Internal Wave Attractors in 3D Geometries : a dynamical systems approach

TL;DR

This paper explores the behavior of internal waves in three-dimensional geometries using dynamical systems theory, revealing new trapping mechanisms and structures like super-attractors that confine wave energy.

Contribution

It introduces a dynamical systems approach to 3D internal wave propagation, identifying new trapping mechanisms and the existence of super-attractors in complex geometries.

Findings

Identification of a new wave trapping mechanism aligning with upslope gradients

Existence of trapezium-shaped 2D attractors in simple geometries

Discovery of a 3D super-attractor structure confining wave energy

Abstract

We study the propagation in three dimensions of internal waves using ray tracing methods and traditional dynamical systems theory. The wave propagation on a cone that generalizes the Saint Andrew's cross justifies the introduction of an angle of propagation that allows to describe the position of the wave ray in the horizontal plane. Considering the evolution of this reflection angle for waves that repeatedly reflect off an inclined slope, a new trapping mechanism emerges that displays the tendency to align this angle with the upslope gradient. In the rather simple geometry of a translationally invariant canal, we show first that this configuration leads to trapezium-shaped attractors, very similar to what has been extensively studied in two-dimensions. However, we also establish a direct link between the trapping and the existence of two-dimensional attractors. In a second stage, considering a geometry that is not translationally invariant, closer to realistic configurations, we prove that although there are no two-dimensional attractors, one can find a structure in three-dimensional space with properties similar to internal wave attractors: a one-dimensional attracting manifold. Moreover, as this structure is unique, it should be easy to visualize in laboratory experiments since energy injected in the domain would eventually be confined to a very thin region in three-dimensional space, for which reason it is called a super-attractor.