Scrambling at the genesis of chaos

TL;DR

This paper explores the universal transition from local instability to global chaos in Hamiltonian systems, deriving analytical expressions and validating with the kicked rotor and driven pendulum models.

Contribution

It provides an analytical framework describing the transition from instability to chaos, unifying the resonance scenario with exponential growth indicators.

Findings

Derived an analytical expression for the evolution near separatrices.

Demonstrated the universality of the transition mechanism.

Validated results with the kicked rotor and driven pendulum examples.

Abstract

The presence of chaos in classical Hamiltonian systems is witnessed by its maximal Lyapunov exponent, that quantifies the instability of motion through the exponential growth of indicators such as the trace of the stability matrix or the out-of-time-ordered correlator. On the other hand, integrable dynamics near unstable fixed points, which are in turn characterized by a stability exponent, can also induce such exponential growth. Following the paradigm of integrability-breaking as driven by nonlinear resonances that hallmarks the genesis of chaos, the integrability-chaos transition is universally described by a periodic perturbation applied to a generic pendulum. Remarkably, this means that within the corresponding separatrix dynamics, which is an unavoidable a consequence of the resonance scenario, both instability exponents must play a role as both dynamical regimes coexist. We report here the universality of the transition from instability to Lyapunov exponents, thus completing the resonance scenario at the level of indicators based on exponential growth. To achieve this goal we obtain an analytical expression for the time evolution near separatrices, which enables us to derive an analytical expression for the exponent that characterises chaos and its transition from local instability to global chaos. We support our claim for the universality of this mechanism by studying two paradigmatic examples of the integrability-to-chaos transition, namely the kicked rotor and the driven pendulum.