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Sedimentary Organics in Glen Torridon, Gale Crater, Mars: Results From the SAM Instrument Suite and Supporting Laboratory Analyses

M. Millán, Amy J. Williams, A. C. McAdam, J. L. Eigenbrode, A. Steele, Caroline Freissinet, D. P. Glavin, Cyril Szopa, A. Buch, Roger E. Summons, J. M. T. Lewis, G. M. Wong, Christopher H. House, B. Sutter, Ophélie McIntosh, A. B. Bryk, H. B. Franz, Chad Pozarycki, J. C. Stern, R. Navarro‐González, D. Archer, V. K. Fox, K. A. Bennett, Samuel Teinturier, C. A. Malespin, S. S. Johnson, P. R. Mahaffy

2022Journal of Geophysical Research Planets60 citationsDOIOpen Access PDF

Abstract

Abstract The Sample Analysis at Mars (SAM) suite instrument on board NASA's Curiosity rover has characterized the inorganic and organic chemical composition of seven samples from the Glen Torridon (GT) clay‐bearing unit. A variety of organic molecules were detected with SAM using pyrolysis (up to ∼850°C) and wet chemistry experiments coupled with evolved gas analysis (EGA) and gas chromatography‐mass spectrometry. SAM EGA and GCMS analyses revealed a greater diversity and abundance of sulfur‐bearing aliphatic and aromatic organic compounds in the sediments of this Gale crater unit than earlier in the mission. We also report the detection of nitrogen‐containing, oxygen‐containing, and chlorine‐containing molecules, as well as polycyclic aromatic hydrocarbons found in GT, although the sources of some of these organics may be related to the presence of chemical reagents in the SAM instrument background. However, sulfur‐bearing organics released at high temperature (≥600°C) are likely derived from Martian sources (e.g., igneous, hydrothermal, atmospheric, or biological) or exogenous sources and consistent with the presence of recalcitrant organic materials in the sample. The SAM measurements of the GT clay‐bearing unit expand the inventory of organic matter present in Gale crater and is also consistent with the hypothesis that clay minerals played an important role in the preservation of ancient refractory organic matter on Mars. These findings deepen our understanding of the past habitability and biological potential of Gale crater.

Topics & Concepts

Impact craterAstrobiologyOrganic matterMars Exploration ProgramSedimentary organic matterEnvironmental chemistryChemistryGeologyTotal organic carbonOrganic chemistryPhysicsPlanetary Science and ExplorationAstro and Planetary ScienceSpace Exploration and Technology
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