Macroscopic Determinism in Interacting Systems Using Large Deviation Theory
Abstract
We consider the quasi-deterministic behavior of systems with a large number, , of deterministically interacting constituents. This work extends the results of a previous paper [J. Stat. Phys. 99:1225-1249 (2000)] to include vector-valued observables on interacting systems. The approach used here, however, differs markedly in that a level-1 large deviation principle (LDP) on joint observables, rather than a level-2 LDP on empirical distributions, is employed. As before, we seek a mapping on the set of (possibly vector-valued) macrostates such that, when the macrostate is given to be at time zero, the macrostate at time is with a probability approaching one as tends to infinity. We show that such a map exists and derives from a generalized dynamic free energy function, provided the latter is everywhere well defined, finite, and differentiable. We discuss some general properties of relevant to issues of irreversibility and end with an example of a simple interacting lattice, for which an exact macroscopic solution is obtained.
Keywords
Cite
@article{arxiv.2104.13313,
title = {Macroscopic Determinism in Interacting Systems Using Large Deviation Theory},
author = {Brian R. La Cour and William C. Schieve},
journal= {arXiv preprint arXiv:2104.13313},
year = {2021}
}
Comments
31 pages, 4 figures