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Lagrangian Description for Particle Interpretations of Quantum Mechanics: Entangled Many-Particle Case
Foundations of Physics 47 (2):174-207 (2017)
Abstract
A Lagrangian formulation is constructed for particle interpretations of quantum mechanics, a well-known example of such an interpretation being the Bohm model. The advantages of such a description are that the equations for particle motion, field evolution and conservation laws can all be deduced from a single Lagrangian density expression. The formalism presented is Lorentz invariant. This paper follows on from a previous one which was limited to the single-particle case. The present paper treats the more general case of many particles in an entangled state. It is found that describing more than one particle while maintaining a relativistic description requires the specification of final boundary conditions as well as the usual initial ones, with the experimenter’s controllable choice of the final conditions thereby exerting a backwards-in-time influence. This retrocausality then allows an important theoretical step forward to be made, namely that it becomes possible to dispense with the usual, many-dimensional description in configuration space and instead revert to a description in space–time using separate, single-particle wavefunctions.Links
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Citations of this work
Taking Heisenberg's Potentia Seriously.Ruth Kastner, Stuart Kauffman & Michael Epperson - 2018 - International Journal of Quantum Foundations 4 (2):158-172.
Probabilities and Certainties Within a Causally Symmetric Model.Roderick I. Sutherland - 2022 - Foundations of Physics 52 (4):1-17.
Lorentz-Invariant, Retrocausal, and Deterministic Hidden Variables.Aurélien Drezet - 2019 - Foundations of Physics 49 (10):1166-1199.
Is There Really "Retrocausation" in Time-Symmetric Approaches to Quantum Mechanics?Ruth Kastner - unknown
Solution to David Chalmer's "Hard Problem".Jack Sarfatti & Arik Shimansky - 2018 - Cosmos and History 14 (1):163-186.
References found in this work
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On the Einstein Podolsky Rosen paradox.J. S. Bell - 1987 - In John Stewart Bell (ed.), Speakable and unspeakable in quantum mechanics: collected papers on quantum philosophy. New York: Cambridge University Press. pp. 14--21.
A Suggested Interpretation of the Quantum Theory in Terms of ‘Hidden’ Variables, I and II.David Bohm - 1952 - Physical Review (85):166-193.
Causality and Chance in Modern Physics.David Bohm - 1960 - British Journal for the Philosophy of Science 10 (40):321-338.
Density Formalism for Quantum Theory.Roderick I. Sutherland - 1998 - Foundations of Physics 28 (7):1157-1190.
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