Quantum Hierarchical Systems: Fluctuation Force by Coarse-Graining, Decoherence by Correlation Noise

TL;DR

This paper explores how hierarchical coarse-graining in closed quantum systems reveals fluctuation forces and decoherence, drawing parallels with Boltzmann and Langevin approaches to understand macro-behavior emergence.

Contribution

It introduces a novel framework for analyzing closed quantum systems through hierarchical coarse-graining, connecting micro-dynamics to macro-behaviors and deriving fluctuation forces and decoherence.

Findings

Derived correlation noises in the BBGKY hierarchy.

Studied decoherence of lower order correlations using Boltzmann-Langevin equations.

Calculated quantum fluctuation forces via ordered coarse-graining.

Abstract

While the issues of dissipation, fluctuations, noise and decoherence in open quantum systems (with autocratic divide) analyzed via Langevin dynamics are familiar subjects, the treatment of corresponding issues in closed quantum systems is more subtle, as witnessed by Boltzmann's explanation of dissipation in a macroscopic system made up of many equal constituents (a democratic system). How to extract useful physical information about a closed democratic system with no obvious ways to distinguish one constituent from another, nor the existence of conservation laws governing certain special kinds of variables, e.g., the hydrodynamic variables -- this is the question we raise in this essay. Taking the inspirations from Boltzmann and Langevin, we study a) how a hierarchical order introduced to a closed democratic system -- defined either by substance or by representation, and b) how hierarchical coarse-graining, executed in a specific order, can facilitate our understanding in how macro-behaviors arise from micro-dynamics. We give two examples in: a) the derivation of correlation noises in the BBGKY hierarchy and how using a Boltzmann-Langevin equation one can study the decoherence of the lower order correlations; and b) the derivation of quantum fluctuation forces by ordered coarse-grainings of the relevant variables in the medium, the quantum field and the internal degrees of freedom of an atom.