More nonlocality with less entanglement in a tripartite atom‐optomechanical system

Zhang, Jing; Zhang, Tiancai; Xuereb, André; Vitali, David; Li, Jie

doi:10.1002/andp.201400107

Cited by 32 publications

(11 citation statements)

References 86 publications

(92 reference statements)

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“…It is commonly thought that the quality of a protocol scales with the degree of the shared entanglement. But, quite counter-intuitively, there exist kinds of information-theoretic tasks for which less entanglement turns out to be more useful [35][36][37]. Coming back to our problem, one may ask: "How if Bob (not Charlie) knows θ?".…”

Section: Entanglement-degree-independent Perfect Controlled Joint Remmentioning

confidence: 90%

Perfect controlled joint remote state preparation independent of entanglement degree of the quantum channel

Bich

2014

Physics Letters A

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Section: Entanglement-degree-independent Perfect Controlled Joint Remmentioning

confidence: 90%

Perfect controlled joint remote state preparation independent of entanglement degree of the quantum channel

Bich

2014

Physics Letters A

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“…In optomechanical systems, the entanglement has been generated between a movable mirror and a cavity [37], two cavity modes [38], or two magnomechanical modes [36]. With atoms in the cavity, the atomcavity-mirror tripartite entanglement emerges [39,40] and the entanglement transfer [41,42] can be observed. Note that, in the cavity magnomechanical system, the magnon-photon-phonon tripartite entanglement has been proposed, where the magnon-phonon entanglement can transfer to other subsystems via the coupling between the cavity and magnon [28].…”

Section: Introductionmentioning

confidence: 99%

Perfect Transfer of enhanced entanglement and asymmetric steering in a cavity magnomechanical system

Chen,

Du,

Zhang

et al. 2020

Preprint

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We propose a hybrid cavity magnomechanical system to realize and transfer the bipartite entanglements and EPR steerings between magnons, photons and phonons in the regime of the stability of the system. Satisfying the PT -like-symmetry relevant to the passive-active-cavity structure and the proper Stokes/anti-Stokes nonlinear processes, the system can enhance the robust distant quantum entanglement and generate the relatively obvious asymmetric (even directional) EPR steering that is useful for the task with the highly asymmetric trusts of the bidirectional local measurements between two entangled states. It is of great interest that, based on such a tunable magnomechanical system, the perfect transfer between near and distant entanglements/steerings of different mode pairs is realized by adjusting the coupling parameters; especially, the transfer scheme of steerings is first proposed here. These transferring processes can suggest a novel method for the quantum information storage and manipulation. In addition, the entanglements and steerings can also be exchanged between different mode pairs by adjusting the detunings between different modes. This work may provide a potential platform for distant/asymmetric quantum modulation.

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“…State generation by quantum measurement is also very useful for multi-mode quantum state engineering. Indeed, using a single photon detection event, entanglement between the vibrational states of two diamond crystals has been generated [38], and techniques for mechanical N 00N state generation have been proposed [39,40], as well as schemes to entangle atomic ensembles with mechanical motion [41,42]. In addition, a scheme has been recently proposed that utilises an optomechanical interaction with a non-classical optical field prepared via photon subtraction to conditionally generate non-classical mechanical states [43].…”

Section: Introductionmentioning

confidence: 99%

Nonclassical-state generation in macroscopic systems via hybrid discrete-continuous quantum measurements

2016

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Nonclassical-state generation is an important component throughout experimental quantum science for quantum information applications and probing the fundamentals of physics. Here, we investigate permutations of quantum nondemolition quadrature measurements and single quanta addition or subtraction to prepare quantum superposition states in bosonic systems. The performance of each permutation is quantified and compared using several different nonclassicality criteria including Wigner negativity, nonclassical depth, and optimal fidelity with a coherent-state superposition. We also compare the performance of our protocol using squeezing instead of a quadrature measurement and find that the purification provided by the quadrature measurement can significantly increase the nonclassicality generated. Our approach is ideally suited for implementation in light-matter systems such as quantum optomechanics and atomic spin ensembles, and offers considerable robustness to initial thermal occupation.

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More nonlocality with less entanglement in a tripartite atom‐optomechanical system

Cited by 32 publications

References 86 publications

Perfect controlled joint remote state preparation independent of entanglement degree of the quantum channel

Perfect controlled joint remote state preparation independent of entanglement degree of the quantum channel

Perfect Transfer of enhanced entanglement and asymmetric steering in a cavity magnomechanical system

Nonclassical-state generation in macroscopic systems via hybrid discrete-continuous quantum measurements

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