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Spacetime Path Integrals for Entangled States
Foundations of Physics 52 (1):1-23 (2021)
Abstract
Although the path-integral formalism is known to be equivalent to conventional quantum mechanics, it is not generally obvious how to implement path-based calculations for multi-qubit entangled states. Whether one takes the formal view of entangled states as entities in a high-dimensional Hilbert space, or the intuitive view of these states as a connection between distant spatial configurations, it may not even be obvious that a path-based calculation can be achieved using only paths in ordinary space and time. Previous work has shown how to do this for certain special states; this paper extends those results to all pure two-qubit states, where each qubit can be measured in an arbitrary basis. Certain three-qubit states are also developed, and path integrals again reproduce the usual correlations. These results should allow for a substantial amount of conventional quantum analysis to be translated over into a path-integral perspective, simplifying certain calculations, and more generally informing research in quantum foundations.My notes
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Citations of this work
Entanglement and the Path Integral.Raylor Liu & Ken Wharton - 2022 - Foundations of Physics 53 (1):1-23.
References found in this work
Quantum Computation and Quantum Information.Michael A. Nielsen & Isaac L. Chuang - 2000 - Cambridge University Press.
Bell's Theorem without Inequalities.Daniel M. Greenberger, Michael A. Horne, Abner Shimony & Anton Zeilenger - 1990 - American Journal of Physics 58:1131--1143.
A General Argument Against Superluminal Transmission through the Quantum Mechanical Measurement Process.G. C. Ghirardi, A. Rimini & T. Weber - 1980 - Lettere Al Nuovo Cimento 27:294--298.
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