Application of background-oriented schlieren (BOS) technique to a laser-induced underwater shock wave

Abstract

We build an ultra-high-speed imaging system based on the background-oriented schlieren (BOS) technique in order to capture a laser-induced underwater shock wave. This BOS technique is able to provide two-dimensional density-gradient field of fluid and requires a simple setup. The imaging system consists of an ultra-high speed video camera, a laser stroboscope, and a patterned background. This system takes images every 0.2 μs. Furthermore, since the density change of water disturbed by the shock is exceedingly small, the system has high spatial resolution 10 μm/pixel. Using this BOS system, we examine temporal position of a shock wave. The position agrees well with that measured by conventional shadowgraph, which indicates that the high-speed imaging system can successfully capture the instantaneous position of the underwater shock wave that propagates with the speed of about 1500 m/s. The local density gradient can be determined up to O(103 kg/m4), which is confirmed by the gradient estimated from the pressure time history measured by a hydrophone.