varying the quenches from deep to shallow regimes. This work demonstrates how a full study of topological phases can be achieved in quantum simulators.

Topics & Concepts

Topological insulatorPhysicsQuantumQuantum simulatorTheoretical physicsQuantum mechanicsTopology (electrical circuits)Quantum computerMathematicsCombinatoricsTopological Materials and PhenomenaQuantum many-body systemsQuantum and electron transport phenomena
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