Litcius/Paper detail

Exploring 2D Synthetic Quantum Hall Physics with a Quasiperiodically Driven Qubit

Eric Boyers, Philip J. D. Crowley, Anushya Chandran, Alexander O. Sushkov

2020Physical Review Letters52 citationsDOIOpen Access PDF

Abstract

Quasiperiodically driven quantum systems are predicted to exhibit quantized topological properties, in analogy with the quantized transport properties of topological insulators. We use a single nitrogen-vacancy center in diamond to experimentally study a synthetic quantum Hall effect with a two-tone drive. We measure the evolution of trajectories of two quantum states, initially prepared at nearby points in synthetic phase space. We detect the synthetic Hall effect through the predicted overlap oscillations at a quantized fundamental frequency proportional to the Chern number, which characterizes the topological phases of the system. We further observe half-quantization of the Chern number at the transition between the synthetic Hall regime and the trivial regime, and the associated concentration of local Berry curvature in synthetic phase space. Our Letter opens up the possibility of using driven qubits to design and study higher-dimensional topological insulators and semimetals in synthetic dimensions.

Topics & Concepts

Berry connection and curvaturePhysicsQuantum Hall effectQubitTopology (electrical circuits)Topological insulatorQuantum mechanicsQuantization (signal processing)Geometric phaseChern classPhase spaceQuantum spin Hall effectQuantumElectronMathematicsGeometryAlgorithmCombinatoricsTopological Materials and PhenomenaQuantum and electron transport phenomenaGraphene research and applications