Quantifying Quantum Correlation of Quasi‐Werner State and Probing Its Suitability for Quantum Teleportation

We study the efficiency of two-qubit mixed entangled states as resources for quantum teleportation. We first consider two maximally entangled mixed states, viz., the Werner state\cite{werner}, and a class of states introduced by Munro {\it et al.} \cite{munro}. We show that the Werner state when used as teleportation channel, gives rise to better average teleportation fidelity compared to the latter class of states for any finite value of mixedness. We then introduce a non-maximally entangled mixed state obtained as a convex combination of a two-qubit entangled mixed state and a two-qubit separable mixed state. It is shown that such a teleportation channel can outperform another non-maximally entangled channel, viz., the Werner derivative for a certain range of mixedness. Further, there exists a range of parameter values where the former state satisfies a Bell-CHSH type inequality and still performs better as a teleportation channel compared to the Werner derivative even though the latter violates the inequality.

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Quantum Correlation Dynamics in Controlled Two-Coupled-Qubit Systems

Entropy ◽

10.3390/e22070785 ◽

2020 ◽

Vol 22 (7) ◽

pp. 785 ◽

Cited By ~ 1

Author(s):

Iulia Ghiu ◽

Roberto Grimaudo ◽

Tatiana Mihaescu ◽

Aurelian Isar ◽

Antonino Messina

Keyword(s):

Time Evolution ◽

Quantum Correlation ◽

Quantum Dynamics ◽

Quantum Discord ◽

Quantum Correlations ◽

Initial State ◽

Analytical Treatment ◽

Werner State ◽

Driven System ◽

Physical Reasons

We study and compare the time evolutions of concurrence and quantum discord in a driven system of two interacting qubits prepared in a generic Werner state. The corresponding quantum dynamics is exactly treated and manifests the appearance and disappearance of entanglement. Our analytical treatment transparently unveils the physical reasons for the occurrence of such a phenomenon, relating it to the dynamical invariance of the X structure of the initial state. The quantum correlations which asymptotically emerge in the system are investigated in detail in terms of the time evolution of the fidelity of the initial Werner state.

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Quantum Teleportation and Super-Dense Coding in Operator Algebras

International Mathematics Research Notices ◽

10.1093/imrn/rnz095 ◽

2019 ◽

Author(s):

Li Gao ◽

Samuel J Harris ◽

Marius Junge

Keyword(s):

Tensor Product ◽

Cyclic Group ◽

Quantum Teleportation ◽

Quantum Correlation ◽

Unitary Operator ◽

Operator Algebras ◽

Dense Coding ◽

C Algebra ◽

The Matrix

Abstract We show for any $d,m\ge 2$ with $(d,m)\neq (2,2)$, the matrix-valued generalization of the (tensor product) quantum correlation set of $d$ inputs and $m$ outputs is not closed. Our argument uses a reformulation of super-dense coding and teleportation in terms of $C^*$-algebra isomorphisms. Namely, we prove that for certain actions of cyclic group ${{\mathbb{Z}}}_d$, \begin{equation*}M_d(C^*({{\mathbb{F}}}_{d^2}))\cong{{\mathcal{B}}}_d\rtimes{{\mathbb{Z}}}_d\rtimes{{\mathbb{Z}}}_d , M_d({{\mathcal{B}}}_d)\cong C^*({{\mathbb{F}}}_{d^2})\rtimes{{\mathbb{Z}}}_d\rtimes{{\mathbb{Z}}}_d,\end{equation*}where ${{\mathcal{B}}}_d$ is the universal unital $C^*$-algebra generated by the elements $u_{jk}, \, 0 \le i, j \le d-1$, satisfying the relations that $[u_{j,k}]$ is a unitary operator, and $C^*({{\mathbb{F}}}_{d^2})$ is the universal $C^*$-algebra of $d^2$ unitaries. These isomorphisms provide a nice connection between the embezzlement of entanglement and the non-closedness of quantum correlation sets.

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Sharing quantum steering among multiple Alices and Bobs via a two-qubit Werner state

Quantum Information Processing ◽

10.1007/s11128-021-03211-z ◽

2021 ◽

Vol 20 (8) ◽

Author(s):

Xinhong Han ◽

Ya Xiao ◽

Huichao Qu ◽

Runhong He ◽

Xuan Fan ◽

...

Keyword(s):

Quantum Information ◽

Lower Bound ◽

Quantum Correlation ◽

The Other ◽

Werner State ◽

Sharing Scheme ◽

Asymmetric Quantum ◽

Quantum Steering ◽

Information Tasks

AbstractQuantum steering, a type of quantum correlation with unique asymmetry, has important applications in asymmetric quantum information tasks. We consider a new quantum steering scenario in which one half of a two-qubit Werner state is sequentially measured by multiple Alices and the other half by multiple Bobs. We find that the maximum number of Alices who can share steering with a single Bob increases from 2 to 5 when the number of measurement settings N increases from 2 to 16. Furthermore, we find a counterintuitive phenomenon that for a fixed N, at most 2 Alices can share steering with 2 Bobs, while 4 or more Alices are allowed to share steering with a single Bob. We further analyze the robustness of the steering sharing by calculating the required purity of the initial Werner state, the lower bound of which varies from 0.503(1) to 0.979(5). Finally, we show that our both-sides sequential steering sharing scheme can be applied to control the steering ability, even the steering direction, if an initial asymmetric state or asymmetric measurement is adopted. Our work gives insights into the diversity of steering sharing and can be extended to study the problems such as genuine multipartite quantum steering when the sequential unsharp measurement is applied.

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Dynamics of quantum correlations in quantum teleportation

International Journal of Modern Physics B ◽

10.1142/s0217979220500939 ◽

2020 ◽

Vol 34 (10) ◽

pp. 2050093

Author(s):

K. El Anouz ◽

I. El Aouadi ◽

A. El Allati ◽

T. Mourabit

Keyword(s):

Quantum Teleportation ◽

Quantum Correlation ◽

Quantum Discord ◽

Information Source ◽

Dynamical Evolution ◽

Single Mode ◽

Quantum Correlations ◽

Entangled State ◽

Average Fidelity ◽

Level Atom

A scheme of quantum teleportation using Jaynes–Cummings model is proposed. It consists of using a partial entangled state generated from the interaction between a two-level atom and single mode of radiation field as a quantum channel. By controlling the number of photons inside cavity and detuning parameter, the dynamical evolution of quantum correlation and entanglement degree in terms of quantum discord and concurrence, respectively, in the nonresonance case are investigated. Moreover, a comparative study between the teleported entanglement, teleported quantum correlation and average fidelity shows a good similarity between their dynamical evolution. Consequently, we conclude that quantum discord may be considered as a good information source in quantum teleportation process.

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USEFULNESS CLASSES OF TRAVELING ENTANGLED CHANNELS IN NONINERTIAL FRAMES

International Journal of Modern Physics B ◽

10.1142/s0217979213501555 ◽

2013 ◽

Vol 27 (28) ◽

pp. 1350155 ◽

Cited By ~ 14

Author(s):

N. METWALLY

Keyword(s):

Pure State ◽

Quantum Teleportation ◽

The Self ◽

Entangled States ◽

Quantum Channels ◽

Werner State ◽

Qubit System ◽

Pure States

The dynamics of a general two qubit system in a noninetrial frame is investigated analytically, where it is assumed that both of its subsystems are differently accelerated. Two classes of initial traveling states are considered: self-transposed and generic pure states. The entanglement contained in all possible generated entangled states between the qubits and their anti-qubits is quantified. The usefulness of the traveling states as quantum channels to perform quantum teleportation is investigated. For the self-transposed classes, it is shown that the generalized Werner state is the most robust class and starting from a class of pure state, one can generate entangled states more robust than self-transposed classes.

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