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Experimental Verification of Dissipation-Time Uncertainty Relation

L.-L. Yan, Jiawei Zhang, M.-R. Yun, J.-C. Li, G.-Y. Ding, J.-F. Wei, J.-T. Bu, B. Wang, Liang Chen, Shi‐Lei Su, Fei Zhou, Ya Jia, Erjun Liang, Mang Feng

2022Physical Review Letters34 citationsDOI

Abstract

Dissipation is vital to any cyclic process in realistic systems. Recent research focus on nonequilibrium processes in stochastic systems has revealed a fundamental trade-off, called dissipation-time uncertainty relation, that entropy production rate associated with dissipation bounds the evolution pace of physical processes [Phys. Rev. Lett. 125, 120604 (2020)PRLTAO0031-900710.1103/PhysRevLett.125.120604]. Following the dissipative two-level model exemplified in the same Letter, we experimentally verify this fundamental trade-off in a single trapped ultracold ^{40}Ca^{+} ion using elaborately designed dissipative channels, along with a postprocessing method developed in the data analysis, to build the effective nonequilibrium stochastic evolutions for the energy transfer between two heat baths mediated by a qubit. Since the dissipation-time uncertainty relation imposes a constraint on the quantum speed regarding entropy flux, our observation provides the first experimental evidence confirming such a speed restriction from thermodynamics on quantum operations due to dissipation, which helps us further understand the role of thermodynamical characteristics played in quantum information processing.

Topics & Concepts

Dissipative systemDissipationEntropy productionNon-equilibrium thermodynamicsPhysicsStatistical physicsQuantumEntropy (arrow of time)Stochastic processQuantum mechanicsMathematicsStatisticsAdvanced Thermodynamics and Statistical MechanicsQuantum Mechanics and ApplicationsQuantum Information and Cryptography