Nonlinear Localized Modes in Two-Dimensional Hexagonally-Packed Magnetic Lattices

TL;DR

This study investigates nonlinear localized modes in a 2D hexagonal magnetic lattice, combining experiments and modeling to reveal direction-dependent decay, bifurcations, and quasi-periodic solutions.

Contribution

It provides the first experimental and theoretical analysis of nonlinear localized modes in a 2D hexagonal magnetic lattice with detailed bifurcation and resonance behavior.

Findings

Direction-dependent spatial decay of NLMs.

Drive amplitude induces bifurcations to asymmetric NLMs.

Observation of time-quasi-periodic bifurcations from symmetric NLMs.

Abstract

We conduct an extensive study of nonlinear localized modes (NLMs), which are temporally periodic and spatially localized structures, in a two-dimensional array of repelling magnets. In our experiments, we arrange a lattice in a hexagonal configuration with a light-mass defect, and we harmonically drive the center of the chain with a tunable excitation frequency, amplitude, and angle. We use a damped, driven variant of a vector Fermi- Pasta-Ulam-Tsingou lattice to model our experimental setup. Despite the idealized nature of the model, we obtain good qualitative agreement between theory and experiments for a variety of dynamical behaviors. We find that the spatial decay is direction-dependent and that drive amplitudes along fundamental displacement axes lead to nonlinear resonant peaks in frequency continuations that are similar to those that occur in one-dimensional damped, driven lattices. However, driving along other directions leads to the creation of asymmetric NLMs that bifurcate from the main solution branch, which consists of symmetric NLMs. When we vary the drive amplitude, we observe such behavior both in our experiments and in our simulations. We also demonstrate that solutions that appear to be time-quasi-periodic bifurcate from the branch of symmetric time-periodic NLMs.