Insight into the Distribution of High-pressure Shock Metamorphism in Rubble-pile Asteroids

TL;DR

This study models shock metamorphism in rubble-pile asteroids to understand impact effects, revealing impact velocity and size as key factors influencing shock-darkening, with limited high-grade shock features observed.

Contribution

It provides the first detailed modeling of shock metamorphism distribution in rubble-pile asteroids considering impact velocity, porosity, and impactor size.

Findings

Impact velocity and impactor size are primary factors in shock-darkening.

High-grade shock features are rare, occurring in less than 20% of material.

Significant material escape occurs during impacts, but shock-darkening is limited to a small fraction.

Abstract

Shock metamorphism in ordinary chondrites allows for reconstructing impact events between asteroids in the main asteroid belt. Shock-darkening of ordinary chondrites occurs at the onset of complete shock melting of the rock (>70 GPa) or injection of sulfide and metal melt into the cracks within solid silicates (\sim 50 GPa). Darkening of ordinary chondrites masks diagnostic silicate features observed in the reflectance spectrum of S-complex asteroids so they appear similar to C/X-complex asteroids. In this work, we investigate the shock pressure and associated metamorphism pattern in rubble-pile asteroids at impact velocities of 4-10 km/s. We use the iSALE shock physics code and implement two-dimensional models with simplified properties in order to quantify the influence of the following parameters on shock-darkening efficiency: impact velocity, porosity within the asteroid, impactor size, and ejection efficiency. We observe that, in rubble-pile asteroids, the velocity and size of the impactor are the constraining parameters in recording high-grade shock metamorphism. Yet, the recorded fraction of higher shock stages remains low (<0.2). Varying the porosity of the boulders from 10% to 30% does not significantly affect the distribution of pressure and fraction of shock-darkened material. The pressure distribution in rubble-pile asteroids is very similar to that of monolithic asteroids with the same porosity. Thus, producing significant volumes of high-degree shocked ordinary chondrites requires strong collision events (impact velocities above 8 km/s and/or large sizes of impactors). A large amount of asteroid material escapes during an impact event (up to 90%); however, only a small portion of the escaping material is shock-darkened (6%).