Melnikov theory for two-dimensional manifolds in three-dimensional flows

TL;DR

This paper develops a Melnikov method to analyze the dynamics of two-dimensional manifolds in three-dimensional flows, providing tools to quantify manifold splitting, intersections, and transport phenomena in fluid mechanics.

Contribution

It introduces a generalized Melnikov approach for non-volume preserving 3D systems, applicable to fluid flow separators and vortex models, with explicit formulas for manifold splitting and flux.

Findings

Derived formulas for lobe volumes and flux in perturbed systems.

Applied the theory to Hill's spherical vortex models.

Quantified manifold splitting and intersections in 3D fluid flows.

Abstract

We present a Melnikov method to analyze two-dimensional stable or unstable manifolds associated with a saddle point in three-dimensional non-volume preserving autonomous systems. The time-varying perturbed locations of such manifolds is obtained under very general, non-volume preserving and with arbitrary time-dependence, perturbations. In unperturbed situations with a two-dimensional heteroclinic manifold, we adapt our theory to quantify the splitting into a stable and unstable manifold, and thereby obtain a Melnikov function characterizing the time-varying locations of transverse intersections of these manifolds. Formulas for lobe volumes arising from such intersections, as well as the instantaneous flux across the broken heteroclinic manifold, are obtained in terms of the Melnikov function. Our theory has specific application to transport in fluid mechanics, where the flow is in three dimensions and flow separators are two-dimensional stable/unstable manifolds. We demonstrate our theory using both the classical and the swirling versions of Hill's spherical vortex.