Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups

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Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups. / Bardet, Ivan; Junge, Marius; Laracuente, Nicholas; Rouze, Cambyse; Franca, Daniel Stilck.

In: IEEE Transactions on Information Theory, Vol. 67, No. 5, 9376918, 2021, p. 2878-2909.

Research output: Contribution to journalJournal articleResearchpeer-review

Harvard

Bardet, I, Junge, M, Laracuente, N, Rouze, C & Franca, DS 2021, 'Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups', IEEE Transactions on Information Theory, vol. 67, no. 5, 9376918, pp. 2878-2909. https://doi.org/10.1109/TIT.2021.3065452

APA

Bardet, I., Junge, M., Laracuente, N., Rouze, C., & Franca, D. S. (2021). Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups. IEEE Transactions on Information Theory, 67(5), 2878-2909. [9376918]. https://doi.org/10.1109/TIT.2021.3065452

Vancouver

Bardet I, Junge M, Laracuente N, Rouze C, Franca DS. Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups. IEEE Transactions on Information Theory. 2021;67(5):2878-2909. 9376918. https://doi.org/10.1109/TIT.2021.3065452

Author

Bardet, Ivan ; Junge, Marius ; Laracuente, Nicholas ; Rouze, Cambyse ; Franca, Daniel Stilck. / Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups. In: IEEE Transactions on Information Theory. 2021 ; Vol. 67, No. 5. pp. 2878-2909.

Bibtex

@article{30cd1c9511294aee8a54bc025deff0b8,
title = "Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups",
abstract = "Capacities of quantum channels and decoherence times both quantify the extent to which quantum information can withstand degradation by interactions with its environment. However, calculating capacities directly is known to be intractable in general. Much recent work has focused on upper bounding certain capacities in terms of more tractable quantities such as specific norms from operator theory. In the meantime, there has also been substantial recent progress on estimating decoherence times with techniques from analysis and geometry, even though many hard questions remain open. In this article, we introduce a class of continuous-time quantum channels that we called transferred channels, which are built through representation theory from a classical Markov kernel defined on a compact group. In particular, we study two subclasses of such kernels: H{\"o}rmander systems on compact Lie-groups and Markov chains on finite groups. Examples of transferred channels include the depolarizing channel, the dephasing channel, and collective decoherence channels acting on d qubits. Some of the estimates presented are new, such as those for channels that randomly swap subsystems. We then extend tools developed in earlier work by Gao, Junge and LaRacuente to transfer estimates of the classical Markov kernel to the transferred channels and study in this way different non-commutative functional inequalities. The main contribution of this article is the application of this transference principle to the estimation of decoherence time, of private and quantum capacities, of entanglement-assisted classical capacities as well as estimation of entanglement breaking times, defined as the first time for which the channel becomes entanglement breaking. Moreover, our estimates hold for non-ergodic channels such as the collective decoherence channels, an important scenario that has been overlooked so far because of a lack of techniques.",
keywords = "functional analysis, information entropy, Quantum capacitance, quantum entanglement",
author = "Ivan Bardet and Marius Junge and Nicholas Laracuente and Cambyse Rouze and Franca, {Daniel Stilck}",
year = "2021",
doi = "10.1109/TIT.2021.3065452",
language = "English",
volume = "67",
pages = "2878--2909",
journal = "IEEE Transactions on Information Theory",
issn = "0018-9448",
publisher = "Institute of Electrical and Electronics Engineers",
number = "5",

}

RIS

TY - JOUR

T1 - Group Transference Techniques for the Estimation of the Decoherence Times and Capacities of Quantum Markov Semigroups

AU - Bardet, Ivan

AU - Junge, Marius

AU - Laracuente, Nicholas

AU - Rouze, Cambyse

AU - Franca, Daniel Stilck

PY - 2021

Y1 - 2021

N2 - Capacities of quantum channels and decoherence times both quantify the extent to which quantum information can withstand degradation by interactions with its environment. However, calculating capacities directly is known to be intractable in general. Much recent work has focused on upper bounding certain capacities in terms of more tractable quantities such as specific norms from operator theory. In the meantime, there has also been substantial recent progress on estimating decoherence times with techniques from analysis and geometry, even though many hard questions remain open. In this article, we introduce a class of continuous-time quantum channels that we called transferred channels, which are built through representation theory from a classical Markov kernel defined on a compact group. In particular, we study two subclasses of such kernels: Hörmander systems on compact Lie-groups and Markov chains on finite groups. Examples of transferred channels include the depolarizing channel, the dephasing channel, and collective decoherence channels acting on d qubits. Some of the estimates presented are new, such as those for channels that randomly swap subsystems. We then extend tools developed in earlier work by Gao, Junge and LaRacuente to transfer estimates of the classical Markov kernel to the transferred channels and study in this way different non-commutative functional inequalities. The main contribution of this article is the application of this transference principle to the estimation of decoherence time, of private and quantum capacities, of entanglement-assisted classical capacities as well as estimation of entanglement breaking times, defined as the first time for which the channel becomes entanglement breaking. Moreover, our estimates hold for non-ergodic channels such as the collective decoherence channels, an important scenario that has been overlooked so far because of a lack of techniques.

AB - Capacities of quantum channels and decoherence times both quantify the extent to which quantum information can withstand degradation by interactions with its environment. However, calculating capacities directly is known to be intractable in general. Much recent work has focused on upper bounding certain capacities in terms of more tractable quantities such as specific norms from operator theory. In the meantime, there has also been substantial recent progress on estimating decoherence times with techniques from analysis and geometry, even though many hard questions remain open. In this article, we introduce a class of continuous-time quantum channels that we called transferred channels, which are built through representation theory from a classical Markov kernel defined on a compact group. In particular, we study two subclasses of such kernels: Hörmander systems on compact Lie-groups and Markov chains on finite groups. Examples of transferred channels include the depolarizing channel, the dephasing channel, and collective decoherence channels acting on d qubits. Some of the estimates presented are new, such as those for channels that randomly swap subsystems. We then extend tools developed in earlier work by Gao, Junge and LaRacuente to transfer estimates of the classical Markov kernel to the transferred channels and study in this way different non-commutative functional inequalities. The main contribution of this article is the application of this transference principle to the estimation of decoherence time, of private and quantum capacities, of entanglement-assisted classical capacities as well as estimation of entanglement breaking times, defined as the first time for which the channel becomes entanglement breaking. Moreover, our estimates hold for non-ergodic channels such as the collective decoherence channels, an important scenario that has been overlooked so far because of a lack of techniques.

KW - functional analysis

KW - information entropy

KW - Quantum capacitance

KW - quantum entanglement

U2 - 10.1109/TIT.2021.3065452

DO - 10.1109/TIT.2021.3065452

M3 - Journal article

AN - SCOPUS:85102697913

VL - 67

SP - 2878

EP - 2909

JO - IEEE Transactions on Information Theory

JF - IEEE Transactions on Information Theory

SN - 0018-9448

IS - 5

M1 - 9376918

ER -

ID: 261382472