Numerical and experimental investigations on the interaction of light wire-array Z-pinches with embedded heavy foam converters

Summary form only given. The interaction of a light tungsten wire-array Z-pinch with an embedded heavy foam converter, which mass ratio is typically less than 0.16, is numerically analyzed and experimentally investigated on the 1.3MA “QiangGuang I” facility. Computational results show that this implosion process can be divided into three stages: acceleration of the tungsten wire-array plasma, collision, and stagnation. The tungsten plasma is accelerated to a high speed by the J×B force and interacts weakly with the foam plasma in the first stage. Strong energy conversions take place in the second collision stage. When the high speed tungsten plasma impacts on the foam converter, the plasma is thermalized and a radial radiation peak is produced. Meanwhile, a shock wave is generated due to the collision. After the shock rebounds from the axis and meets the W/Foam boundary, the plasma stagnates and the second radial radiation peak appears. The collision and stagnation processes were observed and the two-peak radial radiation pulse was produced in experiments. Increasing the wire-array radius from 4mm to 6mm, the kinetic energy of the tungsten plasma is increased, causing a stronger thermaliztion and generating a higher first radiation peak. Experimental results also showed a higher ratio of the first peak to the second peak in the case of larger wire-array radius. If we add a thin CH film cover onto the surface of the embedded foam converter, the first radiation peak will change less, because the acceleration of the tungsten plasma is not evidently affected by the film cover. However, the second radiation peak decreases remarkably due to the high load mass and the corresponding weak compression.