Dynamical motion of a pair of microparticles at the acoustic pressure nodal plane under the combined effect of axial primary radiation and interparticle forces

Abstract: The dynamical motion of a pair of microparticles exposed to acoustic standing waves and located at the pressure nodal plane is studied using numerical simulations and experiments. The insight into their dynamical behavior along the pressure nodal plane due to the competition between the axial primary radiation and interparticle forces is elucidated. An expression for axial primary radiation force acting on a particle is derived, and the particle dynamics is simulated using fluid-structure interaction model bas… Show more

“…[31][32][33] Recently, the influence of cavity and interface on ARF has been evaluated. [34][35][36] The concept of "acoustic tweezers" emphasizes the construction of acoustic potential wells for particle manipulation and trapping. In actual scenes, the sound source is often confined to a small angle relative to the particles.…”

Scheme of negative acoustic radiation force based on a multiple-layered spherical structure

“…[31][32][33] Recently, the influence of cavity and interface on ARF has been evaluated. [34][35][36] The concept of "acoustic tweezers" emphasizes the construction of acoustic potential wells for particle manipulation and trapping. In actual scenes, the sound source is often confined to a small angle relative to the particles.…”

Scheme of negative acoustic radiation force based on a multiple-layered spherical structure

Applications of Microfluidics

Internal resonance induced nonlinear vibration and acoustic radiation of a hyperelastic cantilever structure immersed in fluid