On the conection between the Liouville equation and the Schrodinger equation

TL;DR

This paper derives a classical Schrödinger-like equation from the Liouville equation using a Fourier transform, linking the constant in the equation to vacuum zero-point radiation and identifying it with Planck's constant.

Contribution

It introduces a method to derive a Schrödinger-type equation from classical phase space dynamics, connecting quantum constants to classical zero-point radiation.

Findings

The constant in the classical Schrödinger equation is identified with Planck's constant.

The derivation relies on a Fourier transform of the classical phase space distribution.

The classical probability amplitude can be expanded in a complete set of configuration space functions.

Abstract

We derive a classical Schrodinger type equation from the classical Liouville equation in phase space. The derivation is based on a Wigner type Fourier transform of the classical phase space probability distribution, which depends on an arbitrary constant $\alpha$ with dimension of action. In order to achieve this goal two requirements are necessary: 1) It is assumed that the classical probability amplitude $\Psi(x,t)$ can be expanded in a complete set of functions $\Phi_n(x)$ defined in the configuration space; 2) the classical phase space distribution $W(x,p,t)$ obeys the Liouville equation and is a real function of the position, the momentum and the time. We show that the constant $\alpha$ appearing in the Fourier transform of the classical phase space distribution, and also in the classical Schrodinger type equation, has its origin in the spectral distribution of the vacuum zero-point radiation, and is identified with the Planck's constant $\hbar$.