Classical stochastic approach to quantum mechanics and quantum thermodynamics

TL;DR

This paper presents a derivation of quantum mechanics and thermodynamics from a classical stochastic framework, linking wave functions to underlying classical particle systems and deriving key equations like Lindblad and Schrödinger from stochastic dynamics.

Contribution

It introduces a novel classical stochastic approach to derive fundamental quantum equations, connecting classical particle systems with quantum wave functions.

Findings

Derives Lindblad-type covariance equations from classical stochastic dynamics.

Obtains Schrödinger and quantum Liouville equations under phase-only noise.

Relates stochastic wave vectors to quantum wave functions via expectation values.

Abstract

We derive the equations of quantum mechanics and quantum thermodynamics from the assumption that a quantum system can be described by an underlying classical system of particles. Each component $\phi_j$ of the wave vector is understood as a stochastic complex variable whose real and imaginary parts are proportional to the coordinate and momentum associated to a degree of freedom of the underlying classical system. From the classical stochastic equations of motion, we derive a general equation for the covariance matrix of the wave vector which turns out to be of the Lindblad type. When the noise changes only the phase of $\phi_j$, the Schr\"odinger and the quantum Liouville equation are obtained. The component $\psi_j$ of the wave vector obeying the Schr\"odinger equation is related to stochastic wave vector by $|\psi_j|^2=\langle|\phi_j|^2\rangle$.