2022
DOI: 10.1016/j.physa.2022.127934
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Quantum correlations and coherence in a moving Unruh–deWitt detector

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Cited by 3 publications
(3 citation statements)
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“…To analyze how the dynamics of entropy disorder and quantum correlation within a system are influenced by interacting with a massless scalar field and uniformly accelerating, a group of parameters has been established to explore the evolution process. The findings demonstrate that the noisy evolution of detectors under the effect of Unruh decoherence can produce quantum correlations, akin to the generation of entanglement and coherence reported in previous works [15,46]. In fact, the quantum correlations experience a resurgence with increasing Unruh temperature, particularly for certain initial state parameters of the detectors.…”
Section: Discussionsupporting
confidence: 68%
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“…To analyze how the dynamics of entropy disorder and quantum correlation within a system are influenced by interacting with a massless scalar field and uniformly accelerating, a group of parameters has been established to explore the evolution process. The findings demonstrate that the noisy evolution of detectors under the effect of Unruh decoherence can produce quantum correlations, akin to the generation of entanglement and coherence reported in previous works [15,46]. In fact, the quantum correlations experience a resurgence with increasing Unruh temperature, particularly for certain initial state parameters of the detectors.…”
Section: Discussionsupporting
confidence: 68%
“…Additionally, the Unruh effect is a specific example of how vacuum fluctuations undergo parametric amplification [14]. This effect causes the detector to behave as if it is immersed in a thermal environment with a Unruh temperature T k 2 B = g p  that corresponds to its own proper acceleration γ, leading to decoherence and loss of the properties of the coupled Unruh-deWitt detectors [7,15,16]. The Unruh-deWitt detector model is commonly used to probe quantum fields in curved spacetime and investigate the implications for relativistic quantum information.…”
Section: Introductionmentioning
confidence: 99%
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