Propulsion particle and potential application analysis based on fiber oriented laser propulsion micro-structures

Abstract

Three kinds of fiber oriented laser propulsion micro-structures (tapered fiber, fiber-capillary, and flat fiber micro-structure) were proposed in this study. The directional of the shock wave generated at the tip of the micro-structure, which can realize the directional propulsion of the particles. The propulsion mechanism, power source, and motion effect of the particles based on the three kinds of propulsion micro-structures were investigated. To better understand the physical mechanism behind the experimental phenomena, physical model of micro-structures were established. The experimental and simulation results demonstrate that the oriented laser propulsion based on three kinds of fiber propulsion micro-structures was dominated by the shock wave ejection mechanism, which was caused by the high pressure of the shock wave. By analyzing the positions of characteristic peaks in the plasma spectra, it is proved that the driving force of particle motion derives from the shock wave formed by the expansion of air plasma. In the process of particle oriented propulsion, it is found that the motion effect of particles strongly depends on the propulsion micro-structure design, laser energy, particle size as well as gap distance d, and it is found that compared with the tapered fiber and flat fiber micro-structure oriented propulsion experiment, the motion effect of particles based on fiber-capillary micro-structure propulsion experiment is more obvious. In addition, based on the characteristic that the fiber oriented laser propulsion micro-structures can realize the directional propulsion of particles, and the micro-structure has shown potential application value in microinjection, laser fun billiard ball, and directional removal of contamination particles inside microsystems, providing theoretical support for later research.