On the reality of quantum states: A pedagogic survey from classical to quantum mechanics

TL;DR

This paper explores the fundamental nature of quantum states by deriving quantum mechanics from classical principles, suggesting many quantum puzzles are rooted in classical physics and can be demystified.

Contribution

It presents a classical-to-quantum derivation of the Schrödinger equation, challenging the notion that quantum states are purely informational and highlighting classical analogs of quantum phenomena.

Findings

Quantum mechanics can be derived from classical wave equations.

Many quantum puzzles have classical counterparts in dormant form.

Objective wave functions in quantum mechanics are comparable to classical wave functions.

Abstract

Some recent experiments claim to show that any model in which a quantum state represents mere information about an underlying physical reality of the system must make predictions which contradict those of quantum theory. The present work undertakes to investigate the issue of reality, treading a more fundamental route from the Hamilton-Jacobi equation of classical mechanics to the Schrodinger equation of quantum mechanics. Motivation for this is a similar approach from the eikonal equation in geometrical optics to the wave equation in electromagnetic theory. We rewrite the classical Hamilton-Jacobi equation as a wave equation and seek to generalise de Broglie's wave particle duality by demanding that both particle and light waves have the freedom of being described by any square-integrable function. This generalisation, which allows superposition also for matter wave functions, helps us to obtain the Schrodinger equation, whose solution can be seen to be as much objective as the classical mechanics wave function. Several other equations which one writes in quantum mechanics, including the eigenvalue equations for observables, series expansion of energy states in terms of eigenstates of observables other than energy, etc., can be written in the classical case too. Absence of any collapse of the wave function, entanglement, etc. in the classical realm have their origin in the nonlinearity of the classical wave equation. These considerations indicate that many of the puzzles in quantum mechanics are present also in classical mechanics in a dormant form, which fact shall help to demystify quantum mechanics to a great extent.