Catalytic/Protective Properties of Martian Minerals and Implications for Possible Origin of Life on Mars
Abstract
:1. Introduction
2. Martian Minerals
3. Organics Detected on the Surface of Mars and in Martian Meteorites
4. Preservation of Biosignatures
4.1. Oxidants on Mars
4.2. Photodegradation Processes of Organic Matter on Mars
4.2.1. Radiation Environment on Mars
4.2.2. Laboratory Simulations of Martian Conditions
Early Investigations
Degradation Power of Water
Photocatalysis
Clay Minerals
Towards Realistic Simulations of the Martian Environment
Effects of Galactic Cosmic Rays and Solar Energetic Particles
5. Summary of the Results and Take-Home Messages
6. Implications for Future Martian Missions
Author Contributions
Funding
Conflicts of Interest
References
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Minerals | Region of Discovery on Mars | Mars Mission |
---|---|---|
Phyllosilicates, such as clay minerals (aluminium-rich dioctahedral and magnesium-rich trioctahedral smectites, kaolinite, illite, pyrophyllite-talc), micas (muscovite), and chamosite chlorite. | Echus Chasma, Mawrth Vallis, Eridania basin, Memnonia quadrangle, Elysium quadrangle, Nili Fossae, Argyre Planitia, Gale crater, and Marathon Valley. | ESA Mars Express, NASA Mars Exploration Rovers, NASA Mars Reconnaissance Orbiter, and NASA Mars Science Laboratory [1,4,71,72,73,74,75,76,77,78,79,80]. |
Evaporites (chloride salts). | Southern highlands within Noachian-aged terrains. | NASA 2001 Mars Odyssey [87,88,89]. |
Sulfates (magnesium sulfates, like kieserite, and calcium sulfates, like gypsum). | Gale crater, Endeavor crater, the North and South Poles of Mars. | ESA Mars Express and NASA Mars Science Laboratory [69,90,91]. |
Opaline silica. | Valles Marineris, Gusev crater, and Gale crater. | NASA Mars Reconnaissance Orbiter and NASA Mars Science Laboratory [67,89,90]. |
Ferric oxides, like hematite and goethite. | Chryse Planitia, Utopia Planitia, Ares Vallis, Gusev Crater, Meridiani Planum, Terra Meridiani, Valles Marineris, Aureum Chaos, Columbia Hills, Gale crater. | NASA Viking Landers, NASA Mars Global Surveyor, NASA Mars Pathfinder, NASA 2001 Mars Odyssey, and NASA Mars Exploration Rovers [66,92,93,101]. |
Mafic minerals, such as pyroxene and olivine. | Mainly in older terrains, included within sand dunes, associated to ancient Noachian crustal rocks and early Hesperian volcanism in the southern hemisphere. | ESA Mars Express [105,106]. |
Amorphous material. | Gale crater. | NASA Mars Science Laboratory [86,108]. |
Reference | Sample/Preparation Method | Irradiation Source/Spectral Range | Temperature | Pressure/Atmospheric Composition | Oxidants | In Situ/Ex Situ Analysis | Analytical Techniques |
---|---|---|---|---|---|---|---|
Oro & Holzer 1979 [178] | Adenine, glycine, and naphthalene impregnated on powdered quartz at various concentration from 0.01% to 0.2%/Murchison meteorite | Mercury-Xenon lamp/200–300 nm | −10 to 25 °C | 1 mbar N2/various O2-content | None | Ex situ | Ion exchange chromatography for glycine, UV-vis spectrophotometry for adenine, Gas chromatography for naphthalene and Murchison |
Stoker & Bullock 1997 [177] | Glycine powder mixed with palagonite at 1% concentration | Xenon lamp/210–710 nm | Room temperature | 100 mbar, 95.59% CO2, 4.21% Ar, 0.11% O2, 0.09% CO | None | In situ | Gas chromatography |
Scappini et al. 2004 [179] | Aqueous suspension of DNA and montmorillonite and kaolinite (20 μg DNA and 2 mg clay in 2 mL water) | Nd:YAG pulsed laser/266 nm | Room temperature | Terrestrial ambient conditions | None | Ex situ | Biological transformation |
Ciaravella et al. 2004 [180] | Aqueous suspension of DNA and montmorillonite and kaolinite (10 μg DNA and 2 mg clay in 1.4 mL water) | Electron impact X-ray source/Monochromatic X-rays of 1.49, 4.51, and 8.04 keV | Room temperature | Vacuum | None | Biological transformation | |
Garry et al. 2006 [181] | JSC Mars-1 and Salten Skov Martian soil analogs containing native amino acids | Deuterium lamp/190–325 nm | Room temperature (Experiment I and II)/−63 °C (Experiment III) | 1 × 10−5 mbar (Experiment I and II)/7 mbar CO2 (Experiment III) | None | Ex situ | HPLC |
Biondi et al. 2007 [182] | Aqueous suspension of RNA and montmorillonite (2.25 × 10−10 moles RNA and 1.3 mg montmorillonite in 75 μL water) | Atlas Germicidal Lamp (15 W)/254 nm | Room temperature | Terrestrial ambient conditions | None | Ex situ | Analysis of self-cleavage activity |
Shkrob & Chemerisov 2009 [183] | Aqueous suspensions of carboxylic, hydroxycarboxylic, and aminocarboxylic acids, carboxylated aromatics, amino acids, and peptides with anatase, goethite, and hematite | Nd:YAG pulsed laser/355 nm | −196 to −73 °C/22 °C | 1 bar, N2 | None | Ex situ | EPR/transient absorption spectroscopy |
Shkrob et al. 2010 [184] | Aqueous suspensions of carboxylic, hydroxycarboxylic, and aminocarboxylic acids, carboxylated aromatics, amino acids, and peptides with anatase, goethite, and hematite | Nd:YAG pulsed laser/355 nm | −196 °C | 1 bar, N2 | None | Ex situ | EPR |
Stalport et al. 2010 [185] | Carboxylic acids α-aminoisobutyric acid (AIB), mellitic acid, phthalic acid, and trimesic acid directly deposited on quartz windows or underneath a layer of JSC Mars-1 | Solar radiation >200 nm | Temperature at low Earth orbit | Pressure at low Earth orbit | None | Ex situ | IR spectroscopy |
Johnson & Pratt 2010 [186] | Amino acids glycine, L-alanine, L-valine, L-glutamic acid, and L-aspartic acid in metal-rich sulfate brines (1 mM amino acid concentration) | Xenon lamp/250–700 nm | −40 to 20 °C | 7 to 15 mbar, 95.3% CO2, 2.7% N2, 1.6% Ar, and 0.13% O2 | None | Ex situ | XRD, HPLC |
Johnson & Pratt 2011 [187] | Amino acids L-Alanine, L-valine, L-aspartic acid, L-glutamic acid, and glycine inoculated into I-MAR Martian regolith simulant at 0.01% concentration | Xenon lamp/210–900 nm | −40.4 to 24 °C (on average −17.6 °C) | 10−22 mbar (on average 13.3 mbar), 48.6% CO2, 50% Ar, 1.4% N2, 0.07% O2, 0.04% CO, 0.02% H2O, 0.01% H2 | None | Ex situ | HPLC |
Shkrob et al. 2011 [188] | Aqueous suspensions of nucleic acid components with anatase, goethite, and hematite | Nd:YAG pulsed laser/355 nm | −196 °C | 1 bar, N2 | None | Ex situ | EPR |
Fornaro et al. 2013 [168] | Nucleobases adenine, uracil, cytosine, and hypoxanthine adsorbed on magnesium oxide and forsterite at concentrations in the range 0.1–10% | Mercury-Xenon lamp/185–2000 nm | 25 °C | Vacuum (~10−2–10−3 mbar) | None | In situ | Diffuse Reflectance Fourier Transform Infrared (DRIFT) spectroscopy |
Poch et al. 2015 [172] | Glycine, urea, and adenine co-deposited with nontronite with high molecule-mineral mass ratio (from 1.0 to 3.6) | Xenon lamp/190–400 nm | −55 °C | 6 ± 1 mbar, N2 | None | In situ | IR spectroscopy |
dos Santos et al. 2016 [189] | 25 amino acids spiked onto augite, enstatite, goethite, gypsum, hematite, jarosite, labradorite, montmorillonite, nontronite, olivine, saponite, and a basaltic lava, at various concentration (approx. 0.001% to 0.1%) | Xenon lamp/200–400 nm | −80 to 20 °C | 6 mbar, 95% CO2, 5% N2 | None | Ex situ | GC-MS |
Ertem et al. 2017 [190] | Purine, pyrimidine, and uracil impregnated on ferric oxide, calcite, calcium sulphate, kaolinite, and clay-bearing Atacama desert soil at 0.0025% concentration | Xenon lamp/200–400 nm (Experiment I); Gamma Cell 40 from a 137Cs source/Gamma rays 3 Gy (Experiment II) | −196 to 25 °C (Experiment I); 25 °C (Experiment II) | 15–25 mbar/Ambient pressure, 95.3% CO2, 2.7% N2, 0.13 O2 (Experiment I); Ambient pressure, 95.3% CO2, 2.7% N2, 0.13 O2 (Experiment II) | 0.6% NaClO4 | Ex situ | HPLC |
Fornaro et al. 2018 [67] | AMP and UMP adsorbed on lizardite, antigorite, labradorite, natrolite, hematite, apatite, and forsterite at 5% concentration | Xenon lamp/200–930 nm (Experiment I); Xenon lamp/180–900 nm (Experiment II) | 25 °C (Experiment I); −20 °C (Experiment II) | Terrestrial ambient conditions (Experiment I); 6 mbar CO2 (Experiment II) | None | In situ (Experiment I); Ex situ (Experiment II) | Diffuse Reflectance Fourier Transform Infrared (DRIFT) spectroscopy |
Mineral | Biomarker | Radiation | Protection/Preservation | Catalysis/Degradation | Supposed Mechanism |
---|---|---|---|---|---|
Quartz | Adenine | 200–300 nm | Under N2 | Under O2 | Photo-oxidation by O2 (Oro & Holzer 1979). |
Quartz | Glycine | 200–300 nm | Under N2 | Under O2 | Photo-oxidation by O2 (Oro & Holzer 1979). |
Quartz | Naphthalene | 200–300 nm | x | Under O2/N2 | Photo-oxidation by O2 (Oro & Holzer 1979). |
Murchison meteorite | Indigenous organics | 200–300 nm | x | Under O2/N2 | Photo-oxidation by O2 (Oro & Holzer 1979). |
Palagonite | Glycine | 210–710 nm | x | Under Martian-like atmosphere | Photolysis into CH4, C2H6, C2H4 (Stoker & Bullock 1997). |
JSC Mars-1 and Salten Skov Martian soil analogs | Indigenous amino acids | 190–325 nm | x | Under Martian-like atmosphere | Decomposition induced by radicals produced by photolysis of water condensed onto minerals (Garry et al. 2006). |
JSC Mars-1 Martian soil analog | Carboxylic acids α-aminoisobutyric acid (AIB), mellitic acid, phthalic acid, and trimesic acid | Solar radiation > 200 nm | x | Under low Earth orbit conditions | Decomposition induced by radicals/oxidants produced by TiO2–photocatalysis (Stalport et al. 2010). |
I-MAR Martian regolith simulant | Amino acids L-Alanine, L-valine, L-aspartic acid, L-glutamic acid, and glycine | 210–900 nm | x | Under Martian-like atmosphere | Photolytic oxidation up to UV penetration depth, then decomposition induced by radicals formed from condensed atmospheric water vapor diffused into the regolith (Johnson & Pratt 2011). |
Aqueous suspensions of anatase, goethite, and hematite | Carboxylic, hydroxycarboxylic, and aminocarboxylic acids, carboxylated aromatics, amino acids and peptides | 355 nm | x | Under N2 | Decarboxylation initiated by charge transfer from the metal oxide to the adsorbate. Specifically, anatase, goethite, and hematite feature a similar photocatalytic activity for aromatic, carboxylic, and hydroxycarboxylic acids, while for α-amino acids and peptides hematite has reduced activity (Shkrob et al. 2010). |
Aqueous suspensions of anatase, goethite, and hematite | Nucleic acid components | 355 nm | Only for double-stranded oligoribonucleotides and DNA | Under N2 | Oxidation of purine nucleotides leads to formation of purine radical cations and sugar-phosphate radicals. In the case of pyrimidine nucleotides other than thymine only the sugar-phosphate moiety undergoes oxidation, while deprotonation from the methyl group of the base occurs for thymine derivatives. Single-stranded (ss) oligoribonucleotides and wild-type ss RNA are oxidized at purine sites, while double-stranded (ds) oligoribonucleotides and DNA show high stability against oxidation (Shkrob et al. 2011). |
Aqueous suspensions of montmorillonite and kaolinite | DNA | 266 nm | Under terrestrial ambient conditions | x | Photoprotection due to specific molecule-mineral interactions; specifically, a change in DNA configuration from B to A when adsorbed on the mineral surface, which is more compact and its binding to the surface sites may take place through electrostatic and/or hydrogen bonds likely stabilizing the molecule (Scappini et al. 2004). |
Aqueous suspensions of montmorillonite | RNA molecule ADHR1 | 254 nm | Under terrestrial ambient conditions | x | Photoprotection due to specific molecule-mineral interactions (Biondi et al. 2007). |
Nontronite | Glycine and adenine | 190–400 nm | Under N2 | x | Photoprotection is not only due to mechanical shielding, but also stabilizing molecule-mineral interactions, such as electrostatic interactions of the molecules in the interlayers and/ or on the edges of nontronite allowing a more efficient energy dissipation and/or easier recombination for the fragments of the photo-dissociated molecules (Poch et al. 2015). |
Nontronite | Urea | 190–400 nm | x | Under N2 | Catalysis in urea photo-oxidation and decomposition, maybe due to chelation with Fe3+ ions (Poch et al. 2015). |
Smectites montmorillonite, nontronite and saponite | 25 Amino acids | 200–400 nm | Under Martian-like conditions | x | Photoprotection by mechanical shielding effect (dos Santos et al. 2016). |
Sulfates gypsum and jarosite | 25 Amino acids | 200–400 nm | Under Martian-like conditions | x | Photoprotection due to low UV absorbance of sulfates or entrapment of amino acids upon recrystallization of partially dissolved sulfate (dos Santos et al. 2016). |
Augite, enstatite, hematite and basaltic lava | 25 Amino acids | 200–400 nm | x | Under Martian-like conditions | Photocatalytic activity due to iron(II) reactions (dos Santos et al. 2016). |
Calcite, calcium sulphate, kaolinite, clay-bearing Atacama desert soil + 0.6% NaClO4 | Purine, pyrimidine and uracil | 200–400 nm | Under Martian-like conditions | x | Photoprotection mechanism not specified (Ertem et al. 2017). |
Ferric oxide + 0.6% NaClO4 | Purine, pyrimidine and uracil | 200–400 nm | x | Under Martian-like conditions | Complete decomposition before UV irradiation (Ertem et al. 2017). |
Magnesium oxide and forsterite | Adenine, uracil, cytosine, and hypoxanthine | 185–2000 nm | x | Under vacuum | Catalysis likely due to a proximity effect (Fornaro et al. 2013). |
Lizardite, antigorite and apatite | AMP and UMP | 200–930 nm | Under Martian-like conditions | x | Various photoprotection mechanisms: mechanical shielding/stabilizing molecule-mineral interactions for lizardite and antigorite, photo-luminescence for apatite (Fornaro et al. 2018). |
Labradorite, natrolite, hematite, forsterite | AMP and UMP | 200–930 nm | x | Under Martian-like conditions | Remarkable catalytic activity of labradorite and natrolite, likely due to photo-ionization phenomena that may occur inside the mineral matrix promoting redox processes. For hematite and forsterite the catalytic activity is not so high, maybe due to the opacity of iron to UV radiation (Fornaro et al. 2018). |
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Fornaro, T.; Steele, A.; Brucato, J.R. Catalytic/Protective Properties of Martian Minerals and Implications for Possible Origin of Life on Mars. Life 2018, 8, 56. https://doi.org/10.3390/life8040056
Fornaro T, Steele A, Brucato JR. Catalytic/Protective Properties of Martian Minerals and Implications for Possible Origin of Life on Mars. Life. 2018; 8(4):56. https://doi.org/10.3390/life8040056
Chicago/Turabian StyleFornaro, Teresa, Andrew Steele, and John Robert Brucato. 2018. "Catalytic/Protective Properties of Martian Minerals and Implications for Possible Origin of Life on Mars" Life 8, no. 4: 56. https://doi.org/10.3390/life8040056
APA StyleFornaro, T., Steele, A., & Brucato, J. R. (2018). Catalytic/Protective Properties of Martian Minerals and Implications for Possible Origin of Life on Mars. Life, 8(4), 56. https://doi.org/10.3390/life8040056