Concentration phenomena in the geometry of Bell correlations

Duarte, Cristhiano; Brito, Samuraí; Amaral, Bárbara; Chaves, Rafael

doi:10.1103/physreva.98.062114

Cited by 13 publications

(25 citation statements)

References 63 publications

(87 reference statements)

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“…Covering both foundational and applied perspectives, a crucial aspect to better understand quantum correlations, their potential advantages over classical resources but also their limitations in the processing of information, relies on understanding their geometry [21]. Many more works [22][23][24][25][26][27][28][29][30] have also revealed a number of interesting geometrical aspects of the set of quantum correlations. Perhaps the best available tool for studying the quantum-postquantum boundary is the Navascues-Pironio-Acin (NPA) hierarchy [31,32], which gives a series of outer approximations converging to a set of quantum correlations Q. Interestingly, in a more recent development [33], it was shown that any nonlocal correlation which belongs to the set of almost quantum correlations Q (1+ab) , the set determined by the (1 + ab) level of the NPA hierarchy [31,32], satisfies all physical principles proposed so far, with two possible exceptions: (i) the information causality principle [11,12] and its generalization [13], and (ii) the recently proposed principle of many-box locality [16].…”

Section: Introductionmentioning

confidence: 99%

Geometry of the quantum set on no-signaling faces

et al. 2019

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Since Bell's theorem we know that quantum mechanics is incompatible with local hidden-variable models, the phenomenon known as quantum nonlocality. However, despite steady progress over the years, precise characterization of the set of quantum correlations remained elusive. There are correlations compatible with the no-signaling principle and still beyond what can be achieved within quantum theory, which has motivated the search for physical principles and computational methods to decide the quantum or postquantum behavior of correlations. Here, we identify a feature of Bell correlations that we call quantum voids: faces of the no-signaling set where all nonlocal correlations are postquantum. Considering the simplest possible Bell scenario, we give a full characterization of quantum voids, also understanding its connections to known principles and its potential use as a dimension witness. arXiv:1812.06057v2 [quant-ph]

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Section: Introductionmentioning

confidence: 99%

Geometry of the quantum set on no-signaling faces

et al. 2019

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“…We point out that although the main application of a resource theory is to understand the role of a physical property as an operational resource, this construction can be interesting on its own and it can give insight into the physical property under consideration. For example, Duarte et al [43] use contextuality quantifiers to explore the geometry of the set of behaviours, finding the approximate relative volume of the non-contextual set in relation to the non-disturbing set.…”

Section: Discussionmentioning

confidence: 99%

Resource theory of contextuality

Amaral

2019

Phil. Trans. R. Soc. A.

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In addition to the important role of contextuality in foundations of quantum theory, this intrinsically quantum property has been identified as a potential resource for quantum advantage in different tasks. It is thus of fundamental importance to study contextuality from the point of view of resource theories, which provide a powerful framework for the formal treatment of a property as an operational resource. In this contribution we review recent developments towards a resource theory of contextuality and connections with operational applications of this property.

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“…To this end, it is worth noting that, quantitative difference between the "size" of the Bell-local set L, the quantum set Q, and the nonsignaling set N S has been investigated in [47][48][49]. Specifically, in the simplest Bell scenario involving two parties, each performing two binary-outcome measurements, the volume of L and that of Q, relative to N S, in the subspace of "full" correlation functions [50] was first determined in [47].…”

Section: Introductionmentioning

confidence: 99%

“…Then, for the same Bell scenario, the analysis has been generalized [48] to include also the subspace spanned by marginal correlations. Beyond this, numerical estimation on the relative volume of L to N S was carried out in [49] for a few Bell scenarios with either two measurement settings or outcomes; some analytic results were also presented therein when restricted to the subspace of full correlations.…”

Section: Introductionmentioning

confidence: 99%

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Naturally restricted subsets of nonsignaling correlations: typicality and convergence

Lin,

Vértesi,

Liang

2021

Preprint

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It is well-known that in a Bell experiment, the observed correlation between measurement outcomes-as predicted by quantum theory-can be stronger than that allowed by local causality, yet not fully constrained by the principle of relativistic causality. In practice, the characterization of the set Q of quantum correlations is often carried out through a converging hierarchy of outer approximations. On the other hand, some subsets of Q arising from additional constraints [e.g., originating from quantum states having positive-partial-transposition (PPT) or being finite-dimensional maximally entangled] turn out to be also amenable to similar numerical characterizations. How then, at a quantitative level, are all these naturally restricted subsets of nonsignaling correlations different? Here, we consider several bipartite Bell scenarios and numerically estimate their volume relative to that of the set of nonsignaling correlations. Among others, our findings allow us to (1) gain insight on (i) the effectiveness of the so-called Q1 and the almost quantum set in approximating Q, (ii) the rate of convergence among the first few levels of the aforementioned outer approximations, (iii) the typicality of the phenomenon of more nonlocality with less entanglement, and (2) identify a Bell scenario whose Bell violation by PPT states might be experimentally viable.

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Concentration phenomena in the geometry of Bell correlations

Cited by 13 publications

References 63 publications

Geometry of the quantum set on no-signaling faces

Geometry of the quantum set on no-signaling faces

Resource theory of contextuality

Naturally restricted subsets of nonsignaling correlations: typicality and convergence

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