Dynamics of interacting particle systems: Modeling implications of the repulsive interactions and experiments on magnetic prototypes

TL;DR

This paper develops a comprehensive model for the dynamics of repulsively interacting particles, especially magnetic lattices, revealing how initial static forces influence wave behavior and confirming findings through laser vibrometry experiments.

Contribution

The paper introduces a general dynamical model for interacting particle systems with arbitrary potentials, highlighting the role of initial static forces and validating predictions with experiments.

Findings

Initial static forces affect wave dispersion in 2D lattices.

The model accurately predicts dispersive regimes confirmed by experiments.

Effects observed are absent in 1D chains.

Abstract

In this work, we investigate the dynamics of interacting particle systems subjected to repulsive forces, such as lattices of magnetized particles. To this end, we first develop a general model capable of capturing the complete dynamical behavior of interacting particle systems governed by arbitrary potentials. The model elucidates the important role played by the static repulsive forces exchanged between particles in the initial equilibrium configuration, which is distilled and mathematically captured by a dedicated component of the stiffness matrix. The implications of the model are then examined through the simple illustrative example of a magnetic particle oscillator, by which we show that the effect associated with the initial static forces is germane to two- or higher-dimensional particle systems and vanishes for 1D chains. In the context of wave propagation, we show that this type of effect manifests as modal-selective corrections of the dispersion relation of 2D repulsive lattices. To corroborate these findings, we perform laser vibrometry experiments on a lattice prototype consisting of a triangular grid of magnets supported by an elastic foundation of thin pillars. The tests unequivocally confirm the emergence of distinctive dispersive regimes in quantitative accordance to the model.