Particle distributions in Lamb wave based acoustofluidics

Abstract

Acoustic streaming enabled by a Lamb wave resonator (LWR) is efficient for particle trapping and enrichment in microfluidic channels. However, because Lamb waves combine the features of bulk acoustic waves and surface acoustic waves, the resulting acoustic streaming in the LWR occurs in multiple planes, and the particle flow behavior in this acoustofluidic system is largely unknown. Reported here are numerical simulations and laboratory experiments conducted to investigate the boundary conditions for particle motion inside a microvortex induced by an LWR. Upon dynamic capture, the particles’ trajectories become orbital paths within an acoustic vortex. The suspended particles encounter two distinct acoustic phenomena, i.e., the drag force resulting from acoustic streaming and the acoustic radiation force, which exert forces in various directions on the particles. When the acoustic radiation force and the fluid drag force are dominant for large and small particles in a mixed solution, respectively, the large particles reside within the vortex while the small particles remain at its periphery. Conversely, when the acoustic radiation force is dominant for both types of particles, the distribution pattern is reversed.