Multi-ring basins are features produced by the collision of solid bodies with the planets, so the basin problem is a subset of the more general problem of impact cratering, a vast field of study. This chapter briefly describes the impact process from theoretical considerations, from the evidence of some well studied terrestrial impact craters, and from the observed morphology of impact craters on the Moon and their systematic changes with increasing crater size.

The cratering process

Impact mechanics

Our understanding of what happens when a solid body hits a planetary surface at high speeds has increased greatly over the past 25 years. The study of the physical processes occurring during impact events is called impact mechanics. Although the details of this complex process are not understood, laboratory experiments, explosion craters, natural impact craters, and computer simulations have given us a general outline of the main stages that characterize the formation of an impact crater.

Solid bodies collide with planetary surfaces at very high speeds; such impact speeds are in the range called hypervelocity. Encounter velocities can vary from lunar escape velocity (about 2.5 km/s) at a minimum, up to many tens of kilometers per second (on the basis of velocities of bodies in heliocentric orbits). On the Moon, the mean impact velocity is about 20 km/s (Shoemaker, 1977). At the moment of contact between an impactor and a planet, the kinetic energy of the impacting body is transferred to the planetary surface target. A shock wave propagates into the target and projectile, resulting in intensive compression of both objects. In hypervelocity impacts, the quantities of energy produced greatly exceed the heat of vaporization for geological materials.