Sink-rise dynamics of horizontally oscillating active matter in granular media: Theory

TL;DR

This paper develops a theoretical model and simulations to understand how active objects oscillating horizontally in granular media can rise or sink depending on their oscillation parameters, revealing complex nonlinear dynamics.

Contribution

It introduces a first-principles theoretical framework for the sink-rise behavior of active objects in granular media, supported by simulation validation.

Findings

Active objects can rise or sink depending on oscillation speed and energy.

A critical speed $v_c$ determines the transition between rising and sinking.

The model accurately predicts the observed nonlinear dynamics.

Abstract

An intermediate step to modelling behaviour of active matter is understanding interactions of active objects (AOs) with inanimate matter, which often lead to a range of rich behaviour. We present a range of simulations of the interaction of a self-energised AO with three-dimensional granular matter and develop a first-principles theoretical model to describe the observed phenomena. The AO oscillates horizontally, which causes it to either rise against gravity or sink, depending on the oscillation amplitude and frequency. We identify two competing mechanisms that drive the vertical motion. When the AO moves below a critical speed, $v_c$, it generates a jammed stagnant zone ahead of it, which effects an upward force and leads to the rise. Above $v_c$ and certain kinetic energy, the medium around the AO fluidises and the AO sinks into the layer supporting it. The duration of the rising and sinking phases depend non-trivially on the AO's amplitude and frequency leading to an intricate nonlinear dynamics. We derive the equation of motion for the time-dependent depth from first-principles and show that its solutions agree well with a wide range of computer simulations, which we perform within the range of parameters allowed by the finiteness of the simulated system.