Impact Erosion Model for Gravity-Dominated Planetesimals
H. Genda, T. Fujita, H. Kobayashi, H. Tanaka, R. Suetsugu, Y. Abe

TL;DR
This paper develops a new impact erosion model for gravity-dominated planetesimals, highlighting how ejected mass depends on impact energy and target parameters, and providing a unified scaling law for erosive collisions.
Contribution
It introduces a comprehensive erosion model based on impact simulations, linking ejected mass to impact energy normalized by disruption thresholds for planetesimals.
Findings
Ejected mass scales with impact energy and target size.
Erosion depends only on Q_R/Q_RD^* for small impacts.
A new erosion model for planetesimal collisions is proposed.
Abstract
Disruptive collisions have been regarded as an important process for planet formation, while non-disruptive, small-scale collisions (hereafter called erosive collisions) have been underestimated or neglected by many studies. However, recent studies have suggested that erosive collisions are also important to the growth of planets, because they are much more frequent than disruptive collisions. Although the thresholds of the specific impact energy for disruptive collisions (Q_RD^*) have been investigated well, there is no reliable model for erosive collisions. In this study, we systematically carried out impact simulations of gravity-dominated planetesimals for a wide range of specific impact energy (Q_R) from disruptive collisions (Q_R ~ Q_RD^*) to erosive ones (Q_R << Q_RD^*) using the smoothed particle hydrodynamics method. We found that the ejected mass normalized by the total mass…
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