Adaptive recurrence quantum entanglement distillation for two-Kraus-operator channels

Ruan, Liangzhong; Dai, Wenhan; Win, Moe Z.

doi:10.1103/physreva.97.052332

Cited by 31 publications

(10 citation statements)

References 57 publications

(143 reference statements)

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“…These gates inherently generate a series of errors, specifically, three types: bit flip (X-errors), phase flip (Z-errors, or phase damping), and bit-phase flip [45]. The aforementioned link will also allow a better understanding of aspects related to decoherence [14,15] in non-adiabatic environments, as well as a very common process present in all real quantum channels known as the amplitude damping [46].…”

Section: Discussionmentioning

confidence: 99%

On the spectral nature of entanglement

Mastriani

2021

IET Quantum Communication

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This study establishes, for the first time in literature, that quantum entanglement, as well as the most important protocol derived from it, that is, quantum teleportation, completely rest on the Quantum Fourier Transform. This highlights the spectral nature of both protocols with important consequences on quantum computing, quantum communications, and quantum cryptography, with a particular emphasis on quantum Internet. This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

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Section: Discussionmentioning

confidence: 99%

On the spectral nature of entanglement

Mastriani

2021

IET Quantum Communication

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“…We note that it has been recently shown that the DE-JMPS protocol achieves the highest possible fidelity over LOCC operations when distilling a two-qubit state from two copies of a Bell diagonal state of rank two [42]. Moreover, in [41] protocols that permute Bell states in the mixture were analyzed and it was claimed that for two copies of all Bell diagonal states, DEJMPS protocol achieves the highest achievable fidelity when distilling a two-qubit state, but only among all such permuting protocols.…”

Section: B Bell Diagonal Statesmentioning

confidence: 85%

Optimizing practical entanglement distillation

et al. 2018

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The goal of entanglement distillation is to turn a large number of weakly entangled states into a smaller number of highly entangled ones. Practical entanglement distillation schemes offer a tradeoff between the fidelity to the target state, and the probability of successful distillation. Exploiting such tradeoffs is of interest in the design of quantum repeater protocols. Here, we present a number of methods to assess and optimize entanglement distillation schemes. We start by giving a numerical method to compute upper bounds on the maximum achievable fidelity for a desired probability of success. We show that this method performs well for many known examples by comparing it to well-known distillation protocols. This allows us to show optimality for many well-known distillation protocols for specific states of interest. As an example, we analytically prove optimality of the distillation protocol utilized within the Extreme Photon Loss (EPL) entanglement generation scheme, even in the asymptotic limit. We proceed to present a numerical method that can improve an existing distillation scheme for a given input state, and we present an example for which this method finds an optimal distillation protocol. An implementation of our numerical methods is available as a Julia package. * These authors contributed equally;Electronic address: f.d.rozpedek@tudelft.nl

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“…Furthermore, sophisticated quantum repeater protocols need to be developed for mitigating the errors introduced by the channels, which may be partly addressed through quantum error correction codes. In the absence of coding, the losses may be dealt with by heralded entanglement generation, while the error probability may be reduced by entanglement distillation (see e.g., [29]). Despite all these potential approaches, practical realization of quantum repeaters remains an open technical challenge.…”

Section: Entanglement Distribution and Quantum Networkingmentioning

confidence: 99%