Dynamics of Acoustically Bound Particles

It is well known that acoustic fields can produce forces on single particles, however they can also induce inter-particle forces due to multiple scattering events. This multi-particle force -- here referred to as acoustic binding -- is comparable to other acoustic forces when the particles are of order wavelength in diameter. In principle, this force could be used as a tunable method for directing the assembly of particles of mm-scales, but has not been extensively explored in previous work. Here, we use a novel numerical method to compute binding interactions between strongly scattering bodies and find that they can produce stable clusters of particles with approximately wavelength separation. Moreover, we also observe that -- depending on the level of damping -- these structures can produce driven linear, rotational, or vibrational motion. These effects are a result of the non-conservative and non-pairwise nature of the acoustic binding force, and represent novel contactless manipulation and transport methods with potential application to metamaterial synthesis and drug delivery.