کد مقاله | کد نشریه | سال انتشار | مقاله انگلیسی | نسخه تمام متن |
---|---|---|---|---|
6429310 | 1634763 | 2014 | 12 صفحه PDF | دانلود رایگان |
- We used Earth analogue to explain origin of hydrated sulfates in Valles Marineris.
- Similar surface appearance of Mg-Ca-Na sulfates is found along canyons walls.
- Arid climate is a major factor accumulating sulfate minerals in surface environment.
- Surface mass of hydrated sulfates in Valles Marineris is relatively small.
- Minimum â¼100 to 1000 yr would be needed to activate aqueous SO4 in Valles Marineris.
A distinctive sulfur cycle dominates many geological processes on Mars and hydrated sulfate minerals are found in numerous topographic settings with widespread occurrences on the Martian surface. However, many of the key processes controlling the hydrological transport of sulfur, including sulfur sources, climate and the depositional history that led to precipitation of these minerals, remain unclear. In this paper, we use a model for the formation of sulfate efflorescent salts (Mg-Ca-Na sulfates) in the Rio Puerco watershed of New Mexico, a terrestrial analog site from the semiarid Southwest U.S., to assess the origin and environmental conditions that may have controlled deposition of hydrated sulfates in Valles Marineris on Mars. Our terrestrial geochemical results (δS34 of â36.0 to +11.1â°) show that an ephemeral arid hydrological cycle that mobilizes sulfur present in the bedrock as sulfides, sulfate minerals, and dry/wet atmospheric deposition can lead to widespread surface accumulations of hydrated sulfate efflorescences. Repeating cycles of salt dissolution and reprecipitation appear to be major processes that migrate sulfate efflorescences to sites of surface deposition and ultimately increase the aqueous SO42â flux along the watershed (average 41,273 metric tons/yr). We suggest that similar shallow processes may explain the occurrence of hydrated sulfates detected on the scarps and valley floors of Valles Marineris on Mars. Our estimates of salt mass and distribution are in accord with studies that suggest a rather short-lived process of sulfate formation (minimum rough estimate â¼100 to 1000 years) and restriction by prevailing arid conditions on Mars.
Journal: Earth and Planetary Science Letters - Volume 393, 1 May 2014, Pages 14-25