Abstract
Groundwater is a crucial reservoir in Mars’s global water cycle1,2 and plays an important role in aqueous alteration of bedrock3,4,5,6. Understanding groundwater flow is also important for assessing the possibility of past and present martian life7. The Valles Marineris is a series of fault-bounded troughs and chasms stretching over 4,000 km from west to east, with a width of 600 km and depth of up to 10 km below the surrounding high plains8. In this region, ancient groundwater movement is suggested by links between chasms of the Valles Marineris and the sources of catastrophic floods in chaotic collapse terrains9. Here, images obtained by the Viking, Mars Express, Mars Reconnaissance Orbiter and Mars Odyssey missions are used to map ridges on the walls of the Valles Marineris that extend in an east–west direction up to the surface of the surrounding high plains from almost 7 km beneath10. These erosion-resistant ridges, which can be tens of kilometres long, most likely represent cementation of the fault zones and surrounding rock by water-deposited minerals11,12 and suggest that groundwater in this region flowed for long distances through major east–west-trending fault systems. This interpretation implies that liquid water was stable at (or near) Mars’s surface when the fault zones were cemented ∼3,500–1,800 Myr ago and that chemical deposition from groundwater was regionally significant.
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Acknowledgements
This work began as an LPI Summer Internship in 1995 with K. Morgan (nee Spiker), now of the Colorado Geological Survey. Technical support from B. Fessler was invaluable, and P. McGovern assisted with presentation of graphics. Image access is courtesy of NASA, ESA and individual instrument teams (Viking, HRSC, MOC, THEMIS and MRO CTX). Critical reviews by C. Okubo and J. Clarke strengthened the manuscript. Supported by the NASA Astrobiology Institute node at NASA Ames Research Center (D. Desmarais, P.I.). Lunar and Planetary Institute Contribution 1389.
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Treiman, A. Ancient groundwater flow in the Valles Marineris on Mars inferred from fault trace ridges. Nature Geosci 1, 181–183 (2008). https://doi.org/10.1038/ngeo131
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DOI: https://doi.org/10.1038/ngeo131
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