Within the framework of the Multidisciplinary Experimental and Modeling Impact
Research Network (MEMIN) research group, the damage zones underneath two
experimentally produced impact craters in sandstone targets were investigated using several
nondestructive testing (NDT) methods. The 20 · 20 · 20 cm sandstones were impacted by
steel projectiles with a radius of 1.25 mm at approximately 5 km s)1, resulting in craters with
approximately 6 cm diameter and approximately 1 cm depth. Ultrasound (US) tomography
and vibrational analysis were applied before and after the impact experiments to characterize
the damage zone, and micro-computer tomography (l-CT) measurements were performed to
visualize subsurface fractures. The newly obtained experimental data can help to quantify the
extent of the damage zone, which extends to about 8 cm depth in the target. The impacted
sandstone shows a local p-wave reduction of 18% below the crater floor, and a general
reduction in elastic moduli by between approximately 9 and approximately 18%, depending
on the type of elastic modulus. The results contribute to a better empirical and theoretical
understanding of hypervelocity events and simulations of cratering processes.
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Within the framework of the Multidisciplinary Experimental and Modeling Impact
Research Network (MEMIN) research group, the damage zones underneath two
experimentally produced impact craters in sandstone targets were investigated using several
nondestructive testing (NDT) methods. The 20 · 20 · 20 cm sandstones were impacted by
steel projectiles with a radius of 1.25 mm at approximately 5 km s)1, resulting in craters with
approximately 6 cm diameter and approximately 1 cm depth. Ultrasound...
»