Current-based Simulation Models of Quantum Motion
Abstract
With purely classical tools a model for a bouncer-walker system of an elementary particle will be derived in this work which reflects the old idea of de Broglie's particle-wave duality. This model contains, on the one hand, a possible explanation of the work-energy exchange between the two separated motions, thereby providing an energy quantisation as originally postulated by Max Planck. On the other hand, the system perfectly obeys the Bohmian-type law of motion in full accordance with quantum mechanics. For the calculation of elementary particles' trajectories a ballistic diffusion equation will be derived which is a special case of a diffusion equation with a time-dependent diffusivity. Therewith the simulation of spreading of an elementary Gaussian is made easy as will be shown herein. With these tools one also accounts for Born's rule for multi-slit systems and develops a set of current rules that directly leads to a new formulation of the guiding equation equivalent to the original one of the de Broglie-Bohm theory. As will be shown in this thesis, this tool reproduces Talbot patterns and Talbot distance for an arbitrary multi-slit system. Moreover, the sweeper effect is shown to arise when the intensity relation of two beams of a double-slit experiment exhibit a big difference. Then, the low-intensity beam is pushed aside in a sense that its initial propagation straight out of the slit is bent towards the side. A sideways screen as an alternative measurement method is proposed.
Keywords
Cite
@article{arxiv.1705.02916,
title = {Current-based Simulation Models of Quantum Motion},
author = {Johannes Mesa Pascasio},
journal= {arXiv preprint arXiv:1705.02916},
year = {2017}
}
Comments
PhD thesis (dissertation) defended in April 2017; 125 pages, 59 figures; Supervisor: Manfried Faber (TU Wien); Referees: Maurice de Gosson (Universit\"at Wien), Basil Hiley (Birkbeck, University of London)