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Bounding generalized relative entropies: Nonasymptotic quantum speed limits

Diego Paiva Pires, Kavan Modi, Lucas C. Céleri

2021Physical review. E29 citationsDOIOpen Access PDF

Abstract

Information theory has become an increasingly important research field to better understand quantum mechanics. Noteworthy, it covers both foundational and applied perspectives, also offering a common technical language to study a variety of research areas. Remarkably, one of the key information-theoretic quantities is given by the relative entropy, which quantifies how difficult is to tell apart two probability distributions, or even two quantum states. Such a quantity rests at the core of fields like metrology, quantum thermodynamics, quantum communication, and quantum information. Given this broadness of applications, it is desirable to understand how this quantity changes under a quantum process. By considering a general unitary channel, we establish a bound on the generalized relative entropies (Rényi and Tsallis) between the output and the input of the channel. As an application of our bounds, we derive a family of quantum speed limits based on relative entropies. Possible connections between this family with thermodynamics, quantum coherence, asymmetry, and single-shot information theory are briefly discussed.

Topics & Concepts

Statistical physicsQuantum informationQuantum thermodynamicsQuantum information scienceQuantum channelQuantum metrologyQuantumQuantum relative entropyKullback–Leibler divergenceQuantum discordQuantum mechanicsMathematicsQuantum operationAmplitude damping channelPhysicsOpen quantum systemQuantum networkQuantum entanglementStatisticsStatistical Mechanics and EntropyAdvanced Thermodynamics and Statistical MechanicsQuantum Mechanics and Applications
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