Classical Equations for Quantum Systems

TL;DR

This paper explores how classical equations emerge from quantum mechanics through coarse graining and decoherence, deriving phenomenological equations for quantum systems and analyzing their classical limit.

Contribution

It provides a detailed analysis of the conditions for decoherence and classical predictability, explicitly deriving phenomenological equations from quantum models.

Findings

Coarser coarse graining than naive uncertainty principles is needed for decoherence.

Derived explicit phenomenological equations of motion for specific quantum models.

Quantitatively linked decoherence, noise, dissipation, and coarse graining to classical predictability.

Abstract

The origin of the phenomenological deterministic laws that approximately govern the quasiclassical domain of familiar experience is considered in the context of the quantum mechanics of closed systems such as the universe as a whole. We investigate the requirements for coarse grainings to yield decoherent sets of histories that are quasiclassical, i.e. such that the individual histories obey, with high probability, effective classical equations of motion interrupted continually by small fluctuations and occasionally by large ones. We discuss these requirements generally but study them specifically for coarse grainings of the type that follows a distinguished subset of a complete set of variables while ignoring the rest. More coarse graining is needed to achieve decoherence than would be suggested by naive arguments based on the uncertainty principle. Even coarser graining is required in the distinguished variables for them to have the necessary inertia to approach classical predictability in the presence of the noise consisting of the fluctuations that typical mechanisms of decoherence produce. We describe the derivation of phenomenological equations of motion explicitly for a particular class of models. Probabilities of the correlations in time that define equations of motion are explicitly considered. Fully non-linear cases are studied. Methods are exhibited for finding the form of the phenomenological equations of motion even when these are only distantly related to those of the fundamental action. The demonstration of the connection between quantum-mechanical causality and causalty in classical phenomenological equations of motion is generalized. The connections among decoherence, noise, dissipation, and the amount of coarse graining necessary to achieve classical predictability are investigated quantitatively.