学术文献库

Among the many types of artificial motile nano- and microparticles that have been developed in the past, colloidal particles that exhibit propulsion when they are exposed to ultrasound are particularly advantageous. Their properties, however, are still largely unexplored. For example, the dependence of the propulsion on the particle shape and the structure of the flow field generated around the particles are still unknown. In this article, we address the propulsion mechanism of ultrasound-propelled nano- and microparticles in more detail. Based on direct computational fluid dynamics simulations and focusing on traveling ultrasound waves, we study the effect of two important aspects of the particle shape on the propulsion: rounded vs. pointed and filled vs. hollow shapes. We also address the flow field generated around such particles. Our results reveal that pointedness leads to an increase of the propulsion speed, whereas it is not significantly affected by hollowness. Furthermore, we find that the flow field of ultrasound-propelled particles allows to classify them as pusher squirmers, which has far-reaching consequences for the understanding of these particles and allows us to predict that they can be used to realize active materials with a tunable viscosity that can exhibit suprafluidity and even negative viscosities. The obtained results are helpful, e.g., for future experimental work further investigating or applying ultrasound-propelled colloidal particles as well as for theoretical approaches that aim at modeling their dynamics on mesoscopic scales.