Abstract
The oldest terrains of Mars are cratered landscapes, in which extensive valleys and basins are covered by ubiquitous fluvial plains. One current paradigm maintains that an impact-generated megaregolith underlies these sediments. This megaregolith was likely largely generated during the Early Noachian (~4.1 to ~3.94 Ga) when most Martian impact basins formed. We examined the geologic records of NW Hellas and NW Isidis, which include this epoch’s most extensive circum-basin outcrops. Here, we show that these regions include widespread, wind-eroded landscapes, crater rims eroded down by several hundred meters, pitted plains, and inverted fluvial and crater landforms. These surfaces exhibit few fresh craters, indicating geologically recent wind erosion. The deep erosion, topographic inversions, and an absence of dunes on or near talus across these regions suggest that sediments finer than sand compose most of these highland materials. We propose that basin-impact-generated hurricane-force winds created sediment-laden atmospheric conditions, and that muddy rains rapidly settled suspended sediments to construct extensive Early Noachian highlands. The implied high abundance of fine-grained sediments before these impacts suggests large-scale glacial silt production and supports the previously proposed Noachian “icy highlands” hypothesis. We suggest that subglacial meltwater interactions with the sedimentary highlands could have promoted habitability, particularly in clay strata.
Highlights
The cratered highlands of Mars include extensive ancient terrains that formed during the Noachian Period (~4.1 to ~3.7 Ga; ages based on Neukum chronology[1])
Most of the Martian impact basins formed during the Early Noachian, but only the peripheries of Hellas and Isidis retain highland terrains that date back to this geologic epoch
The erosional depths point to the presence of a fine-grained sedimentary stratigraphy, reaching several hundred meters to over a kilometer in thickness
Summary
The cratered highlands of Mars include extensive ancient terrains that formed during the Noachian Period (~4.1 to ~3.7 Ga; ages based on Neukum chronology[1]). The stratigraphic record beneath these fluvial plains is thought to mostly consist of massive volumes of Early Noachian impact-generated megaregolith (~4.1 to ~3.94 Ga)[6] This geologic superposition relationship is consistent with the finding that most of Mars’ impact basins >150 km in diameter formed[6,7] during this epoch (i.e., >65 for Early Noachian, >15 for Middle Noachian, 3 for Late Noachian, 4 for Hesperian, and 2 for Early Amazonian[7]). The fallout of clastic materials ejected by these impacts must have resulted in both the emplacement of enormous ejecta blankets around the impact basins and significantly contributed to the formation of a global megaregolith These impacts, could have triggered paleoclimates conducive to rainfall[24,25,26], perhaps followed by episodic glaciation. Segura et al.[25] considered possible
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