Slope failures and mantle degradation along the Nilosyrtis Rupes, Mars - An inventory of putative slab avalanches and sublimated terrain in the latitude-dependent mantle layer
Abstract
New data acquired from Mars orbiter and landers have led to major advances in planetary
science during the last two decades, allowing for more detailed interpretations of the
geological and climatic history of Mars. With the help of gamma spectroscopy, high-resolution
satellite images of polygon-patterned, sorted, and sublimated ground, as well as field
samples of near-surface ice, we know that much of Mars' water reservoir is bound as waterice
in a thick latitude-dependent mantle layer (LDM). At latitudes poleward of 30°-45°, this
ice-rich LDM covers the older terrain and is in turn overlain by a 10–20 cm thick layer of lag
deposits, effectively protecting the underlying ice from fully sublimating under the low
atmospheric pressure. Deposition of atmospheric ice and dust during periods of high obliquity
has alternated with erosion and sublimation during periods of moderate or low obliquity during
much of the Amazonian epoch. By studying the latitude-dependent mantle layer and its
degradation, we may gain insight into how seasonal variations and Milankovitch cycles affect
the possibility and extent of atmospheric precipitation and the stability of near-surface waterice
on Mars.
The aim of this study is to gain further insight into the latitudinal mantle layer properties and
the spatial distribution of sublimation-induced erosion as well as the presence of mass
movements of putative slab avalanches that indicate internal layering in the upper, dust- and
ice-rich sediment. HiRISE and CTX data of small-scale features of the LDM-covered
Nilosyrtis Rupes shows an aspect dependency of sublimated terrain and putative slab
avalanches in north and northeast slope directions, which is consistent with previous mapping
of glacial structures in the area (Saar, 2022). In this study, outcrops of putative sedimentary
layering and large fracture lines were observed. The fracture lines predominantly lie parallel
to the Nilosyrtis Rupes in a northwest and southeast direction. The orientation of these
fractures favors slope instability along the ridge and cuts through both eroded and smooth
terrain. Triggering factors for these relatively new fracture lines are discussed based on two
hypotheses: volume collapse caused by long-term sublimation during the current moderate
obliquity angle, or a geologically recent seismic event.
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Date
2023-08-16Author
Sjöberg, Trine
Keywords
Mars
Planetary geology
Latitude-dependent mantle layer
Sublimation
Geomorphology
Milankovitch cycles
Glacial ice deposits
Series/Report no.
B1231
Language
eng