Tracing quantum correlations back to collective interferences

Abstract In this paper, we investigate the possibility of explaining nonclassical correlations between two quantum systems in terms of quantum interferences between collective states of the two systems. We achieve this by mapping the relations between different measurement contexts in the product Hi...

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Bibliographic Details
Published inNew journal of physics Vol. 26; no. 6; pp. 63021 - 63031
Main Authors Ji, Ming, Hance, Jonte R, Hofmann, Holger F
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.06.2024
Subjects
collective interferences
Correlation
Hilbert space
Interferometers
Probability
quantum contextuality
quantum correlations
quantum foundations
Quantum mechanics
Quantum phenomena
weak values
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Summary:Abstract In this paper, we investigate the possibility of explaining nonclassical correlations between two quantum systems in terms of quantum interferences between collective states of the two systems. We achieve this by mapping the relations between different measurement contexts in the product Hilbert space of a pair of two-level systems onto an analogous sequence of interferences between paths in a single-particle interferometer. The relations between different measurement outcomes are then traced to the distribution of probability currents in the interferometer, where paradoxical relations between the outcomes are identified with currents connecting two states that are orthogonal and should therefore exclude each other. We show that the relation between probability currents and correlations can be represented by continuous conditional (quasi)probability currents through the interferometer, given by weak values; the violation of the noncontextual assumption is expressed by negative conditional currents in some of the paths. Since negative conditional currents correspond to the assignment of negative conditional probabilities to measurements results in different measurement contexts, the necessity of such negative probability currents represents a failure of noncontextual local realism. Our results help to explain the meaning of nonlocal correlations in quantum mechanics, and support Feynman’s claim that interference is the origin of all quantum phenomena.
Bibliography:NJP-117208.R1
ISSN:1367-2630
1367-2630
DOI:10.1088/1367-2630/ad5619