Ground-state-entanglement bound for quantum energy teleportation of general spin-chain models

Hotta, Masahiro

doi:10.1103/physreva.87.032313

Cited by 3 publications

(1 citation statement)

References 24 publications

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“…That would imply that (16) is the strongest possible bound on the energy to the right of x 0 . If you start with an excited state, this tells you the maximum amount of energy extractable from that region (without using classical communication to teleport information [65][66][67]).…”

Section: Quantum Field Theorymentioning

confidence: 99%

Lower Bound on the Energy Density in Classical and Quantum Field Theories

Wall

2017

Phys. Rev. Lett.

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A novel method for deriving energy conditions in stable field theories is described. In a local classical theory with one spatial dimension, a local energy condition always exists. For a relativistic field theory, one obtains the dominant energy condition. In a quantum field theory, there instead exists a quantum energy condition, i.e. a lower bound on the energy density that depends on information-theoretic quantities. Some extensions to higher dimensions are briefly discussed.

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Section: Quantum Field Theorymentioning

confidence: 99%

Lower Bound on the Energy Density in Classical and Quantum Field Theories

Wall

2017

Phys. Rev. Lett.

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Investigating global and topological orders of states by local measurement and classical communication: Study on SPT phase diagrams by quantum energy teleportation

Ikeda

2023

AVS Quantum Science

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Distinguishing non-local orders, including global and topological orders of states through solely local operations and classical communications (LOCC), is a highly non-trivial and challenging task since the topology of states is determined by the global characteristics of the many-body system, such as the system's symmetry and the topological space it is based on. Here, we report that we reproduced the phase diagram of Ising model and symmetry protected topological phases using the quantum energy teleportation protocol, which foresees non-trivial energy transfer between remote observers using the entanglement nature of the ground state and LOCC. The model we use includes the Haldane model, the AKLT model, and the Kitaev model. Therefore, our method paves a new general experimental framework to determine and quantify phase transitions in various condensed matter physics and statistical mechanics.

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Quantum Transport in the Markovian and Non-Markovian Environment

Xie

Wang

2013

Mod. Phys. Lett. B

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In this paper, we report on a detailed study of how decoherence assists quantum transport in a dimer system. By carrying out analytical and numerical computations, we find that the decoherence induced by a Markovian (memoryless) environment only assists the maximum probability of quantum transport in the dimer system to 50% not close to the unity, and the decoherence induced by a non-Markovian environment with perfect memory (infinite memory time) can improve the maximum probability of quantum transport to unity. The combination of non-Markovian decoherence and Markovian decoherence assist the quantum transport more effectively. Comparing the classical environment with the quantum environment, we obtain that the classical non-Markovian environment cannot assist the maximum probability of quantum transport close to unity. In addition, enlarging the quantum environment can improve the maximum probability of quantum transport.

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Ground-state-entanglement bound for quantum energy teleportation of general spin-chain models

Cited by 3 publications

References 24 publications

Lower Bound on the Energy Density in Classical and Quantum Field Theories

Lower Bound on the Energy Density in Classical and Quantum Field Theories

Investigating global and topological orders of states by local measurement and classical communication: Study on SPT phase diagrams by quantum energy teleportation

Quantum Transport in the Markovian and Non-Markovian Environment

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