A Habitable Fluvio-Lacustrine Environment at Yellowknife Bay, Gale Crater, Mars

J. P. Grotzinger; D. Y. Sumner; L. C. Kah; K. Stack; S. Gupta; L. Edgar; D. Rubin; K. Lewis; J. Schieber; N. Mangold; R. Milliken; P. G. Conrad; D. DesMarais; J. Farmer; K. Siebach; F. Calef; J. Hurowitz; S. M. McLennan; D. Ming; D. Vaniman; J. Crisp; A. Vasavada; K. S. Edgett; M. Malin; D. Blake; R. Gellert; P. Mahaffy; R. C. Wiens; S. Maurice; J. A. Grant; S. Wilson; R. C. Anderson; L. Beegle; R. Arvidson; B. Hallet; R. S. Sletten; M. Rice; J. Bell; J. Griffes; B. Ehlmann; R. B. Anderson; T. F. Bristow; W. E. Dietrich; G. Dromart; J. Eigenbrode; A. Fraeman; C. Hardgrove; K. Herkenhoff; L. Jandura; G. Kocurek; S. Lee; L. A. Leshin; R. Leveille; D. Limonadi; J. Maki; S. McCloskey; M. Meyer; M. Minitti; H. Newsom; D. Oehler; A. Okon; M. Palucis; T. Parker; S. Rowland; M. Schmidt; S. Squyres; A. Steele; E. Stolper; R. Summons; A. Treiman; R. Williams; A. Yingst; M. S. Team; O. Kemppinen; N. Bridges; J. R. Johnson; D. Cremers; A. Godber; M. Wadhwa; D. Wellington; I. McEwan; C. Newman; M. Richardson; A. Charpentier; L. Peret; P. King; J. Blank; G. Weigle; S. Li; K. Robertson; V. Sun; M. Baker; C. Edwards; K. Farley; H. Miller; M. Newcombe; C. Pilorget; C. Brunet; V. Hipkin; R. Leveille; G. Marchand; P. S. Sanchez; L. Favot; G. Cody; L. Fluckiger; D. Lees; A. Nefian; M. Martin; M. Gailhanou; F. Westall; G. Israel; C. Agard; J. Baroukh; C. Donny; A. Gaboriaud; P. Guillemot; V. Lafaille; E. Lorigny; A. Paillet; R. Perez; M. Saccoccio; C. Yana; C. Armiens-Aparicio; J. C. Rodriguez; I. C. Blazquez; F. G. Gomez; J. Gomez-Elvira; S. Hettrich; A. L. Malvitte; M. M. Jimenez; J. Martinez-Frias; J. Martin-Soler; F. J. Martin-Torres; A. M. Jurado; L. Mora-Sotomayor; G. M. Caro; S. N. Lopez; V. Peinado-Gonzalez; J. Pla-Garcia; J. A. R. Manfredi; J. J. Romeral-Planello; S. A. S. Fuentes; E. S. Martinez; J. T. Redondo; R. Urqui-O'Callaghan; M.-P. Z. Mier; S. Chipera; J.-L. Lacour; P. Mauchien; J.-B. Sirven; H. Manning; A. Fairen; A. Hayes; J. Joseph; R. Sullivan; P. Thomas; A. Dupont; A. Lundberg; N. Melikechi; A. Mezzacappa; J. DeMarines; D. Grinspoon; G. Reitz; B. Prats; E. Atlaskin; M. Genzer; A.-M. Harri; H. Haukka; H. Kahanpaa; J. Kauhanen; M. Paton; J. Polkko; W. Schmidt; T. Siili; C. Fabre; J. Wray; M. B. Wilhelm; F. Poitrasson; K. Patel; S. Gorevan; S. Indyk; G. Paulsen; D. Bish; B. Gondet; Y. Langevin; C. Geffroy; D. Baratoux; G. Berger; A. Cros; C. d'Uston; O. Forni; O. Gasnault; J. Lasue; Q.-M. Lee; P.-Y. Meslin; E. Pallier; Y. Parot; P. Pinet; S. Schroder; M. Toplis; E. Lewin; W. Brunner; E. Heydari; C. Achilles; B. Sutter; M. Cabane; D. Coscia; C. Szopa; F. Robert; V. Sautter; S. Le Mouelic; M. Nachon; A. Buch; F. Stalport; P. Coll; P. Francois; F. Raulin; S. Teinturier; J. Cameron; S. Clegg; A. Cousin; D. DeLapp; R. Dingler; R. S. Jackson; S. Johnstone; N. Lanza; C. Little; T. Nelson; R. B. Williams; A. Jones; L. Kirkland; B. Baker; B. Cantor; M. Caplinger; S. Davis; B. Duston; D. Fay; D. Harker; P. Herrera; E. Jensen; M. R. Kennedy; G. Krezoski; D. Krysak; L. Lipkaman; E. McCartney; S. McNair; B. Nixon; L. Posiolova; M. Ravine; A. Salamon; L. Saper; K. Stoiber; K. Supulver; J. Van Beek; T. Van Beek; R. Zimdar; K. L. French; K. Iagnemma; K. Miller; F. Goesmann; W. Goetz; S. Hviid; M. Johnson; M. Lefavor; E. Lyness; E. Breves; M. D. Dyar; C. Fassett; L. Edwards; R. Haberle; T. Hoehler; J. Hollingsworth; M. Kahre; L. Keely; C. McKay; L. Bleacher; W. Brinckerhoff; D. Choi; J. P. Dworkin; M. Floyd; C. Freissinet; J. Garvin; D. Glavin; D. Harpold; D. K. Martin; A. McAdam; A. Pavlov; E. Raaen; M. D. Smith; J. Stern; F. Tan; M. Trainer; A. Posner; M. Voytek; A. Aubrey; A. Behar; D. Blaney; D. Brinza; L. Christensen; L. DeFlores; J. Feldman; S. Feldman; G. Flesch; I. Jun; D. Keymeulen; M. Mischna; J. M. Morookian; B. Pavri; M. Schoppers; A. Sengstacken; J. J. Simmonds; N. Spanovich; M. d. l. T. Juarez; C. R. Webster; A. Yen; P. D. Archer; F. Cucinotta; J. H. Jones; R. V. Morris; P. Niles; E. Rampe; T. Nolan; M. Fisk; L. Radziemski; B. Barraclough; S. Bender; D. Berman; E. N. Dobrea; R. Tokar; T. Cleghorn; W. Huntress; G. Manhes; J. Hudgins; T. Olson; N. Stewart; P. Sarrazin; E. Vicenzi; M. Bullock; B. Ehresmann; V. Hamilton; D. Hassler; J. Peterson; S. Rafkin; C. Zeitlin; F. Fedosov; D. Golovin; N. Karpushkina; A. Kozyrev; M. Litvak; A. Malakhov; I. Mitrofanov; M. Mokrousov; S. Nikiforov; V. Prokhorov; A. Sanin; V. Tretyakov; A. Varenikov; A. Vostrukhin; R. Kuzmin; B. Clark; M. Wolff; O. Botta; D. Drake; K. Bean; M. Lemmon; S. P. Schwenzer; E. M. Lee; R. Sucharski; M. A. d. P. Hernandez; J. J. B. Avalos; M. Ramos; M.-H. Kim; C. Malespin; I. Plante; J.-P. Muller; R. Navarro-Gonzalez; R. Ewing; W. Boynton; R. Downs; M. Fitzgibbon; K. Harshman; S. Morrison; O. Kortmann; A. Williams; G. Lugmair; M. A. Wilson; B. Jakosky; T. Balic-Zunic; J. Frydenvang; J. K. Jensen; K. Kinch; A. Koefoed; M. B. Madsen; S. L. S. Stipp; N. Boyd; J. L. Campbell; G. Perrett; I. Pradler; S. VanBommel; S. Jacob; T. Owen; H. Savijarvi; E. Boehm; S. Bottcher; S. Burmeister; J. Guo; J. Kohler; C. M. Garcia; R. Mueller-Mellin; R. Wimmer-Schweingruber; J. C. Bridges; T. McConnochie; M. Benna; H. Franz; H. Bower; A. Brunner; H. Blau; T. Boucher; M. Carmosino; S. Atreya; H. Elliott; D. Halleaux; N. Renno; M. Wong; R. Pepin; B. Elliott; J. Spray; L. Thompson; S. Gordon; A. Ollila; J. Williams; P. Vasconcelos; J. Bentz; K. Nealson; R. Popa; J. Moersch; C. Tate; M. Day; R. Francis; E. McCullough; E. Cloutis; I. L. ten Kate; D. Scholes; S. Slavney; T. Stein; J. Ward; J. Berger; J. E. Moores

doi:10.1126/science.1242777

Thermodynamic Constrains on Smectite and Iron Oxide Formation at Gale Crater, Mars: Insights into Potential Free Energy from Aerobic Fe Oxidation in Lake Water–Groundwater Mixing Zone

Minerals ◽

10.3390/min11040341 ◽

2021 ◽

Vol 11 (4) ◽

pp. 341

Author(s):

Sakiko Kikuchi ◽

Takazo Shibuya

Keyword(s):

Iron Oxides ◽

Surface Waters ◽

Fluid Mixing ◽

Habitable Zone ◽

Mixing Zone ◽

Oxide Formation ◽

Lacustrine Environment ◽

Gale Crater ◽

Metabolic Reactions ◽

Temperature Water

The presence of saponite and iron oxides in Sheepbed mudstone of Yellowknife Bay at Gale crater on Mars is considered as evidence of a habitable fluvio-lacustrine environment for chemolithoautotrophy. However, the energetic availability for metabolic reactions is poorly constrained. Herein, we propose the possible mixing of surface water and groundwater that (i) explains the formation of magnetite and hematite detected in Sheepbed mudstone and (ii) may work as a potential habitable zone for aerobic Fe2+-oxidizing microbes. Our thermodynamic modeling of water–rock reactions revealed that the formation of abundant saponite in Sheepbed mudstone may occur under various conditions of water-to-rock mass ratios, temperatures (5–200 °C), and initial fluid compositions. In contrast, the formation of iron oxides in the mudstone can be explained only by the mixing of Fe2+-rich groundwater and more oxidized surface waters, where the Fe2+-rich groundwater can be generated by the low-temperature water–rock reactions with a CO2-bearing initial fluid. The calculated bioavailable energy of aerobic Fe2+ oxidation in the fluid-mixing zone on Mars is similar to that estimated for a fluid-mixing zone on Earth actually inhabited by aerobic Fe2+-oxidizing microbes. The findings will contribute to a better understanding of potential habitability on Mars.

Download Full-text

Intense subaerial weathering of eolian sediments in Gale crater, Mars

Science Advances ◽

10.1126/sciadv.abh2687 ◽

2021 ◽

Vol 7 (32) ◽

pp. eabh2687

Author(s):

Jiacheng Liu ◽

Joseph R. Michalski ◽

Mei-Fu Zhou

Keyword(s):

Environmental Change ◽

Ancient Lake ◽

Acidic Precipitation ◽

Lacustrine Environment ◽

Gale Crater ◽

Stratigraphic Section ◽

Eolian Sediments ◽

Curiosity Rover

After over 8 years of successful surface operations on Mars, the Curiosity rover has revealed much about the environment in Gale crater. Despite early observations of a lacustrine environment, few of the subsequent deposits exhibit demonstrable lacustrine character. We suggest instead that most of the stratigraphic section explored to date can be best explained as eolian and/or volcaniclastic sediments subaerially chemically weathered by acidic precipitation in a reduced atmosphere. Most of the deposits in Gale crater seemingly did not form in an ancient lake, but the results nonetheless shed considerable light on ancient climate, environmental change, and the astrobiology of Mars. Discoveries by Curiosity provide a critical piece to Mars’ global alteration puzzle.

Download Full-text

Microbial habitability of the early Mars lacustrine environment sustained by iron redox cycling

10.1101/2021.09.07.459191 ◽

2021 ◽

Author(s):

Rachel A. Moore ◽

Christopher E. Carr

Keyword(s):

Solid Phase ◽

Modeling Processes ◽

Chemical Components ◽

Metabolic Potential ◽

Lacustrine Environment ◽

Gale Crater ◽

The Past ◽

Lack Of Information ◽

Early Mars ◽

Iron Redox

AbstractSeveral studies have reported new data on the estimated compositions of chemical components at Gale crater; however, there is still a lack of information regarding potential past support of biomass and detectable biomarkers of ancient life. In this study we evaluate microbial habitability of early Mars constrained by the recently reconstructed water chemistry at Gale. The modeled community is based on Fe-metabolizing bacteria with the ability to utilize solid-phase iron oxides (e.g., magnetite) as an electron source or sink. Our results illustrate the plausibility of a sustained community in Gale Lake and provides suggestions for future modeled and laboratory-based studies to further evaluate the past habitability of Mars, biosignatures and their preservation potential, and hidden metabolic potential.One Sentence SummaryThis work provides an existence proof of habitability on early Mars and demonstrates modeling processes by which the habitability of extraterrestrial environments can be explored quantitatively.

Download Full-text