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Half-Integer Quantized Topological Response in Quasiperiodically Driven Quantum Systems

Philip J. D. Crowley, Ivar Martin, Anushya Chandran

2020Physical Review Letters38 citationsDOIOpen Access PDF

Abstract

A spin strongly driven by two harmonic incommensurate drives can pump energy from one drive to the other at a quantized average rate, in close analogy with the quantum Hall effect. The pumping rate is a nonzero integer in the topological regime, while the trivial regime does not pump. The dynamical transition between the regimes is sharp in the zero-frequency limit and is characterized by a Dirac point in a synthetic band structure. We show that the pumping rate is half-integer quantized at the transition and present universal Kibble-Zurek scaling functions for energy transfer processes. Our results adapt ideas from quantum phase transitions, quantum information, and topological band theory to nonequilibrium dynamics, and identify qubit experiments to observe the universal linear and nonlinear response of a Dirac point in synthetic dimensions.

Topics & Concepts

PhysicsTopology (electrical circuits)Zero-point energyQuantum mechanicsScalingQuantum Hall effectQuantumQubitQuantum phase transitionSpin (aerodynamics)Integer (computer science)Topological entropy in physicsTopological quantum numberMathematicsElectronComputer scienceProgramming languageThermodynamicsCombinatoricsGeometryTopological Materials and PhenomenaQuantum many-body systemsQuantum and electron transport phenomena
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