Tuning the quantum Mpemba effect in an isolated system by initial-state engineering
Yi-Han Yu, Tian‐Ren Jin, L. M. Zhang, Kai Xu, Heng Fan
Abstract
We investigate the quantum Mpemba effect (QME) in isolated, non-integrable quantum systems, where relaxation dynamics depend on structure of the initial states. By analyzing the distribution of initial states across symmetrical subspaces, we identify a tunable mechanism that influences the emergence of QME, showing faster relaxation from certain out-of-equilibrium states. Additionally, we propose an experimentally realizable quantum circuit, which requires no complex controls on quantum simulator platforms and serves to verify our theoretical predictions. These results establish symmetry-resolved state engineering as a practical tool for manipulating non-equilibrium quantum dynamics.
Topics & Concepts
QuantumPhysicsQuantum systemRelaxation (psychology)Statistical physicsQuantum dynamicsQuantum stateQuantum mechanicsState (computer science)Quantum processOpen quantum systemQuantum operationQuantum sensorComputer scienceMechanism (biology)Quantum computerQuantum networkQuantum error correctionDynamics (music)Quantum algorithmQuantum dissipationQuantum informationDistribution (mathematics)Quantum simulatorQuantum technologyQuantum key distributionQuantum fluctuationQuantum many-body systemsQuantum Computing Algorithms and ArchitectureQuantum and electron transport phenomena