English

Macroscopic Determinism in Interacting Systems Using Large Deviation Theory

Statistical Mechanics 2021-04-28 v1

Abstract

We consider the quasi-deterministic behavior of systems with a large number, nn, 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 ψt\psi_{t} on the set of (possibly vector-valued) macrostates such that, when the macrostate is given to be a0a_0 at time zero, the macrostate at time tt is ψt(a0)\psi_{t}(a_0) with a probability approaching one as nn 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 ψt\psi_{t} 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

R2 v1 2026-06-24T01:34:15.428Z