Related papers: Relaxation to quantum equilibrium and the Born rule in Nelson's stochastic dynamics

Relaxation to quantum equilibrium and the Born rule in Nelson's stochastic dynamics

URL: http://arxiv.org/abs/2305.04084v2
Date: Thu, 9 Nov 2023 16:54:21 GMT
Title: Relaxation to quantum equilibrium and the Born rule in Nelson's stochastic dynamics
Authors: Vincent Hardel, Paul-Antoine Hervieux, Giovanni Manfredi
Abstract summary: Nelson's quantum mechanics provides an ideal arena to test how the Born rule is established. For all cases, Nelson's trajectories are initially localized at a definite position.
Score: 0.1315429617442362
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Nelson's stochastic quantum mechanics provides an ideal arena to test how the Born rule is established from an initial probability distribution that is not identical to the square modulus of the wave function. Here, we investigate numerically this problem for three relevant cases: a double-slit interference setup, a harmonic oscillator, and a quantum particle in a uniform gravitational field. For all cases, Nelson's stochastic trajectories are initially localized at a definite position, thereby violating the Born rule. For the double slit and harmonic oscillator, typical quantum phenomena, such as interferences, always occur well after the establishment of the Born rule. In contrast, for the case of quantum particles free-falling in the gravity field of the Earth, an interference pattern is observed \emph{before} the completion of the quantum relaxation. This finding may pave the way to experiments able to discriminate standard quantum mechanics, where the Born rule is always satisfied, from Nelson's theory, for which an early subquantum dynamics may be present before full quantum relaxation has occurred. Although the mechanism through which a quantum particle might violate the Born rule remains unknown to date, we speculate that this may occur during fundamental processes, such as beta decay or particle-antiparticle pair production.

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