Classical stochastic approach to quantum mechanics and quantum thermodynamics

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 φj 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 φj, the Schr\"odinger and the quantum Liouville equation are obtained. The component j of the wave vector obeying the Schr\"odinger equation is related to stochastic wave vector by |j|2=|φj|2.