Schrodinger's Equation is Universal, Dark Matter and Double Diffusion
- URL: http://arxiv.org/abs/2105.02690v1
- Date: Wed, 5 May 2021 11:02:37 GMT
- Title: Schrodinger's Equation is Universal, Dark Matter and Double Diffusion
- Authors: Johan Beumee, Hershel Rabitz
- Abstract summary: This paper considers a main particle and an incident particle classical mechanics elastic collision preserving energy and momentum.
The main result of the paper shows that the colliding two particle classical Hamiltonian energy can be represented in four weighted individual particle.
The Schrodinger equation can also be used to represent corrections for Newton's equation and suggests a user profile to be used in the search for Dark Matter.
- Score: 0.0
- License: http://creativecommons.org/publicdomain/zero/1.0/
- Abstract: This paper considers a main particle and an incident particle classical
mechanics elastic collision preserving energy and momentum while ignoring the
angular momentum, spin or other particle characteristics. The main result of
the paper shows that the colliding two particle classical Hamiltonian energy
can be represented in four weighted individual particle in symmetric and
anti-symmetric (osmotic) terms similar to the quadratic Nelson measure used in
the derivation of the Schrodinger wave function. Following Nelson, if the
second particle behavior can be captured in a potential and the ingoing and
outgoing velocities of the main particle are modelled using stochastic
differential equations the motion of the main particle satisfies the
Schrodinger's equation. The diffusion variance of this equation is replaced by
a related ratio of masses and the assumed variance. The first example attempts
to reconcile this result with quantum mechanics by considering the Schrodinger
equation in the presence of only one type of incident particle. The main
particle energy levels become multiples of the incident particle and the energy
expression for the entire system agrees with quantum mechanics but there are
differences with the stochastic equation. The Schrodinger equation can also be
used to represent corrections for Newton's equation and suggests a user profile
to be used in the search for Dark Matter. An alternative solution to the
collision model also shows relativistic properties as the interactions suggest
corrections to the Minkowski equation in Einstein's Special Relativity. It is
also possible to use the classical Schrodinger's equation both on the main and
incident particle simultaneously leading to a correlated set of wave equations
with different diffusion parameters.
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