1. Quantifying Preservation Potential: Lipid Degradation in a Mars-Analog Circumneutral Iron Deposit
- Author
-
Mark A. Sephton, Jonathan S W Tan, and Science and Technology Facilities Council (STFC)
- Subjects
Life Sciences & Biomedicine - Other Topics ,010504 meteorology & atmospheric sciences ,Extraterrestrial Environment ,Iron ,Mars ,Hydrous pyrolysis ,Astronomy & Astrophysics ,01 natural sciences ,Ferrihydrite ,chemistry.chemical_compound ,Artificial maturation. Astrobiology 21, xxx–xxx ,Desorption ,0103 physical sciences ,Biosignature ,Artificial maturation ,0201 Astronomical and Space Sciences ,Exobiology ,0402 Geochemistry ,Organic matter ,Geosciences, Multidisciplinary ,010303 astronomy & astrophysics ,Biology ,0105 earth and related environmental sciences ,chemistry.chemical_classification ,Minerals ,Mineral ,Science & Technology ,Chemistry ,Geology ,Agricultural and Biological Sciences (miscellaneous) ,Lipids ,0403 Geology ,Space and Planetary Science ,Environmental chemistry ,Physical Sciences ,Hydroxide ,Kinetic parameters ,Life Sciences & Biomedicine ,Groundwater - Abstract
Comparisons between the preservation potential of Mars-analog environments have historically been qualitative rather than quantitative. Recently, however, laboratory-based artificial maturation combined with kinetic modeling techniques have emerged as a potential means by which the preservation potential of solvent-soluble organic matter can be quantified in various Mars-analog environments. These methods consider how elevated temperatures, pressures, and organic-inorganic interactions influence the degradation of organic biomarkers post-burial. We used these techniques to investigate the preservation potential of deposits from a circumneutral iron-rich groundwater system. These deposits are composed of ferrihydrite (Fe5HO8 · 4H2O), an amorphous iron hydroxide mineral that is a common constituent of rocks found in ancient lacustrine environments on Mars, such as those observed in Gale Crater. Both natural and synthetic ferrihydrite samples were subjected to hydrous pyrolysis to observe the effects of long-term burial on the mineralogy and organic content of the samples. Our experiments revealed that organic-inorganic interactions in the samples are dominated by the transformation of iron minerals. As amorphous ferrihydrite transforms into more crystalline species, the decrease in surface area results in the desorption of organic matter, potentially rendering them more susceptible to degradation. We also find that circumneutral iron-rich deposits provide unfavorable conditions for the preservation of solvent-soluble organic matter. Quantitative comparisons between preservation potentials as calculated when using kinetic parameters show that circumneutral iron-rich deposits are ∼25 times less likely to preserve solvent-soluble organic matter compared with acidic, iron-rich environments. Our results suggest that circumneutral iron-rich deposits should be deprioritized in favor of acidic iron- and sulfur-rich deposits when searching for evidence of life with solvent extraction techniques.
- Published
- 2021