Bipartite qutrit local realist inequalities and the robustness of their quantum mechanical violation

Das, Debarshi; Datta, Siddhartha; Goswami, Suchetana; Majumdar, A. S.; Home, Dipankar

doi:10.1016/j.physleta.2017.08.052

Cited by 10 publications

(8 citation statements)

References 53 publications

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“…Secondly, in the same spirit of the present work, it would be interesting to investigate sharing of multipartite quantum steering [50][51][52] by multiple observers measuring sequentially on the same particle. Thirdly, exploring the concept of nonlocality sharing for higher dimensional quantum systems by using different many-outcome local realist inequalities [53,54] remains open till date. Another interesting direction is to explore the pos-sibility of sharing tripartite nonlocal correlations between (i) single Alice -multiple Bobs -multiple Charlies, (ii) multiple Alices -multiple Bobs -multiple Charlies and finding a connection of these sharing phenomena with some information processing task(s).…”

Section: Concluding Discussionmentioning

confidence: 99%

Sharing of tripartite nonlocality by multiple observers measuring sequentially at one side

Saha

Das

Sasmal

et al. 2019

Quantum Inf Process

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Standard tripartite nonlocality and genuine tripartite nonlocality can be detected by the violations of Mermin inequality and Svetlichny inequality, respectively. Since tripartite quantum nonlocality has novel applications in quantum information and quantum computation, it is important to investigate whether more than three observers can share tripartite nonlocality, simultaneously. In the present study we answer this question in the affirmative. In particular, we consider a scenario where three spin-1 2 particles are spatially separated and shared between Alice, Bob and multiple Charlies. Alice performs measurements on the first particle; Bob performs measurements on the second particle and multiple Charlies perform measurements on the third particle sequentially. In this scenario we investigate how many Charlies can simultaneously demonstrate standard tripartite nonlocality and genuine tripartite nonlocality with single Alice and single Bob. The interesting result revealed by the present study is that at most six Charlies can simultaneously demonstrate standard tripartite nonlocality with single Alice and single Bob. On the other hand, at most two Charlies can simultaneously demonstrate genuine tripartite nonlocality with single Alice and single Bob. Hence, the present study shows that standard tripartite nonlocality can be simultaneously shared by larger number of Charlies compared to genuine tripartite nonlocality in the aforementioned scenario, which implies that standard tripartite nonlocality is more effective than genuine tripartite nonlocality in the context of simultaneous sharing by multiple observers.

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Section: Concluding Discussionmentioning

confidence: 99%

Sharing of tripartite nonlocality by multiple observers measuring sequentially at one side

Saha

Das

Sasmal

et al. 2019

Quantum Inf Process

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“…This is similar to the case of nonlocality studies using Bell-type inequalities involving measurements pertaining to mutually noncommuting bases which do not necessarily need to be MUBs [46]. Here we may also mention that apart from its other applications, the procedure of entanglement characterization and quantification using PCCs in the qutrit case, together with the results of studies on the nonlocality of bipartite qutrit states can provide a powerful experimental platform for a comprehensive probing of hitherto unexplored quantitative aspects of the relationship between entanglement and nonlocality [44][45][46][58][59][60][61][62][63].…”

Section: Introductionmentioning

confidence: 99%

Pearson correlation coefficient as a measure for certifying and quantifying high-dimensional entanglement

2020

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A scheme for characterizing entanglement using the statistical measure of correlation given by the Pearson correlation coefficient (PCC) was recently suggested that has remained unexplored beyond the qubit case. Towards the application of this scheme for the high dimensional states, a key step has been taken in a very recent work by experimentally determining PCC and analytically relating it to Negativity for quantifying entanglement of the empirically produced bipartite pure state of spatially correlated photonic qutrits. Motivated by this work, we present here a comprehensive study of the efficacy of such an entanglement characterizing scheme for a range of bipartite qutrit states by considering suitable combinations of PCCs based on a limited number of measurements. For this purpose, we investigate the issue of necessary and sufficient certification together with quantification of entanglement for the two-qutrit states comprising maximally entangled state mixed with white noise and coloured noise in two different forms respectively. Further, by considering these classes of states for d = 4 and 5, extension of this PCC based approach for higher dimensions (d) is discussed.

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“…All mentioned above information and entropic schemes for quantum systems open a new prospective for implementation of quantum technologies, e.g., realization of quantum memory, quantum algorithms, and many-level quantum simulation [ 16 ]. However, in order to prove the inequality and study its application experimentally, especially the higher-dimensional inequality, the quality requirement of the entangled system is very strict [ 17 , 18 , 19 ]. To our knowledge, experimental reports on quantum entanglement entropy are very few [ 18 , 19 , 20 , 21 ].…”

Section: Introductionmentioning

confidence: 99%

Experimentally Demonstrate the Spin-1 Information Entropic Inequality Based on Simulated Photonic Qutrit States

Cao

Liu

Yang

et al. 2020

Entropy

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Quantum correlations of higher-dimensional systems are an important content of quantum information theory and quantum information application. The quantification of quantum correlation of high-dimensional quantum systems is crucial, but difficult. In this paper, using the second-order nonlinear optical effect and multiphoton interference enhancement effect, we experimentally implement the photonic qutrit states and demonstrate the spin-1 information entropic inequality for the first time to quantitative quantum correlation. Our work shows that information entropy is an important way to quantify quantum correlation and quantum information processing.Keywords: information entropic inequality; second-order nonlinear effect; multiphoton interference enhancement effect; high dimensional quantum correlation

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Bipartite qutrit local realist inequalities and the robustness of their quantum mechanical violation

Cited by 10 publications

References 53 publications

Sharing of tripartite nonlocality by multiple observers measuring sequentially at one side

Sharing of tripartite nonlocality by multiple observers measuring sequentially at one side

Pearson correlation coefficient as a measure for certifying and quantifying high-dimensional entanglement

Experimentally Demonstrate the Spin-1 Information Entropic Inequality Based on Simulated Photonic Qutrit States

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