Acoustic Macroscopic Rigid Body Levitation by Responsive Boundary Hologram

TL;DR

This paper demonstrates a novel method for stably levitating macroscopic rigid bodies using holographic acoustic fields, expanding the range of levitatable objects without dynamic control, with potential applications in micromachines.

Contribution

It introduces a static holographic acoustic levitation technique for rigid bodies, modeling radiation forces and optimizing fields for stability without dynamic adjustments.

Findings

Successfully levitated a 50 mm octahedron in air

Used ultrasonic phased array at 40 kHz frequency

Achieved stable levitation with no dynamic control

Abstract

Propagated acoustic waves, which generate radiation pressure, exert a non-contact force on a remote object. By suitably designing the wave field, remote tweezers are produced that stably levitate particles in the air without any mechanical contact forces. Recent works have revealed that holographic traps can levitate particles even with a single-sided wave source. However, the levitatable objects in the previous studies were limited to particles smaller than the wavelength, or flat parts placed near a rigid wall. Here, we achieve a stable levitation of a macroscopic rigid body by a holographic design of acoustic field without any dynamic control. The levitator models the acoustic radiation force and torque applied to a rigid body by discretising the body's surface, as well as the acoustic wave sources, and optimizes the acoustic field on the body surface to achieve the Lyapunov stability so that the field can properly respond to the fluctuation of the body position and rotation. In an experiment, a 40 kHz (8.5 mm wavelength) ultrasonic phased array levitated a polystyrene sphere and a regular octahedron with a size of ~50 mm located 200 mm away from acoustic elements in the air. This method not only expands the variety of levitatable objects but also contributes to microscopic contexts, such as in-vivo micromachines, since shorter-wavelength ultrasound than the size of target objects can be used to achieve higher controllability and stability.