The Quantum Ratio
Abstract
The concept of {\it quantum ratio} emerged in the recent efforts to understand how Newton's equations appear for the center of mass (CM) of an isolated macroscopic body at finite body-temperatures, as the first approximation to quantum-mechanical equations. It is defined as , where the quantum fluctuation range is the spatial extension of the pure-state CM wave function, whereas stands for the body's linear size (the space support of the internal, bound-state wave function). The two cases or , roughly correspond to the body's CM behaving classically or quantum mechanically, respectively. In the present note we elaborate more on this concept, illustrating it in several examples. An important notion following from introduction of the quantum ratio is that the elementary particles (thus the electron and the photon) are quantum mechanical, even when the environment-induced decoherence turns them into a mixed state. Decoherence and classical state should not be identified. This simple observation, further illustrated by the consideration of a few atomic or molecular processes, may have significant implications on the way quantum mechanics works in biological systems.
Cite
@article{arxiv.2402.10702,
title = {The Quantum Ratio},
author = {Hans-Thomas Elze and Kenichi Konishi},
journal= {arXiv preprint arXiv:2402.10702},
year = {2024}
}
Comments
34 pages, 8 figures