Electrostatics overcome acoustic collapse to assemble, adapt, and activate levitated matter

TL;DR

This paper introduces a method combining acoustic levitation with electrostatic charging to prevent particle merging, enabling stable, adaptable, and dynamic manipulation of many-particle systems in mid-air.

Contribution

It presents a novel approach that uses electrostatics to overcome acoustic collapse, allowing controlled assembly, configuration changes, and activation of levitated particles.

Findings

Electrostatic charging prevents particle merging in acoustic levitation.

Stable, hybrid, and dynamic particle structures are demonstrated.

Large structures exhibit selective energy transfer, enabling complex motions.

Abstract

Acoustic levitation provides a unique method for manipulating small particles as it completely evades effects from gravity, container walls, or physical handling. These advantages make it a tantalizing platform for studying complex phenomena in many-particle systems, save for one severe limitation -- particles suspended by sound interact via acoustic scattering forces, which cause them to merge into a single dense object. To overcome this "acoustic collapse", we have developed a strategy that combines acoustic levitation with controlled electrostatic charging to assemble, adapt, and activate complex, many-particle systems. The key idea is to introduce electrostatic repulsion, which renders a so-called "mermaid" potential where interactions are attractive at short range and repulsive at long range. By controlling the balance between attraction/repulsion, we are able to levitate fully expanded structures where all particles are separated, fully collapsed structures where they are all in contact, and hybrid ones consisting of both expanded and collapsed components. We find that fully collapsed and expanded structures are inherently stable, whereas hybrid ones exhibit transient stability governed by acoustically unstable dimers. Furthermore, we show how electrostatics allow us to adapt between configurations on the fly, either by quasistatic discharge or discrete up/down charge steps. Finally, we demonstrate how large structures experience selective energy pumping from the acoustic field -- thrusting some particles into motion while others remain stationary -- leading to complex dynamics including coupled rotations and oscillations. Our approach provides an easy-to-implement and easy-to-understand solution to the pervasive problem of acoustic collapse, while simultaneously providing new insights into the assembly and activation of many-particle systems with complex interactions.