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

Chatterjee, Arpita; Thapliyal, Kishore; Pathak, Anirban

doi:10.1002/andp.202100201

Cited by 5 publications

(3 citation statements)

References 99 publications

(92 reference statements)

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“…We consider two double chargers schemes. In the first one, the state of two chargers is a product state |ψ = |α 1 |α 2 , while in the second, the two chargers are prepared to be in an entangles semi Bell state [44,45]…”

Section: B Correlated and Uncorrelated Chargersmentioning

confidence: 99%

Performance of quantum batteries with correlated and uncorrelated chargers

Arjmandi¹,

Shokri²,

Faizi³

et al. 2022

Preprint

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Energy can be stored in some quantum batteries by electromagnetic fields as chargers. In this paper, the performance of a quantum battery with single and double chargers is studied. It is shown that by using two independent charging fields, prepared in coherent states, charging power of the quantum battery can be significantly improved, though the average number of embedded photons are kept the same in both scenarios. Then the results reveal that for the case of initially correlated states of the chargers the amount of extractable energy, measured by ergotropy, is more than initially uncorrelated ones. Finally, the behavior of generated quantum consonance between different cells of quantum battery and also the effect of generated battery-charger mutual information during the evolution are investigated and some qualitative relations between the generation of such correlations and the capability of energy storage in the quantum battery is demonstrated.

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Section: B Correlated and Uncorrelated Chargersmentioning

confidence: 99%

Performance of quantum batteries with correlated and uncorrelated chargers

Arjmandi¹,

Shokri²,

Faizi³

et al. 2022

Preprint

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“…Specifically, there are no-go theorems limiting the applications of Gaussian operations and Gaussian states in entanglement distillation, [26] quantum error correction, [27] quantum computing, [23] and quantum bit commitment. [28] Use of non-Gaussian operations is known to provide advantages in computation, [23] communication, [29] metrology, [24] etc. These set of promising applications have motivated witnesses of non-Gaussianity, [20] resource theory of non-Gaussianity, [25] and a set of measures of quantum non-Gaussianity (refs.…”

Section: 𝜌 = ∫ D(p(𝛼))|𝛼⟩⟨𝛼| (1)mentioning

confidence: 99%

Enhancement of Non‐Gaussianity and Nonclassicality of Photon‐Added Displaced Fock State: A Quantitative Approach

et al. 2022

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Non-Gaussian and nonclassical states and processes are already found to be important resources for performing various tasks related to quantum gravity and quantum information processing. Considering these facts, a quantitative analysis of the nonclassical and non-Gaussian features is performed here for photon added displaced Fock state, as a test case, using a set of measures, namely entanglement potential, Wigner-Yanese skew information, Wigner logarithmic negativity, and relative entropy of non-Gaussianity. It is observed that Fock parameter always increases the amount of nonclassicality and non-Gaussianity, while photon addition is effective only for small values of the displacement parameter. Further, the nonclassical and non-Gaussian effects decrease initially with an increase in the displacement parameter before increasing for the large displacement to saturate to the corresponding Fock state (equivalently displaced Fock state) value. Finally, dynamics of the Wigner function under the effect of photon loss channel is used to show that only highly efficient detectors are able to detect Wigner negativity.

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“…In particular, there are no-go theorems limiting the use of Gaussian operations and Gaussian states in entanglement distillation [20], quantum error correction [21], quantum computing [17], and quantum bit commitment [22]. Use of non-Gaussian operations provides advantages in quantum computation [17], quantum communication [23], quantum metrology [18], and so on. These promising applications motivated people to study about resource theory of non-Gaussianity [19], and a number of measures of quantum non-Gaussianity ( [24][25][26], and references therein).…”

Section: Introductionmentioning

confidence: 99%

Detecting nonclassicality and non-Gaussianity of a coherent superposed quantum state

Deepak¹,

Chatterjee²

2022

J. Phys. B: At. Mol. Opt. Phys.

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In this paper, we investigate the nonclassicality and non-Gaussianity of a coherent superposed quantum state (CSQS) which is obtained by applying a coherent superposition of field annihilation ($a$) and creation ($a^\dagger$) operators, $N(ta+ra^\dagger)$ to a classical coherent state $\ket\alpha$, where $t$ and $r$ are scalars with $t^2+r^2=1$. Such an operation, when applied on states having classical characters, introduces strong nonclassicality. We use different criteria to check the nonclassicality and non-Gaussianity of the considered quantum state. We first compute the Wigner function of CSQS. To study the nonclassicality of the considered state we further use (i) linear entropy (LE) (ii) Wigner logarithmic negativity (WLN) and (iii) skew information based measure. Relative entropy based measure is considered to analyze the variation in non-Gaussianity of CSQS. Finally, the dynamics of the Wigner function evolving under the photon loss channel is addressed to probe the effect of noise on nonclassicality as well as non-Gaussianity of CSQS.

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

Cited by 5 publications

References 99 publications

Performance of quantum batteries with correlated and uncorrelated chargers

Performance of quantum batteries with correlated and uncorrelated chargers

Enhancement of Non‐Gaussianity and Nonclassicality of Photon‐Added Displaced Fock State: A Quantitative Approach

Detecting nonclassicality and non-Gaussianity of a coherent superposed quantum state

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