Scaling laws for the oblique impact cratering on an inclined granular surface

Although a large number of astronomical craters are actually produced by the oblique impacts onto inclined surfaces, most of the laboratory experiments mimicking the impact cratering have been performed by the vertical impact onto a horizontal target surface. In previous studies on the effects of oblique impact and inclined terrain, only one of the impact angle phi or target inclination angle theta has been varied in the experiments. Therefore, we perform impact-cratering experiments by systematically varying both phi and theta. A solid projectile of diameter D-i = 6 mm is impacted onto a sand surface with the range of impact velocity v(i) = 7-97 m s(-1). From the experimental result, we develop scaling laws for the crater dimensions on the basis of Pi-group scaling. As a result, the crater dimensions such as cavity volume, diameter, aspect ratio, and depth-diameter ratio can be scaled by the factors sin phi and cos theta as well as the usual impact parameters (v(i), D-i, density of projectile, and surface gravity). Finally, we consider the possible application of the obtained scaling laws to estimate impact conditions (e.g., impact speed and impact angle) in natural crater records.