Catalytic quantum randomness as a correlational resource

What is the origin of quantum randomness? Why does the deterministic, unitary time development in Hilbert space (the ‘4π-realm’) lead to a probabilistic behaviour of observables in space-time (the ‘2π-realm’)? We propose a simple topological model for quantum randomness. Following Kauffmann, we elaborate the mathematical structures that follow from a distinction(A,B) using group theory and topology. Crucially, the 2:1-mapping from SL(2,C) to the Lorentz group SO(3,1) turns out to be responsible for the stochastic nature of observables in quantum physics, as this 2:1-mapping breaks down during interactions. Entanglement leads to a change of topology, such that a distinction between A and B becomes impossible. In this sense, entanglement is the counterpart of a distinction (A,B). While the mathematical formalism involved in our argument based on virtual Dehn twists and torus splitting is non-trivial, the resulting haptic model is so simple that we think it might be suitable for undergraduate courses and maybe even for High school classes.

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Quantum Randomness: From Practice to Theory and Back

The Incomputable - Theory and Applications of Computability ◽

10.1007/978-3-319-43669-2_11 ◽

2017 ◽

pp. 169-181 ◽

Cited By ~ 1

Author(s):

Cristian S. Calude

Keyword(s):

Quantum Randomness

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Quantum randomness in the Sky

The European Physical Journal C ◽

10.1140/epjc/s10052-019-7072-1 ◽

2019 ◽

Vol 79 (7) ◽

Cited By ~ 3

Author(s):

Sayantan Choudhury ◽

Arkaprava Mukherjee

Keyword(s):

Quantum Randomness

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How Does Quantum Uncertainty Emerge from Deterministic Bohmian Mechanics?

Fluctuation and Noise Letters ◽

10.1142/s0219477516400101 ◽

2016 ◽

Vol 15 (03) ◽

pp. 1640010 ◽

Cited By ~ 3

Author(s):

A. Solé ◽

X. Oriols ◽

D. Marian ◽

N. Zanghì

Keyword(s):

Wave Function ◽

Classical Mechanics ◽

Bohmian Mechanics ◽

The State ◽

Quantum Uncertainty ◽

Point Particles ◽

Quantum Randomness ◽

Quantum Dynamical ◽

System Of Particles ◽

Quantum Phenomena

Bohmian mechanics is a theory that provides a consistent explanation of quantum phenomena in terms of point particles whose motion is guided by the wave function. In this theory, the state of a system of particles is defined by the actual positions of the particles and the wave function of the system; and the state of the system evolves deterministically. Thus, the Bohmian state can be compared with the state in classical mechanics, which is given by the positions and momenta of all the particles, and which also evolves deterministically. However, while in classical mechanics it is usually taken for granted and considered unproblematic that the state is, at least in principle, measurable, this is not the case in Bohmian mechanics. Due to the linearity of the quantum dynamical laws, one essential component of the Bohmian state, the wave function, is not directly measurable. Moreover, it turns out that the measurement of the other component of the state — the positions of the particles — must be mediated by the wave function; a fact that in turn implies that the positions of the particles, though measurable, are constrained by absolute uncertainty. This is the key to understanding how Bohmian mechanics, despite being deterministic, can account for all quantum predictions, including quantum randomness and uncertainty.

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