Tunable mechanical properties and air-based lubrication in an acoustically levitated granular material

TL;DR

This study explores how acoustic levitation can create tunable, cohesive granular materials with adjustable mechanical properties and air-based lubrication, providing a new experimental platform for granular physics research.

Contribution

It introduces a novel acoustic levitation method to control cohesion and lubrication in granular materials, enabling detailed mechanical property investigations.

Findings

Rafts deform under varying acoustic pressure

Air layers act as lubricants reducing friction between grains

Acoustic forces can tune cohesion strength

Abstract

Cohesive granular materials are found in many natural and industrial environments, but experimental platforms for exploring the innate mechanical properties of these materials are often limited by the difficulty of adjusting cohesion strength. Granular particles levitated in an acoustic cavity form a model system to address this. Such particles self-assemble into free-floating, quasi-two-dimensional raft structures which are held together by acoustic scattering forces; the strength of this attraction can be changed simply by modifying the sound field. We investigate the mechanical properties of acoustically bound granular rafts using substrate-free micro-scale shear tests. We first demonstrate deformation of rafts of spheres and the dependence of this deformation on acoustic pressure. We then apply these methods to rafts composed of anisotropic sand grains and smaller spheres, in which the smaller spheres have a thin layer of air separating them from other grain surfaces. These spheres act as soft, effectively frictionless particles that populate the interstices between the larger grains, which enables us to investigate the effect of lubricating the mixture in the presence of large-grain cohesion.