Using the youngest asteroid clusters to constrain the Space Weathering and Gardening rate on S-complex asteroids

TL;DR

This study investigates the space weathering and regolith gardening rates on S-complex asteroids by analyzing very young asteroid clusters and pairs, providing new constraints on surface evolution timescales and formation mechanisms.

Contribution

The paper extends space weathering models to include regolith gardening effects and provides the first direct measurements of gardening and weathering timescales for S-complex asteroids.

Findings

Young asteroid clusters have colors consistent with previous models.

Very young asteroid pairs are redder than predicted, suggesting gentle separation mechanisms.

The derived gardening time significantly differs from impact rate estimates, implying a 'honeycomb' regolith structure.

Abstract

We have extended our earlier work on space weathering of the youngest S-complex asteroid families to include results from asteroid clusters with ages <10^6 years and to newly identified asteroid pairs with ages <5x10^5 years. We have identified three S-complex asteroid clusters with ages in the range 10^{5-6} years. The average color of the objects in these clusters agree with the prediction of Willman et al., 2008. SDSS photometry of the members of very young asteroid pairs with ages <10^5 years was used to determine their taxonomy. The average color of the S-complex pairs is PC_1=0.49+/-0.03, over 5-sigma redder than predicted by Willman et al., 2008. Therefore, the most likely pair formation mechanism is gentle separation due to YORP spin-up leaving much of the aged and reddened surface undisturbed. In this case our color measurement allows us to set an upper limit of ~64% on the disturbed surface portion. Using pre-existing color data and our new results for the youngest S-complex asteroid clusters we have extended our space weather model to explicitly include the effects of regolith gardening and fit separate weathering and gardening characteristic timescales of tau_w=960+/-160My and tau_g=2000+/-290My respectively. The first principal component color for fresh S-complex material is 0.37+/-0.01 while the maximum amount of local reddening is 0.33+/-0.06. Our first-ever determination of the gardening time is in stark contrast to our calculated gardening time of tau_g~270My based on main belt impact rates and reasonable assumptions about crater and ejecta blanket sizes. A possible resolution for the discrepancy is through a `honeycomb' mechanism in which the surface regolith structure absorbs small impactors without producing significant ejecta. This mechanism could also account for the paucity of small craters on (433) Eros.