Quantum Markov Order

Philip Taranto; Felix A. Pollock; Simon Milz; Marco Tomamichel; Kavan Modi

doi:10.1103/physrevlett.122.140401

Quantum Markov Order

Philip Taranto, Felix A. Pollock, Simon Milz, Marco Tomamichel, Kavan Modi

Theoretical Physics Group

Research output: Contribution to journal › Article › peer-review

Abstract

We formally extend the notion of Markov order to open quantum processes by accounting for the instruments used to probe the system of interest at different times. Our description recovers the classical property in the appropriate limit: when the stochastic process is classical and the instruments are noninvasive, i.e., restricted to orthogonal, projective measurements. We then prove that there do not exist non-Markovian quantum processes that have finite Markov order with respect to all possible instruments; the same process exhibits distinct memory effects when probed by different instruments. This naturally leads to a relaxed definition of quantum Markov order with respect to specified instrument sequences. The memory effects captured by different choices of instruments vary dramatically, providing a rich landscape for future exploration.

Original language	English
Article number	140401
Number of pages	6
Journal	Physical Review Letters
Volume	122
DOIs	https://doi.org/10.1103/physrevlett.122.140401
Publication status	Published - 9 Apr 2019

Keywords

Open quantum systems & decoherence
Quantum formalism

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10.1103/physrevlett.122.140401

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title = "Quantum Markov Order",

abstract = "We formally extend the notion of Markov order to open quantum processes by accounting for the instruments used to probe the system of interest at different times. Our description recovers the classical property in the appropriate limit: when the stochastic process is classical and the instruments are noninvasive, i.e., restricted to orthogonal, projective measurements. We then prove that there do not exist non-Markovian quantum processes that have finite Markov order with respect to all possible instruments; the same process exhibits distinct memory effects when probed by different instruments. This naturally leads to a relaxed definition of quantum Markov order with respect to specified instrument sequences. The memory effects captured by different choices of instruments vary dramatically, providing a rich landscape for future exploration.",

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AU - Pollock, Felix A.

AU - Milz, Simon

AU - Tomamichel, Marco

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AB - We formally extend the notion of Markov order to open quantum processes by accounting for the instruments used to probe the system of interest at different times. Our description recovers the classical property in the appropriate limit: when the stochastic process is classical and the instruments are noninvasive, i.e., restricted to orthogonal, projective measurements. We then prove that there do not exist non-Markovian quantum processes that have finite Markov order with respect to all possible instruments; the same process exhibits distinct memory effects when probed by different instruments. This naturally leads to a relaxed definition of quantum Markov order with respect to specified instrument sequences. The memory effects captured by different choices of instruments vary dramatically, providing a rich landscape for future exploration.

KW - Open quantum systems & decoherence

KW - Quantum formalism

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VL - 122

JO - Physical Review Letters

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ER -

Quantum Markov Order

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