Tangency bifurcation of invariant manifolds in a slow-fast system

TL;DR

This paper investigates the complex bifurcations and chaotic oscillations in a three-dimensional slow-fast dynamical system, focusing on invariant manifold tangencies and their role in mixed-mode oscillations.

Contribution

It introduces a detailed analysis of tangency bifurcations of invariant manifolds in a slow-fast system and links these to chaotic mixed-mode oscillations and bifurcation structures.

Findings

Identification of tangency leading to chaos

Classification of mixed-mode oscillations

Bifurcation analysis of global returns

Abstract

We study a three-dimensional dynamical system in two slow variables and one fast variable. We analyze the tangency of the unstable manifold of an equilibrium point with "the" repelling slow manifold, in the presence of a stable periodic orbit emerging from a Hopf bifurcation. This tangency heralds complicated and chaotic mixed-mode oscillations. We classify these solutions by studying returns to a two-dimensional cross section. We use the intersections of the slow manifolds as a basis for partitioning the section according to the number and type of turns made by trajectory segments. Transverse homoclinic orbits are among the invariant sets serving as a substrate of the dynamics on this cross-section. We then turn to a one-dimensional approximation of the global returns in the system, identifying saddle-node and period-doubling bifurcations. These are interpreted in the full system as bifurcations of mixed-mode oscillations. Finally, we contrast the dynamics of our one-dimensional approximation to classical results of the quadratic family of maps. We describe the transient trajectory of a critical point of the map over a range of parameter values.