Weak and strong chaos in FPU models and beyond

TL;DR

This paper reviews key results on the dynamics of FPU models, highlighting two types of chaos transitions, a geometric theory of Hamiltonian chaos, and the link between chaos and phase transitions.

Contribution

It introduces the concepts of Stochasticity Threshold and Strong Stochasticity Threshold, and develops a Riemannian geometric framework to explain Hamiltonian chaos and its relation to phase transitions.

Findings

Existence of two chaos transition thresholds in FPU models

Development of a Riemannian geometric theory for Hamiltonian chaos

Identification of a sharp SST as a thermodynamic phase transition counterpart

Abstract

We briefly review some of the most relevant results that our group obtained in the past, while investigating the dynamics of the Fermi-Pasta-Ulam (FPU) models. A first result is the numerical evidence of the existence of two different kinds of transitions in the dynamics of the FPU models: i) a Stochasticity Threshold (ST), characterized by a value of the energy per degree of freedom below which the overwhelming majority of the phase space trajectories are regular (vanishing Lyapunov exponents). It tends to vanish as the number N of degrees of freedom is increased. ii) a Strong Stochasticity Threshold (SST), characterized by a value of the energy per degree of freedom at which a crossover appears between two different power laws of the energy dependence of the largest Lyapunov exponent, which phenomenologically corresponds to the transition between weakly and strongly chaotic regimes. It is stable with N. A second result is the development of a Riemannian geometric theory to explain the origin of Hamiltonian chaos. The starting of this theory has been motivated by the inadequacy of the approach based on homoclinic intersections to explain the origin of chaos in systems of arbitrarily large N, or arbitrarily far from quasi-integrability, or displaying a transition between weak and strong chaos. Finally, a third result stems from the search for the transition between weak and strong chaos in systems other than FPU. Actually, we found that a very sharp SST appears as the dynamical counterpart of a thermodynamic phase transition, which in turn has led, in the light of the Riemannian theory of chaos, to the development of a topological theory of phase transitions.