The response of dry and water saturated silica sand to high velocity impact

The dynamic penetration of projectiles into brittle granular materials is important in a broad range of fields including planetary science and defense. As a projectile impacts a granular material, various material mechanisms are activated, including grain fracture, plasticity, fragmentation, granular flow, and pore collapse. Experimental visualization and quantification of these mechanisms is extremely difficult without disrupting the mechanisms at work; however, quantifying of the role of each mechanisms in projectile behavior is essential for validation of constitutive laws. In this poster we discuss a novel approach to visualizing and quantifying the 3D flow fields inside a sand sample during penetration by using lead tracer particles that are embedded in matrix of sand and a radiographic image generation algorithm. The 3D positions of the lead particles are known prior to impact from X-ray computed tomography. During impact, two orthogonally placed flash x-ray sources capture the displacement of the lead particles in a single instance of time. By using a known position of particles both before and during penetration and an optimization scheme employing the image generation algorithm, a full 3D flow field can be obtained. The 3D flow fields are investigated for both dry and saturated sand samples at different times during penetration.