Orientation-dependent propulsion of cone-shaped nano- and microparticles by a traveling ultrasound wave

TL;DR

This study investigates how the propulsion of cone-shaped nano- and microparticles by traveling ultrasound waves varies with their orientation, revealing a tendency to align perpendicularly and providing insights for future applications.

Contribution

It introduces a detailed simulation analysis of orientation-dependent propulsion of cone-shaped particles, expanding understanding beyond previous perpendicular-only studies.

Findings

Propulsion depends strongly on particle orientation.

Particles tend to orient perpendicularly to wave direction.

Provides orientation-averaged velocities for isotropic ultrasound exposure.

Abstract

Previous studies on ultrasound-propelled nano- and microparticles have considered only systems where the particle orientation is perpendicular to the direction of propagation of the ultrasound. However, in future applications of these particles, they will typically be able to attain also other orientations. Therefore, using direct acoustofluidic simulations, we here study how the propulsion of cone-shaped nano- and microparticles, which are known to have a particularly efficient acoustic propulsion and are therefore promising candidates for future applications, depends on their orientation relative to the propagation direction of a traveling ultrasound wave. Our results reveal that the propulsion of the particles depends strongly on their orientation relative to the direction of wave propagation and that the particles tend to orient perpendicularly to the wave direction. We also present the orientation-averaged translational and angular velocities of the particles, which correspond to the particles' effective propulsion for an isotropic exposure to ultrasound. Our results allow assessing how free ultrasound-propelled colloidal particles move in three spatial dimensions and thus constitute an important step towards the realization of the envisaged future applications of such particles.