Collisional disruption of highly porous targets in the strength regime: Effects of mixture

Abstract: Highly porous small bodies are thought to have been ubiquitous in the early solar system. Therefore, it is essential to understand the collision process of highly porous objects when considering the collisional evolution of primitive small bodies in the solar system. To date, impact disruption experiments have been conducted using high-porosity targets made of ice, pumice, gypsum, and glass, and numerical simulations of impact fracture of porous bodies have also been conducted. However, a variety of internal s… Show more

“…The largest craters relative to the host boulders may represent the largest sub-disruption impact sizes allowable. Laboratory impact experiments show that this is possible for impacts onto porous targets [11]; however, the largest possible craters on non-porous consolidated targets, produced through spall (fracturing and ejection of plate-like near-surface fragments), are created by impacts that are a factor of a few less than the disruption threshold [12]. Therefore, equating the formation of the largest possible crater to the catastrophic disruption threshold is a viable framework, as CM and CI meteorites-the meteoritic analogs to Bennu's boulders-have high porosities (≳ 20% [13]) and Bennu's boulders show little evidence for spalls.…”

“…An object's response to an impact is dominated by one of these strengths. The formation of welldefined deep craters, as observed on Bennu's boulders, is typically dominated by shear [19] or compressive strength [11]. In contrast, impacts onto brittle material lead to shallow spall craters formed by tensile failure.…”

Bennu’s near-Earth lifetime of 1.75 million years inferred from craters on its boulders

“…The largest craters relative to the host boulders may represent the largest sub-disruption impact sizes allowable. Laboratory impact experiments show that this is possible for impacts onto porous targets [11]; however, the largest possible craters on non-porous consolidated targets, produced through spall (fracturing and ejection of plate-like near-surface fragments), are created by impacts that are a factor of a few less than the disruption threshold [12]. Therefore, equating the formation of the largest possible crater to the catastrophic disruption threshold is a viable framework, as CM and CI meteorites-the meteoritic analogs to Bennu's boulders-have high porosities (≳ 20% [13]) and Bennu's boulders show little evidence for spalls.…”

“…An object's response to an impact is dominated by one of these strengths. The formation of welldefined deep craters, as observed on Bennu's boulders, is typically dominated by shear [19] or compressive strength [11]. In contrast, impacts onto brittle material lead to shallow spall craters formed by tensile failure.…”

Bennu’s near-Earth lifetime of 1.75 million years inferred from craters on its boulders

9th workshop on Catastrophic Disruption in the Solar System (CD9)

Impact Cratering at the Lunar Ina Irregular Mare Patch (IMP): Experimental Evidence for the Nature of Impacts Into Porous Basaltic Substrate and Outstanding Questions