The Quantum Mechanics of Closed Systems

TL;DR

This paper introduces the quantum mechanics of closed systems, emphasizing decoherence and the emergence of classical behavior from quantum principles, applicable to the universe as a whole.

Contribution

It provides a comprehensive pedagogical framework for understanding quantum mechanics of closed systems, including decoherence mechanisms and the emergence of classicality.

Findings

Decoherence explains the emergence of classical behavior in quantum systems.

Copenhagen quantum mechanics is an approximation within the broader closed-system framework.

Initial conditions of the universe influence the classical domain emergence.

Abstract

A pedagogical introduction is given to the quantum mechanics of closed systems, most generally the universe as a whole. Quantum mechanics aims at predicting the probabilities of alternative coarse-grained time histories of a closed system. Not every set of alternative coarse-grained histories that can be described may be consistently assigned probabilities because of quantum mechanical interference between individual histories of the set. In the quantum mechanics of closed systems, containing both observer and observed, probabilities are assigned to those sets of alternative histories for which there is negligible interference between individual histories as a consequence of the system's initial condition and dynamics. Such sets of histories are said to decohere. Typical mechanisms of decoherence that are widespread in our universe are illustrated. Copenhagen quantum mechanics is an approximation to the more general quantum framework of closed subsystems. It is appropriate when there is an approximately isolated subsystem that is a participant in a measurement situation in which (among other things) the decoherence of alternative registrations of the apparatus can be idealized as exact. Since the quantum mechanics of closed systems does not posit the existence of the quasiclassical domain of everyday experience, the domain of the approximate aplicability of classical physics must be explained. We describe how a quasiclassical domain described by averages of densities of approximately conserved quantities could be an emergent feature of an initial condition of the universe that implies the approximate classical behavior of spacetime on accessible scales.