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- Title
Boulder Distributions Around Young, Small Lunar Impact Craters and Implications for Regolith Production Rates and Landing Site Safety.
- Authors
Watkins, R. N.; Jolliff, B. L.; Mistick, K.; Fogerty, C.; Lawrence, S. J.; Singer, K. N.; Ghent, R. R.
- Abstract
We use Lunar Reconnaissance Orbiter Camera Narrow Angle Camera images to characterize boulder populations around six small (<1 km), young (<200 Ma) impact craters near spacecraft landing sites. The Narrow Angle Camera boulder counts are used to analyze how boulder distributions vary around craters of different sizes and ages. These comparisons inform how various properties affect the distance to which boulders are ejected and the size and density of boulders produced by an impact event. The counts show that boulder population densities decrease with crater age, with few boulders remaining at craters older than a few hundred million years, consistent with results of other studies of boulder degradation rates on the Moon. Variations in boulder distributions around younger craters may provide information regarding impact conditions; South Ray crater has a larger population of small boulders than the larger North Ray crater, which could be explained by variations in impact velocity. Large craters generally excavate more boulders than smaller craters, and the size of the largest boulder ejected is related to crater size by a power‐law function. Larger boulders occur closer to the crater rim (within 2–4 crater radii), whereas smaller boulders occur at all distances. The density of boulders is greater near the crater rim and decreases with increasing radial distance; this data can aid in establishing safe landing zones for future missions. Analyzing boulder distributions across craters of varying ages allows us to test models of boulder breakdown rates, with implications for understanding the Moon's regolith production rate. Plain Language Summary: Many of the boulders found on the surface of the Moon are located around impact craters. Over time, these boulders break down, primarily as a result of being bombarded with small meteorites. Correlating the abundance of boulders with the age of the crater they are located around can inform how long it takes for boulders to break down and become part of the regolith (the Moon's soil). We used high‐resolution images from the Lunar Reconnaissance Orbiter Camera to measure and count boulders around six young lunar impact craters. We found that it takes a few hundred million years for boulders to begin disappearing due to degradation. We also analyzed how boulder distributions change with increasing distance from the crater rim, and we find that more small boulders occur at greater distances than large boulders. Understanding how boulder distributions vary around craters of different sizes and ages is important in planning for the safety of future landed missions to the lunar surface. Key Points: Few boulders remain at craters older than a few hundred million yearsDetermining boulder size distributions as a function of distance from a crater is key in assessing boulder hazards for future missionsLunar Reconnaissance Orbiter Camera Narrow Angle Camera boulder counts are consistent with Diviner rock abundance estimates
- Subjects
LUNAR craters; REGOLITH; MARS landing sites; MOON; RECONNAISSANCE operations
- Publication
Journal of Geophysical Research. Planets, 2019, Vol 124, Issue 11, p2754
- ISSN
2169-9097
- Publication type
Article
- DOI
10.1029/2019JE005963