2020
DOI: 10.3390/app10030792
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Double Slit with an Einstein–Podolsky–Rosen Pair

Abstract: In this somewhat pedagogical paper we revisit complementarity relations in bipartite quantum systems. Focusing on continuous variable systems, we examine the influential class of EPR-like states through a generalization to Gaussian states and present some new quantitative relations between entanglement and local interference within symmetric and asymmetric double-double-slit scenarios. This approach is then related to ancilla-based quantum measurements, and weak measurements in particular. Finally, we tie up t… Show more

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Cited by 11 publications
(10 citation statements)
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References 41 publications
(79 reference statements)
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“…(3) Not only the Tsirelson bound is found but also the Tsirelson-Landau-Masanes (TLM) bound [ 56 , 57 , 58 ], as well as new, hitherto unnoticed bounds. (4) It has already proved useful in deriving new outcomes [ 59 , 60 , 61 ].…”
Section: Uncertainty and Nonlocality: A Quantum Intimacymentioning
confidence: 99%
See 1 more Smart Citation
“…(3) Not only the Tsirelson bound is found but also the Tsirelson-Landau-Masanes (TLM) bound [ 56 , 57 , 58 ], as well as new, hitherto unnoticed bounds. (4) It has already proved useful in deriving new outcomes [ 59 , 60 , 61 ].…”
Section: Uncertainty and Nonlocality: A Quantum Intimacymentioning
confidence: 99%
“…Similar relations apply to multiple-input-multiple-output, multipartite scenarios [ 1 , 55 ]. Moreover, this approach can be extended through the use of “complex correlations” to non-Hermitian, signaling operators [ 60 ] and to continuous variables [ 61 ]. Finally, our approach has given rise to multiplicative Bell inequalities and their Tsirelson bounds [ 59 ], as well as several other results currently underway.…”
Section: Uncertainty and Nonlocality: A Quantum Intimacymentioning
confidence: 99%
“…The arguments covered in the previous section are then developed in the research articles, which consist of eight papers, offering a panorama of the present studies in quantum optics and analyzing some specific issues of the different lines of research in which this field is structured. In summary, issues concerning non-locality studies range from the application of the de Broglie-Bohm model to Gauss-Maxwell beams [13] to revisiting complementarity relations in bipartite quantum systems [14]; correlations in atoms are investigated in [15,16], photon emission and statistics in [17,18] and methods in quantum technologies in [19,20] The first paper [13] of this section deals with a Bohmian-based approach to Gauss-Maxwell beams, a particularly appropriate and natural tool in optical problems dealing with Gaussian beams acted or manipulated by polarizers: a hydrodynamic-type extension of such a formulation is provided and discussed, complementing the notion of the electromagnetic field with that of (electromagnetic) flow or streamline. The described features confer the approach a potential interest in the analysis and description of single-photon experiments.…”
Section: Quantum Optics For Fundamental Quantum Mechanicsmentioning
confidence: 99%
“…The complementarity relations in bipartite quantum systems are revisited in paper [14], where, by focusing on continuous-variable systems, the authors examine the influential class of EPR-like (EPR: Einstein Podolsky Rosen) states through a generalization to Gaussian states and introduce some new quantitative relations between entanglement and local interference within symmetric and asymmetric double-double-slit scenarios. In the paper, this approach is then related to ancilla-based quantum measurements and specifically to the paradigm of weak measurements.…”
Section: Quantum Optics For Fundamental Quantum Mechanicsmentioning
confidence: 99%
“…[13] Calculations on a pair of correlated particles that traverse interferometers whose components are treated as classical potentials also predict marginal distributions that vanish. [2,14] Two-body interference has been observed with a Bose-Einstein condensate that uses a potential well as a classical double slit but marginal distributions were not measured. [15] Marginal distributions also play an important role in quantum computing due to the difficultly in measuring all of the qubits after completion of a computation.…”
Section: Introductionmentioning
confidence: 99%