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  1. Quantum Causality Relations and the Emergence of Reality from Coherent Superpositions.Holger F. Hofmann - 2020 - Foundations of Physics 50 (12):1809-1823.
    The Hilbert space formalism describes causality as a statistical relation between initial experimental conditions and final measurement outcomes, expressed by the inner products of state vectors representing these conditions. This representation of causality is in fundamental conflict with the classical notion that causality should be expressed in terms of the continuity of intermediate realities. Quantum mechanics essentially replaces this continuity of reality with phase sensitive superpositions, all of which need to interfere in order to produce the correct conditional probabilities for (...)
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  • How (not) to understand weak measurements of velocities.Johannes Fankhauser & Patrick M. Dürr - 2021 - Studies in History and Philosophy of Science Part A 85:16-29.
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  • Relativistic Bohmian Trajectories and Klein-Gordon Currents for Spin-0 Particles.M. Alkhateeb & A. Matzkin - 2022 - Foundations of Physics 52 (5):1-13.
    It is generally believed that the de Broglie-Bohm model does not admit a particle interpretation for massive relativistic spin-0 particles, on the basis that particle trajectories cannot be defined. We show this situation is due to the fact that in the standard representation of the Klein-Gordon equation the wavefunction systematically contains superpositions of particle and anti-particle contributions. We argue that by working in a Foldy-Wouthuysen type representation uncoupling the particle from the anti-particle evolutions, a positive conserved density for a particle (...)
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  • On the Quantum Mechanical Measurement Process.H. W. L. Naus - 2021 - Foundations of Physics 51 (1):1-13.
    The quantum mechanical measurement process is analyzed by means of an explicit generic model describing the interaction between object and measuring device. The solution of the Schrödinger equation for the whole system reflects the ‘collapse’ of the object wave function. A necessary condition is a sufficiently sharply peaked initial measurement device wave function, which is guaranteed in its classical limit. With this assumption, it is in particular proven that the off-diagonal elements of the object density matrix vanish. This study therefore (...)
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