Quantum Hydrodynamics: Kirchhoff Equations
Abstract
In this paper, we show that the Kirchhoff equations are derived from the Schr\"odinger equation by assuming the wave function to be a polynomial like solution. These Kirchhoff equations describe the evolution of point vortices in hydrodynamics. In two dimensions, Kirchhoff equations are used to demonstrate the solution to single particle Laughlin wave function as complex Hermite polynomials. We also show that the equation for optical vortices, a two dimentional system, is derived from Kirchhoff equation by using paraxial wave approximation. These Kirchhoff equations satisfy a Poisson bracket relationship in phase space which is identical to the Heisenberg uncertainty relationship. Therefore, we conclude that being classical equations, the Kirchhoff equations, describe both a particle and a wave nature of single particle quantum mechanics in two dimensions.
Cite
@article{arxiv.1809.09964,
title = {Quantum Hydrodynamics: Kirchhoff Equations},
author = {K. V. S. Shiv Chaitanya},
journal= {arXiv preprint arXiv:1809.09964},
year = {2019}
}
Comments
Accepted for publication in foundations of physics and this version contains quant-ph 1709.02075 and quant-ph 1609.06159