Classical and quantum correlations under decoherence

Maziero, Jonas; Céleri, Lucas C.; Serra, R. M.; Vedral, Vlatko

doi:10.1103/physreva.80.044102

Cited by 497 publications

(540 citation statements)

References 31 publications

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“…The behavior of TQD in this case is related to the minimization process of the quantum conditional entropy (A.2). We observe that for finite T there is an exchange in the functions that minimize the conditional entropy which in turn leads to a sudden change in TQD [33] Moving to the cases where h > 0 we keep the same set of parameters of Fig. 2 but the value of the external magnetic field.…”

Section: A the Xxz Modelmentioning

confidence: 99%

Spotlighting quantum critical points via quantum correlations at finite temperatures

2011

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We extend the program initiated in [T. Werlang et al., Phys. Rev. Lett. 105, 095702 (2010)] in several directions. Firstly, we investigate how useful quantum correlations, such as entanglement and quantum discord, are in the detection of critical points of quantum phase transitions when the system is at finite temperatures. For that purpose we study several thermalized spin models in the thermodynamic limit, namely, the XXZ model, the XY model, and the Ising model, all of which with an external magnetic field. We compare the ability of quantum discord, entanglement, and some thermodynamic quantities to spotlight the quantum critical points for several different temperatures. Secondly, for some models we go beyond nearest-neighbors and also study the behavior of entanglement and quantum discord for second nearest-neighbors around the critical point at finite temperature. Finally, we furnish a more quantitative description of how good all these quantities are in spotlighting critical points of quantum phase transitions at finite T , bridging the gap between experimental data and those theoretical descriptions solely based on the unattainable absolute zero assumption.

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Section: A the Xxz Modelmentioning

confidence: 99%

Spotlighting quantum critical points via quantum correlations at finite temperatures

2011

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“…The finitetime disappearance of entanglement, sometimes called "sudden-death of entanglement" [28,33] was experimentally demonstrated by Almeida et al [32]. The dynamics of quantum correlations other then entanglement has also been analyzed, both theoretically [34,35] and experimentally [36].…”

Section: Introductionmentioning

confidence: 99%

Quantum correlations as precursors of entanglement

Auyuanet

2010

Phys. Rev. A

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We show that for two initially excited qubits, interacting via dipole forces and with a common reservoir, entanglement is preceded by the emergence of quantum and classical correlations. After a time lag, entanglement finally starts building up, giving rise to a peculiar entangled state, with very small classical correlations. Different measures of quantum correlations are discussed, and their dynamics are compared and shown to lead to coincident values of these quantifiers for several ranges of time.

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“…Recent results showing that almost all (separable) quantum states actually have such nonclassical correlations [3] and that they can improve some computational tasks in comparison to when classical states are used [4,5] reinforce the relevance of such an issue. As a result, the last few years have witnessed an increasing number of articles discussing the quantification of these correlations [1,2,[6][7][8], their behavior under decoherence [9][10][11][12], and their relevance for quantum phase transitions [13][14][15][16].…”

Section: Introductionmentioning

confidence: 99%

Sudden change in quantum and classical correlations and the Unruh effect

et al. 2010

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We use the Unruh effect to analyze the dynamics of classical and quantum correlations for a two-qubit system when one of them is uniformly accelerated for a finite amount of proper time. We show that the quantum correlation is completely destroyed in the limit of infinite acceleration, while the classical one remains nonzero. In particular, we show that such correlations exhibit the so-called sudden-change behavior as a function of acceleration. Eventually, we discuss how our results can be interpreted when the system lies in the vicinity of the event horizon of a Schwarzschild black hole.

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Classical and quantum correlations under decoherence

Cited by 497 publications

References 31 publications

Spotlighting quantum critical points via quantum correlations at finite temperatures

Spotlighting quantum critical points via quantum correlations at finite temperatures

Quantum correlations as precursors of entanglement

Sudden change in quantum and classical correlations and the Unruh effect

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