学术文献库

This paper discusses laser-induced flow stabilizing of Rayleigh particle jets. Laser technology, has important applications in micro/nano-scale static monomer particle operations, such as optical tweezers, or is used for the passive measurement of macroscopic physical features of particle groups. However, it is relatively rare for the laser beam to directly interfere with the behavior of particle populations dynamically, so as to achieve the purpose of instant group manipulations. Based on the theoretical analysis of particle dynamics and hydrodynamic stability theory, the effects of light induced convergence on rarified jets (as a point source emitting particle off a nozzle) and denser jets consists of Rayleigh sized particles have been considered. For rarified particle jet's analysis, compared with the classical vacuum evaporation deposition theory, we found that the laser positively guided the movement of particles, leading their pathes into more concentrated targets. Such convergence effect also happens in the case of denser Rayleigh particle jets. Particle dynamics simulations and hydrodynamic stability analysis mutually authenticated that the optical field forces suppress the instability both of long-wave and short-wave on particle jet interfaces, and have broad-spectrum stabilization characteristics. Therefor, diffusive particles in vacuum evaporation can also have very good targeted aggregations by laser.