Granular avalanches on the Moon: Mass‐wasting conditions, processes, and features

Seven lunar crater sites of granular avalanches are studied utilizing high‐resolution images (0.42–1.3 m/pixel) from the Lunar Reconnaissance Orbiter Camera; one, in Kepler crater, is examined in detail. All the sites are slopes of debris extensively aggraded by frictional freezing at their dynamic angle of repose, four in craters formed in basaltic mare and three in the anorthositic highlands. Diverse styles of mass wasting occur, and three types of dry‐debris flow deposit are recognized: (1) multiple channel‐and‐lobe type, with coarse‐grained levees and lobate terminations that impound finer debris, (2) single‐surge polylobate type, with subparallel arrays of lobes and fingers with segregated coarse‐grained margins, and (3) multiple‐ribbon type, with tracks reflecting reworked substrate, minor levees, and no coarse terminations. The latter type results from propagation of granular erosion‐deposition waves down slopes dominantly of fine regolith, and it is the first recognized natural example. Dimensions, architectures, and granular segregation styles of the two coarse‐grained deposit types are like those formed in natural and experimental avalanches on Earth, although the timescale of motion differs due to the reduced gravity. Influences of reduced gravity and fine‐grained regolith on dynamics of granular flow and deposition appear slight, but we distinguish, for the first time, extensive remobilization of coarse talus by inundation with finer debris. The (few) sites show no clear difference attributable to the contrasting mare basalt and highland megaregolith host rocks and their fragmentation. This lunar study offers a benchmarking of deposit types that can be attributed to formation without influence of liquid or gas. Key Points Recent LROC imaging of the lunar surface facilitates moderately detailed sedimentological analysis and comparisons with laboratory granular flow experiments Three end‐member types of debris flow deposit are identified having formed without influence of atmosphere or liquid, and two are similar to types seen on Earth Deposits of long‐runout granular erosion‐deposition waves are recognized for the first time in nature and formed on repose slopes dominantly of fine regolith Plain Language Summary The Moon is a large‐scale natural laboratory where surface processes occur without the presence of atmosphere or liquid, making it a relatively accessible analogue of other airless rocky bodies in our Solar System. Recently very high res