Soil Diversity and Hydration as Observed by ChemCam at Gale Crater, Mars

Meslin, Pierre‐Yves; Gasnault, O.; Forni, O.; Schröder, Susanne; Cousin, A.; Berger, G.; Clegg, S. M.; Lasue, J.; Maurice, S.; Sautter, V.; Mouëlic, Stéphane Le; Wiens, R. C.; Fabre, C.; Goetz, W.; Bish, David L.; Mangold, N.; Ehlmann, B. L.; Lanza, N.; Harri, A. M.; Anderson, R. B.; Rampe, E. B.; McConnochie, T. H.; Pinet, P.; Blaney, D. L.; Léveillé, Richard; Archer, D.; Barraclough, B. L.; Bender, Steve; Blake, D. F.; Blank, Jennifer; Bridges, N. T.; Clark, B. C.; DeFlores, L.; Delapp, D.; Dromart, G.; Dyar, M. D.; Fisk, Martin; Gondet, B.; Grotzinger, J. P.; Herkenhoff, K. E.; Johnson, J. R.; Lacour, Jean-Luc; Langevin, Y.; Leshin, L. A.; Lewin, É.; Madsen, M. B.; Melikechi, Noureddine; Mezzacappa, A.; Mischna, M. A.; Moores, John E.; Newsom, H. E.; Ollila, A.; Perez, René; Rennó, N. O.; Sirven, Jean-Baptiste; Tokar, R. L.; Torre, Manuel de la; d’Uston, L.; Vaniman, D. T.; Yingst, Aileen; Minitti, M. E.; Cremers, David A.; Bell, James F.; Edgar, L. A.; Farmer, Jack D.; Godber, Austin; Wadhwa, M.; Wellington, Danika; McEwan, Ian; Newman, C. E.; Richardson, M. E.; Charpentier, Antoine; Péret, Laurent; King, P. L.; Weigle, Gerald; Schmidt, M. E.; Li, Shuai; Milliken, R. E.; Robertson, Kevin; Sun, V. Z.; Baker, M. B.; Edwards, C. S.; Farley, Kenneth A.; Griffes, J. L.; Miller, Hayden; Newcombe, Megan; Pilorget, C.; Rice, M. S.; Siebach, K. L.; Stack, Katie; Stolper, Edward M.; Brunet, Claude; Hipkin, V.; Marchand, Geneviève; Sánchez, Pablo Sobrón; Favot, Laurent; Cody, George D.; Steele, A.; Flückiger, Lorenzo; Lees, David; Nefian, Ara; Martin, Mildred; Gailhanou, M.; Westall, Francès; Agard, Christophe; Baroukh, Julien; Donny, Christophe; Gaboriaud, Alain; Guillemot, Philippe; Lafaille, Vivian; Lorigny, Eric; Paillet, Alexis; Saccoccio, M.; Yana, Charles; Armiens‐Aparicio, Carlos; Rodríguez, Javier Caride; Blázquez, Isaías Carrasco; Gómez, Felipe; Gómez‐Elvira, Javier; Hettrich, Sebastian; Malvitte, Alain Lepinette; Jiménez, Mercedes Marín; Martínez‐Frías, Jesús; Martín-Soler, Javier; Martín-Torres, F. J.; Jurado, Antonio Molina; Mora-Sotomayor, Luis; Muñoz, G. M.; López, Sara Navarro; Peinado-González, Verónica; Pla‐García, Jorge; Manfredi, José Antonio Rodríguez; Romeral-Planelló, Julio José; Fuentes, Sara Alejandra Sans; Martínez, Eduardo Sebastián; Redondo, Josefina Torres; Urqui-O’Callaghan, Roser; Mier, María-Paz Zorzano; Chipera, S. J.; Mauchien, P.; Manning, Heidi; Fairén, Alberto González; Hayes, Alexander G.; Joseph, J.; Squyres, S. W.; Sullivan, Robert; Thomas, P. C.; Dupont, Audrey; Lundberg, Angela; DeMarines, Julia; Grinspoon, David; Reitz, Günther; Prats, Benito; Genzer, M.; Haukka, Harri; Kahanpää, Henrik; Kauhanen, Janne; Kemppinen, Osku; Paton, Mark; Polkko, J.; Schmidt, W.; Siili, T.; Wray, J. J.; Poitrasson, Franck; Patel, Kiran; Gorevan, Stephen; Indyk, Stephen; Paulsen, G.; Gupta, Sanjeev; Schieber, Jüergen; Geffroy, Claude; Baratoux, D.; Cros, A.; Lee, Qiu-Mei; Pallier, E.; Parot, Yann; Toplis, M. J.; Brunner, Will; Heydari, Ezat; Achilles, Cherie; Oehler, Dorothy Z.; Sutter, B.; Cabane, Michel; Coscia, David; Israël, G.; Szopa, Cyril; Robert, François; Nachon, M.; Buch, Arnaud; Stalport, Fabien; Coll, Patrice; François, Pascaline; Raulin, F.; Teinturier, Samuel; Cameron, James F.; Dingler, Robert; Jackson, Ryan; Johnstone, Stephen; Little, Cynthia; Nelson, Tony; Williams, Richard; Kirkland, L. E.; Treiman, Allan H.; Baker, Burt; Cantor, B. A.; Caplinger, Michael; Davis, Scott D.; Duston, Brian; Edgett, K. S.; Fay, Donald; Hardgrove, C.; Harker, David; Herrera, Paul; Jensen, Elsa; Kennedy, M. R.; Krezoski, Gillian; Krysak, Daniel; Lipkaman, Leslie; Malin, M. C.; McCartney, Elaina; McNair, Sean; Nixon, Brian; Posiolova, Liliya; Ravine, M. A.; Salamon, Andrew; Saper, Lee; Stoiber, Kevin; Supulver, Kimberley; Beek, Jason Van; Beek, Tessa Van; Zimdar, Robert; French, Katherine L.; Iagnemma, Karl; Miller, Kristen; Summons, Roger E.; Goesmann, Fred; Hviid, S. F.; Johnson, Micah; Lefavor, Matthew; Lyness, Eric; Breves, E. A.; Fassett, C. I.; Bristow, T. F.; DesMarais, David J.; Edwards, Laurence; Haberle, R. M.; Hoehler, Tori M.; Hollingsworth, Jeff; Kahre, M. A.; Keely, Leslie; McKay, Christopher P.; Wilhelm, Mary Beth; Bleacher, L. V.; Brinckerhoff, W. B.; Choi, David; Conrad, Pamela G.; Dworkin, Jason P.; Eigenbrode, J. L.; Floyd, Melissa; Freissinet, Caroline; Garvin, J. B.; Glavin, Daniel P.; Harpold, Daniel; Jones, Andrea; Mahaffy, P. R.; Martin, David K.; McAdam, A. C.; Pavlov, Alexander A.; Raaen, E.; Smith, M. D.; Stern, J. C.; Tan, Florence; Trainer, M. G.; Meÿer, Michael A.; Posner, A.; Voytek, Mary A.; Anderson, Robert C.; Aubrey, A. D.; Beegle, L. W.; Behar, A.; Brinza, D. E.; Calef, F.; Christensen, L. E.; Crisp, J. A.; Feldman, Jason; Feldman, Sabrina; Flesch, Gregory J.; Hurowitz, J. A.; Jun, I.; Keymeulen, Didier; Maki, J. N.; Morookian, John Michael; Parker, T. J.; Pavri, B.; Schoppers, Marcel; Sengstacken, Aaron; Simmonds, John J.; Spanovich, Nicole; Vasavada, A. R.; Webster, Christopher R.; Yen, A. S.; Cucinotta, Francis A.; Jones, J. H.; Ming, D. W.; Morris, R. V.; Niles, P. B.; Nolan, Thomas; Radziemski, Leon J.; Berman, D. C.; Dobrea, E. Noe; Williams, R. M. E.; Lewis, K. W.; Cleghorn, T.; Huntress, Wesley T.; Manhès, G.; Hudgins, Judy; Olson, Timothy S.; Stewart, Noel; Sarrazin, P.; Grant, J. A.; Vicenzi, E. P.; Wilson, Sharon A.; Bullock, M. A.; Ehresmann, Bent; Hamilton, Victoria E.; Hassler, Donald M.; Peterson, Joseph; Rafkin, Scot; Zeitlin, C.; Fedosov, F.; Golovin, D. V.; Karpushkina, Natalya; Kozyrev, A.; Litvak, M. L.; Malakhov, A.; Митрофанов, И. Г.; Мокроусов, М. И.; Nikiforov, Sergey; Прохоров, В. А.; Санин, А. Б.; Tretyakov, V. I.; Varenikov, A.; Vostrukhin, Andrey; Wolff, Michael; McLennan, S. M.; Botta, Oliver; Drake, D. M.; Bean, Keri; Lemmon, M. T.; Schwenzer, S. P.; Lee, Ella Mae; Sucharski, Robert; Hernández, Miguel Ángel de Pablo; Ávalos, Juan José Blanco; Ramos, Miguel; Kim, Myung‐Hee; Malespin, C. A.; Plante, Ianik; Müller, Jan-Peter; Navarro‐González, Rafael; Ewing, R. C.; Boynton, W. V.; Downs, Robert T.; Fitzgibbon, Mike; Harshman, K.; Morrison, S. M.; Dietrich, W. E.; Kortmann, Onno; Palucis, M. C.; Sumner, D. Y.; Williams, Amy J.; Lugmair, G. W.; Wilson, Michael; Rubin, David M.; Jakosky, B. M.; Balić-Žunić, Tonči; Frydenvang, J.; Jensen, Jaqueline Kløvgaard; Kinch, K. M.; Koefoed, Asmus; Stipp, Susan Louise Svane; Boyd, Nick; Campbell, John L.; Gellert, R.; Perrett, G. M.; Pradler, Irina; VanBommel, S. J.; Jacob, Samantha; Owen, Tobias; Rowland, Scott K.; Atlaskin, Evgeny; Savijärvi, Hannu; Boehm, E.; Böttcher, S.; Burmeister, Sönke; Guo, Jingnan; Köhler, Jan; García, César Martín; Mueller-Mellin, R.; Wimmer‐Schweingruber, R. F.; Bridges, J. C.; Benna, M.; Franz, H. B.; Bower, Hannah; Brunner, A.; Blau, Hannah; Boucher, Thomas; Carmosino, Marco; Atreya, S. K.; Elliott, Harvey; Halleaux, Douglas; Wong, Michael H.; Pepin, R. O.; Elliott, Beverley; Spray, John G.; Thompson, L. M.; Gordon, Suzanne; Williams, Joshua; Vasconcelos, Paulo M.; Bentz, Jennifer; Nealson, Kenneth H.; Popa, Radu; Kah, L. C.; Moersch, J.; Tate, Christopher G.; Day, Mackenzie; Kocurek, Gary; Hallet, Bernard; Sletten, R. S.; Francis, Raymond; McCullough, Emily; Cloutis, E. A.; Kate, I. L. ten; Kuzmin, R. O.; Arvidson, R. E.; Fraeman, A. A.; Scholes, Daniel; Slavney, S.; Stein, Thomas; Ward, Jennifer; Berger, Jeffrey F.

doi:10.1126/science.1238670

Cited by 222 publications

(210 citation statements)

References 73 publications

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“…The surface of Mars currently has a very thin atmosphere, but the possibility of mineral surface hydration under Martian conditions was investigated in the laboratory (12,13) and recently detected directly at Gale Crater, Mars (14). There are great diurnal temperature differences and sheltered basins with subsequent transient melting of ice (15)(16)(17) and craters where the atmospheric pressure is higher than average (18,19).…”

Section: Discussion: Geochemical and Technological Implicationsmentioning

confidence: 99%

Rapidly reversible redox transformation in nanophase manganese oxides at room temperature triggered by changes in hydration

Birkner

Navrotsky

2014

Proc. Natl. Acad. Sci. U.S.A.

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Chemisorption of water onto anhydrous nanophase manganese oxide surfaces promotes rapidly reversible redox phase changes as confirmed by calorimetry, X-ray diffraction, and titration for manganese average oxidation state. Surface reduction of bixbyite (Mn 2 O 3 ) to hausmannite (Mn 3 O 4 ) occurs in nanoparticles under conditions where no such reactions are seen or expected on grounds of bulk thermodynamics in coarse-grained materials. Additionally, transformation does not occur on nanosurfaces passivated by at least 2% coverage of what is likely an amorphous manganese oxide layer. The transformation is due to thermodynamic control arising from differences in surface energies of the two phases (Mn 2 O 3 and Mn 3 O 4 ) under wet and dry conditions. Such reversible and rapid transformation near room temperature may affect the behavior of manganese oxides in technological applications and in geologic and environmental settings.phase transformation | oxidation/reduction | water adsorption/desorption M anganese oxides are ubiquitous in the natural environment, often occurring as very fine grained (nanopahase) precipitates and coatings, and also find numerous technological applications, especially in catalysis. Easy variation of manganese oxidation state (Mn 2+ , Mn 3+ , Mn 4+ ) lends complexity to phase behavior and physical and chemical properties of manganese oxides. The thermodynamic stability of manganese oxide nanoparticles helps determine the robustness of such oxides and their behavior in soils and larger-scale geochemical cycles, as well as in applications in catalysis, renewable energy, and environmental remediation. The structure and energetics of nanoparticle surfaces are influenced by the phase present and its oxidation state and by the extent of surface hydration; thus dry surfaces are structurally and thermodynamically distinct from hydrated surfaces (1, 2). Using Mn 3 O 4 (hausmannite), Mn 2 O 3 (bixbyite), and MnO 2 (pyrolusite), previously, we showed that the position in temperature−oxygen fugacity space, of oxidation−reduction (redox) phase equilibria, is shifted at the nanoscale due to differences in nanophase surface energy as a function of particle size and surface hydration and that this thermodynamic shift is in favor of the lower surface energy phase (3). In the manganese oxides, the surface energy increases in the order hausmannite, bixbyite, pyrolusite, so small particle size favors the more reduced oxide phase.This paper summarizes observations in the nanoscale Mn 2 O 3 − Mn 3 O 4 system, which is found to undergo rapidly reversible redox phase transformations at room temperature induced by the adsorption/desorption of surface water. It is expected that the degree of reduction is a function of both average particle size and particle size distribution, but this work focuses on only one representative material to provide proof of concept. The rapid response of activated surfaces to changing hydration condition implies thermodynamic control and has implications for geochemistry, planetary scie...

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Section: Discussion: Geochemical and Technological Implicationsmentioning

confidence: 99%

Rapidly reversible redox transformation in nanophase manganese oxides at room temperature triggered by changes in hydration

Birkner

Navrotsky

2014

Proc. Natl. Acad. Sci. U.S.A.

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“…Hydration plays fundamental roles in biomolecular functions [1][2][3], crystal growth [4], soil wetting [5], and catalytic reactions [6]. Despite the wide success of diffraction and spectroscopy techniques in investigating hydration structures at the nanoscale [7][8][9][10][11][12][13], molecular level detail of water distributions at critical inhomogeneous interfaces remains elusive.…”

Section: Introductionmentioning

confidence: 99%

Mechanism of atomic force microscopy imaging of three-dimensional hydration structures at a solid-liquid interface

et al. 2015

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Here we present both subnanometer imaging of three-dimensional (3D) hydration structures using atomic force microscopy (AFM) and molecular dynamics simulations of the calcite-water interface. In AFM, by scanning the 3D interfacial space in pure water and recording the force on the tip, a 3D force image can be produced, which can then be directly compared to the simulated 3D water density and forces on a model tip. Analyzing in depth the resemblance between experiment and simulation as a function of the tip-sample distance allowed us to clarify the contrast mechanism in the force images and the reason for their agreement with water density distributions. This work aims to form the theoretical basis for AFM imaging of hydration structures and enables its application to future studies on important interfacial processes at the molecular scale.

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“…In one particular instance-in a paleolake system within Jezero Crater-the clays are reported to be smectite-rich, although these materials (along with coexisting iron oxides or hydroxides) are considered to be allochthonous sediments (Ehlmann et al, 2008a). Furthermore, clay minerals (particularly trioctahedral smectites) have now been detected in martian sedimentary rocks at Yellowknife Bay (Gale Crater) by the MSL Curiosity rover (Vaniman et al, 2014), and a significant component of amorphous material has been identified in Gale Crater (Bish et al, 2013;Blake et al, 2013;Meslin et al, 2013). Consequently, the potential for discovering that clay minerals might also have been widespread in the subsurface of early Mars (Ehlmann et al, 2011) is now higher, and this is important from the standpoint of understanding subsurface/ subaqueous processes on Mars and providing clues to the origin of such clays.…”

Section: Introductionmentioning

confidence: 99%

“…Fluvial conglomerates have also been identified in Gale Crater with the Mast Camera (Mastcam) of the Mars Science Laboratory (MSL) Curiosity rover, indicating that extended aqueous flows once took place on the surface of the planet in that region (Williams et al, 2013). Furthermore, the Sample Analysis at Mars (SAM) instrument on board the MSL Curiosity rover recently measured significant quantities (1.5-3 wt %) of an H 2 O component released from the amorphous fines of the Rocknest eolian deposit of Gale Crater (Leshin et al, 2013), among other volatiles such as CO 2 , SO 2 , and O 2 .…”

Section: Introductionmentioning

confidence: 99%

“…Remote sensing of the martian surface by orbiting spacecraft and in situ investigations conducted by landers and rovers has contributed to these investigations and improved our understanding of the planet (e.g., Bibring et al, 2006Bibring et al, , 2007Bish et al, 2013;Blake et al, 2013). The first major aim was to discover evidence of past or present water on the surface of Mars and then, more importantly, to search for the presence of life.…”

Section: Introductionmentioning

confidence: 99%

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A Conspicuous Clay Ovoid in Nakhla: Evidence for Subsurface Hydrothermal Alteration on Mars with Implications for Astrobiology

Chatzitheodoridis

Haigh

Lyon³

2014

Astrobiology

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A conspicuous biomorphic ovoid structure has been discovered in the Nakhla martian meteorite, made of nanocrystalline iron-rich saponitic clay and amorphous material. The ovoid is indigenous to Nakhla and occurs within a late-formed amorphous mesostasis region of rhyolitic composition that is interstitial to two clinopyroxene grains with Al-rich rims, and contains acicular apatite crystals, olivine, sulfides, Ti-rich magnetite, and a new mineral of the rhoenite group. To infer the origin of the ovoid, a large set of analytical tools was employed, including scanning electron microscopy and backscattered electron imaging, wavelength-dispersive X-ray analysis, X-ray mapping, Raman spectroscopy, time-of-flight secondary ion mass spectrometry analysis, high-resolution transmission electron microscope imaging, and atomic force microscope topographic mapping. The concentric wall of the ovoid surrounds an originally hollow volume and exhibits internal layering of contrasting nanotextures but uniform chemical composition, and likely inherited its overall shape from a preexisting vesicle in the mesostasis glass. A final fibrous layer of Fe-rich phases blankets the interior surfaces of the ovoid wall structure. There is evidence that the parent rock of Nakhla has undergone a shock event from a nearby bolide impact that melted the rims of pyroxene and the interstitial matter and initiated an igneous hydrothermal system of rapidly cooling fluids, which were progressively mixed with fluids from the melted permafrost. Sharp temperature gradients were responsible for the crystallization of Al-rich clinopyroxene rims, rhoenite, acicular apatites, and the quenching of the mesostasis glass and the vesicle. During the formation of the ovoid structure, episodic fluid infiltration events resulted in the precipitation of saponite rinds around the vesicle walls, altered pyrrhotite to marcasite, and then isolated the ovoid wall structure from the rest of the system by depositing a layer of iron oxides/hydroxides. Carbonates, halite, and sulfates were deposited last within interstitial spaces and along fractures. Among three plausible competing hypotheses here, this particular abiotic scenario is considered to be the most reasonable explanation for the formation of the ovoid structure in Nakhla, and although compelling evidence for a biotic origin is lacking, it is evident that the martian subsurface contains niche environments where life could develop.

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Soil Diversity and Hydration as Observed by ChemCam at Gale Crater, Mars

Cited by 222 publications

References 73 publications

Rapidly reversible redox transformation in nanophase manganese oxides at room temperature triggered by changes in hydration

Rapidly reversible redox transformation in nanophase manganese oxides at room temperature triggered by changes in hydration

Mechanism of atomic force microscopy imaging of three-dimensional hydration structures at a solid-liquid interface

A Conspicuous Clay Ovoid in Nakhla: Evidence for Subsurface Hydrothermal Alteration on Mars with Implications for Astrobiology

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