Buscemi非定域量子资源理论的运算意义

Patryk Lipka-Bartosik, Andrés F. Ducuara, T. Purves, Paul Skrzypczyk
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引用次数: 7

摘要

虽然在贝尔实验中,纠缠态对于观察非局域性是必要的,但是纠缠态永远不能用于证明非局域相关。在一篇开创性的论文[PRL 108, 200401(2012)]中,F. Buscemi扩展了标准贝尔实验,允许Alice和Bob被问量子问题,而不是经典问题。这产生了一个更广泛的非定域性概念,它可以在每个纠缠态中被观察到。在这项工作中,我们研究了这种类型的非定域性资源理论,称为Buscemi非定域性。我们提出了一个几何量词来测量给定状态和局部测量产生Buscemi非局部相关的能力,并建立了它的操作意义。特别是,我们证明了任何能够证明Buscemi非局部相关的分布式测量在分布式状态判别任务中比任何不使用纠缠的分布式测量提供了严格更好的性能。我们还证明了使用给定状态可以产生的Buscemi非定域性的最大数量恰好等于它的纠缠内容。最后,我们证明了Buscemi非定域性、执行非经典隐形传态的能力和纠缠之间的定量关系。利用这种关系,我们提出了新的判别任务,其中非经典隐形传态和纠缠导致优于经典对应任务的优势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Operational Significance of the Quantum Resource Theory of Buscemi Nonlocality
Although entanglement is necessary for observing nonlocality in a Bell experiment, there are entangled states which can never be used to demonstrate nonlocal correlations. In a seminal paper [PRL 108, 200401 (2012)] F. Buscemi extended the standard Bell experiment by allowing Alice and Bob to be asked quantum, instead of classical, questions. This gives rise to a broader notion of nonlocality, one which can be observed for every entangled state. In this work we study a resource theory of this type of nonlocality referred to as Buscemi nonlocality. We propose a geometric quantifier measuring the ability of a given state and local measurements to produce Buscemi nonlocal correlations and establish its operational significance. In particular, we show that any distributed measurement which can demonstrate Buscemi nonlocal correlations provides strictly better performance than any distributed measurement which does not use entanglement in the task of distributed state discrimination. We also show that the maximal amount of Buscemi nonlocality that can be generated using a given state is precisely equal to its entanglement content. Finally, we prove a quantitative relationship between: Buscemi nonlocality, the ability to perform nonclassical teleportation, and entanglement. Using this relationship we propose new discrimination tasks for which nonclassical teleportation and entanglement lead to an advantage over their classical counterparts.
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