Resurfacing processes constrained by crater distribution on Ryugu

TL;DR

This study analyzes crater distributions on asteroid Ryugu to evaluate geological modification processes, finding that seismic shaking models do not explain crater patterns and suggesting surface flows as an alternative resurfacing mechanism.

Contribution

The paper demonstrates that seismic diffusion models cannot account for crater distributions on Ryugu, proposing surface flows as a more plausible process for asteroid surface modification.

Findings

Seismic shaking models are inconsistent with observed crater distributions.

Surface flows may be responsible for geological features on Ryugu.

Resurfacing timescales are comparable to cosmic-ray exposure ages.

Abstract

Understanding the geological modification processes on asteroids can provide information concerning their surface history. Images of small asteroids from spacecraft show a depletion in terms of smaller craters. Seismic shaking was considered to be responsible for crater erasure and the main driver modifying the geology of asteroids via regolith convection or the Brazil nut effect. However, a recent artificial impact experiment on the asteroid Ryugu by the Japanese Hayabusa2 mission revealed minimal seismic activity. To investigate whether a seismic shaking model can reproduce the observed crater record, the crater distribution on Ryugu was analyzed using crater production functions under cohesionless conditions. Crater retention ages were estimated as a function of crater diameter for Ryugu, Itokawa, Eros, and Bennu using the crater size-frequency distribution and crater production function estimated for those asteroids. We found that the power-law indices "a" are inconsistent with diffusion processes (e.g., seismic shaking, a=2). This result suggests that seismic shaking models based on diffusion equations cannot explain the crater distribution on small asteroids. Alternative processes include surface flows, possibly at the origin of geomorphological and spectral features of Ryugu. We demonstrate that the vertical mixing of material at depths shallower than 1 m occurs over 10^3-10^5 yr by cratering and obliteration. The young surface age of Ryugu is consistent with the slow space weathering that results from cratering, as suggested in previous studies. The timescale (10^4-10^6 yr) required for resurfacing at depths of 2-4 m can be compared with the cosmic-ray exposure ages of returned samples to constrain the distribution of impactors that collide with Ryugu.