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1. Organic carbon concentrations in 3.5-billion-year-old lacustrine mudstones of Mars

Author

Stern, Jennifer C., Malespin, Charles A., Eigenbrode, Jennifer L., Webster, Christopher R., Flesch, Greg, Franz, Heather B., Graham, Heather V., House, Christopher H., Sutter, Brad, Archer, Paul Douglas, Hofmann, Amy E., McAdam, Amy C., Ming, Douglas W., Navarro-Gonzalez, Rafael, Steele, Andrew, Freissinet, Caroline, and Mahaffy, Paul R.

Published
2022

4. Hydrogen Chloride and Sulfur Dioxide Gas Evolutions from the Reaction between Mg Sulfate and NaCl: Implications for the Sample Analysis at the Mars Instrument in Gale Crater, Mars

Author

Clark, Joanna V., primary, Sutter, Brad, additional, McAdam, Amy C., additional, Knudson, Christine A., additional, Casbeer, Patrick, additional, Tu, Valerie M., additional, Rampe, Elizabeth B., additional, Ming, Douglas W., additional, Archer, Paul D., additional, Mahaffy, Paul R., additional, and Malespin, Charles, additional

Published
2024
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5. Expanded Insights into Martian Mineralogy: Updated Analysis of Gale Crater's Mineral Composition via CheMin Crystal Chemical Investigations.

Author

Morrison, Shaunna M., Blake, David F., Bristow, Thomas F., Castle, Nicholas, Chipera, Steve J., Craig, Patricia I., Downs, Robert T., Eleish, Ahmed, Hazen, Robert M., Meusburger, Johannes M., Ming, Douglas W., Morris, Richard V., Pandey, Aditi, Prabhu, Anirudh, Rampe, Elizabeth B., Sarrazin, Philippe C., Simpson, Sarah L., Thorpe, Michael T., Treiman, Allan H., and Tu, Valerie

Subjects
GALE Crater (Mars), MARTIAN meteorites, MARTIAN surface, SURFACE chemistry, MINERALOGY
Abstract

This study presents mineral composition estimates of rock and sediment samples analyzed with the CheMin X-ray diffraction instrument on board the NASA Mars Science Laboratory rover, Curiosity, in Gale crater, Mars. Mineral composition is estimated using crystal-chemically derived algorithms applied to X-ray diffraction data, specifically unit-cell parameters. The mineral groups characterized include those found in major abundance by the CheMin instrument (i.e., feldspar, olivine, pyroxene, and spinel oxide). In addition to estimating the composition of the major mineral phases observed in Gale crater, we place their compositions in a stratigraphic context and provide a comparison to that of martian meteorites. This work provides expanded insights into the mineralogy and chemistry of the martian surface. [ABSTRACT FROM AUTHOR]

Published
2024
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6. Silicic volcanism on Mars evidenced by tridymite in high-SiO₂ sedimentary rock at Gale crater

Author

Morris, Richard V., Vaniman, David T., Blake, David F., Gellert, Ralf, Chipera, Steve J., Rampe, Elizabeth B., Ming, Douglas W., Morrison, Shaunna M., Downs, Robert T., Treiman, Allan H., Yen, Albert S., Grotzinger, John P., Achilles, Cherie N., Bristow, Thomas F., Crisp, Joy A., Des Marais, David J., Farmer, Jack D., Fendrich, Kim V., Frydenvang, Jens, Graff, Trevor G., Morookian, John-Michael, Stolper, Edward M., and Schwenzer, Susanne P.

Published
2016

7. List of Contributors

Author

Bridges, John C., primary, Butcher, Frances E.G., additional, Clifford, Stephen M., additional, Conway, Susan J., additional, Farrand, William H., additional, Filiberto, Justin, additional, Franz, Heather B., additional, Gaillard, Fabrice, additional, Gellert, Ralf, additional, Hicks, Leon J., additional, Jolliff, Bradley L., additional, King, Penelope L., additional, Knoll, Andrew H., additional, Kounaves, Samuel P., additional, Lasue, Jérémie, additional, Mahaffy, Paul R., additional, Mangold, Nicolas, additional, McAdam, Amy C., additional, McCubbin, Francis M., additional, McLennan, Scott M., additional, Ming, Douglas W., additional, Mittlefehldt, David W., additional, Mustard, John F., additional, Oberlin, Elizabeth A., additional, Olsson-Francis, Karen, additional, Ott, Ulrich, additional, Schwenzer, Susanne P., additional, Sutter, Brad, additional, Swindle, Timothy D., additional, Taylor, G. Jeffrey, additional, Treiman, Allan H., additional, Usui, Tomohiro, additional, and Yen, Albert S., additional

Published
2019
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10. Aqueous Processes and Microbial Habitability of Gale Crater Sediments from the Blunts Point to the Glenn Torridon Clay Unit

Author

Sutter, Brad, Mcadam, Amy C, Achilles, Cherie N, Rampe, Elizabeth B, Archer, Paul D, Thompson, L. M, Ming, Douglas W, Stern, Jennifer C, House, C. H, Navarro-Gonzalez, R, Millan, Maeva M, and Eigenbrode, Jennifer L

Subjects
Lunar And Planetary Science And Exploration
Abstract

A driving factor for sending the Mars Science Laboratory, Curiosity rover to Gale Crater was the orbital detection of clay minerals in the Glen Torridon (GT) clay unit. Clay mineral detections in GT suggested a past aqueous environment that was habitable, and could contain organic evidence of past microbiology. The mission of the Sample Analysis at Mars (SAM) instrument onboard Curiosity was to detect organic evidence of past microbiology and to detect volatile bearing mineralogy that can inform on whether past geochemical conditions would have supported microbiological activity. The objective of this work was to 1) evaluate the depositional/alteration conditions of Blunt’s Point (BP) to GT sediments 2) search for evidence of organics, and 3) evaluate microbial habitability in the BP, Vera Rubin Ridge (VRR), and GT sedimentary rock.

Published
2020

11. Evidence for indigenous nitrogen in sedimentary and aeolian deposits from the Curiosity rover investigations at Gale crater, Mars

Author

MSL Science Team, Stern, Jennifer C., Sutter, Brad, Freissinet, Caroline, Navarro-González, Rafael, McKay, Christopher P., Archer, P. Douglas, Buch, Arnaud, Brunner, Anna E., Coll, Patrice, Eigenbrode, Jennifer L., Fairen, Alberto G., Franz, Heather B., Glavin, Daniel P., Kashyap, Srishti, McAdam, Amy C., Ming, Douglas W., Steele, Andrew, Szopa, Cyril, Wray, James J., Martín-Torres, F. Javier, Zorzano, Maria-Paz, Conrad, Pamela G., and Mahaffy, Paul R.

Published
2015

12. THE MARKER BAND IN GALE CRATER:: A SYNTHESIS OF ORBITAL AND GROUND OBSERVATIONS

Author

Weitz, Catherine, Lewis, Kevin W., Kite, Edwin, Dietrich, William, Thompson, Lucy M., O’connell-Cooper, Catherine, Schieber, Juergen, Rubin, David M., Gasda, Patrick, Mondro, C. A., Seeger, Christina, Rapin, William, Gupta, Sanjeev, Roberts, Amelie, Frydenvang, Jens, Berger, Jeff, Newsom, Horton, Bryk, Alexander, Lamb, Michael P., Grotzinger, John, Fischer, W., Cowart, Aster, Davis, Joel, Grant, John A., Aileen Yingst, R., Farrand, William, Parker, Tim, Vasavada, Ashwin, Fraeman, Abigail, Milliken, Ralph, Sheppard, Rachel, Minitti, Michelle, Ming, Douglas W., Simpson, Sarah, Rampe, Elizabeth B., Mclennan, Scott, Fey, Deirdra M., Kubacki, Tex, Williams, Rebecca M.E., Arvidson, Ray, Caravaca, Gwénaël, Planetary Science Institute [Tucson] (PSI), Johns Hopkins University (JHU), University of Chicago, Department of Earth and Planetary Science [UC Berkeley] (EPS), University of California [Berkeley] (UC Berkeley), University of California (UC)-University of California (UC), University of New Brunswick (UNB), Indiana University [Bloomington], Indiana University System, University of California [Santa Cruz] (UC Santa Cruz), University of California (UC), Los Alamos National Laboratory (LANL), Division of Geological and Planetary Sciences [Pasadena], California Institute of Technology (CALTECH), Institut de recherche en astrophysique et planétologie (IRAP), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), Department of Earth Science and Engineering [Imperial College London], Imperial College London, University of Copenhagen = Københavns Universitet (UCPH), NASA Johnson Space Center (JSC), NASA, The University of New Mexico [Albuquerque], GeoRessources, Institut national des sciences de l'Univers (INSU - CNRS)-Centre de recherches sur la géologie des matières premières minérales et énergétiques (CREGU)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), Birkbeck College [University of London], Smithsonian Institution, Space Science Institute [Boulder] (SSI), Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Brown University, Planetary Geosciences Institute [Knoxville], Department of Earth and Planetary Sciences [Knoxville], The University of Tennessee [Knoxville]-The University of Tennessee [Knoxville], Stony Brook University [SUNY] (SBU), State University of New York (SUNY), Malin Space Science Systems (MSSS), Department of Earth and Planetary Sciences [St Louis], Washington University in Saint Louis (WUSTL), and Lunar and Planetary Institute

Subjects
[SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, [SDU]Sciences of the Universe [physics], [SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, Mars, sedimentology, stratigraphy, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, MSL, Marker Band, Gale crater, mineralogy
Abstract

International audience; The “Marker Band” (previously called the Marker Bed and Marker Horizon [1-4]) in Gale crater is a distinctive indurated and dark-toned unit observed in the strata of Mount Sharp. From orbital data, the Marker Band (MB) was mapped across much of the western and southern edges of Mount Sharp, spanning over 80 km in distance and 1.6 km in elevation [4]. CRISM spectra of the MB show no hydration signatures and broad absorptions around~1 and 2 μm interpreted to be from high-Ca pyroxene [4]. Favored origins for the MB based upon orbital observations included a more indurated sulfate, a sandstone, and a volcanic ash deposit. The Curiosity rover recently reached the MB and is now collecting critical in situ measurements to test these postulated and other origins and make new discoveries at the finer mm- to cm-scale that could not be assessed from orbital data. Here we provide a summary of several of the most crucial MB observations made by the rover thus far from sols 3640-3645 and 3668-present.

Published
2023

13. Evolved Gas Analyses of Sedimentary Rocks and Eolian Sediment in Gale Crater, Mars: Results of the Curiosity Rover's Sample Analysis at Mars Instrument.

Author

Sutter, Brad, McAdam, Amy, Mahaffy, Paul, Ming, Douglas W, Eigenbrode, Jennifer, Rampe, Elizabeth, Franz, Heather, Freissinet, Caroline, Steele, Andrew, House, Christopher, Archer, Doug, Malespin, Charles, Gonzalez, Rafael, and Glavin, Jennifer Stern2 and Daniel

Subjects
Solar Physics
Abstract

The Sample Analysis at Mars instrument evolved gas analyzer (SAM-EGA) has detected evolved water, SO2, NO, CO2, CO, O2, and HCl from two eolian sediments and nine sedimentary rocks from Gale Crater, Mars. The SAM-EGA heats samples to 870°C and measures evolved gas releases as function of temperature. These evolved gas detections indicate nitrates, organics, oxychlorine phase, and sulfates are widespread with phyllosilicates and carbonates occurring in select Gale Crater materials. CO2 and CO evolved at similar temperatures suggesting that as much as 2373 ± 820 μgC/g may occur as organic carbon in the Gale Crater rock record while relatively higher temperature CO2 detections are consistent with carbonate (<0.70 ± 0.1 wt % CO3). Evolved NO amounts up to 0.06 ± 0.03 wt % NO3 have been detected while O2 detections suggests chlorates and/or perchlorates (0.05 to 1.05 wt % ClO4) are present. Evolution of SO2 indicated the presence of crystalline and/or poorly crystalline Fe and Mg sulfate and possibly sulfide. Evolved H2O (0.9 - 2.5 wt% H2O) was consistent with the presence of adsorbed water, hydrated salts, interlayer/structural water from phyllosilicates, and possible inclusion water in mineral/amorphous phases. Evolved H2S detections suggest that reduced phases occur despite the presence of oxidized phases (nitrate, oxychlorine, sulfate, and carbonate). SAM results coupled with CheMin mineralogical and Alpha-Particle X-ray Spectrometer elemental analyses indicate that Gale Crater sedimentary rocks have experienced a complex authigenetic/diagenetic history involving fluids with varying pH, redox, and salt composition. The inferred geochemical conditions were favorable for microbial habitability and if life ever existed, there was likely sufficient organic C to support a small microbial population.

Published
2019

14. Aqueous Alteration on Mars

Author

Ming, Douglas W

Subjects
Lunar And Planetary Science And Exploration
Abstract

The occurrence of extensive valley networks and layered deposits of phyllosilicates and sulfates during the late Noachian/Hesperian periods (approx. 3-4 Gyrs) indicates a past martian climate that was capable of maintaining liquid water at the surface. The planet’s climate drastically changed after these early “episodes” of water to a drier and colder environment during the Amazonian period (past 3.0 Gyrs). The objective of this paper is to describe aqueous alteration/weathering scenarios on Mars based on observations returned by rover and lander missions. The chemistry of most outcrops, rocks, and “soils” that have interacted with water has not been extensively changed from average Mars crustal basaltic composition. Little chemical variation suggests closed hydrologic systems were prominent on early Mars and/or the water/rock ratios were low. Open hydrologic systems occur at local scales, e.g., high Si and Ti rocks and “soil” deposits around a volcanic feature in Gusev crater. Geochemical and mineralogical indicators for aqueous alteration include jarosite and other Fe-sulfates at several locations suggesting acid-sulfate alteration conditions. High Si and Ti rocks, sediments, and “soil” deposits are consistent with basaltic residues extenively leached by extremely acidic fluids. Variations in the Fe/Mn ratio of fracture veins infilled with sulfate-rich materials suggest changes in redox and/or pH conditions of the migrating fluids. The increase of nanophase iron oxides and salts with depth in several “soil” pits escavated by the Spirit rover’s wheel in Gusev crater suggests the translocation/mobolization of these phases by liquid water. This “pedogenic” process is the result of limited water movement through the surface sediments during the Amazonian period; however, it is likely that paleosols exist on Mars that formed during the early “wetter” history of the planet. Soil scientists have the opportunity to continue to (and should) be involved in the exploration of the Red planet.

Published
2019

15. Oxychlorine Detection in Gale Crater, Mars and Implications for past Environmental Conditions

Author

Archer, P. Douglas, Jr, Ming, Douglas W, Sutter, Brad, Morris, Richard V, Clark, B. C, Mahaffy, P. R, Wray, J .J, Fairen, A .G, Gellert, Ralf, Yen, Albert, Blake, David F, Vaniman, David T, Glavin, Daniel P, Eigenbrode, Jen, Trainer, M .G, Navarro-González, Rafael, McKay, Christopher P, Freissinet, Caroline, and Martin, Peter

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Sample Analysis at Mars (SAM) instrument on the Mars Science Laboratory (MSL) rover has detected oxychlorine compounds such as perchlorate or chlorate in Gale Crater samples. Two potential pathways for oxychlorine formation on Mars are UV-induced interaction between chlorine and metal oxides or atmospheric oxygen and radiolysis of Cl-containing surface materials by galactic cosmic rays, with the chlorine being volcanically derived in both cases. Oxychlorine compounds are identified by a diagnostic release of O2 at temperatures <600 °C and an HCl release from ~350-850 °C during sample pyrolysis. Of the 16 samples analyzed by SAM as of July 2018, 12 have contained oxychlorine compounds, including all four scooped samples and 8 of the 12 drilled samples.

Published
2018

16. Predicting Multi-Component Mineral Compositions in Gale Crater, Mars with Label Distribution Learning

Author

Morrison, Shaunna M, Pan, Feifei, Gane, Olivier C, Prabhu, Anirudh, Eleish, Ahmed, Fox, Peter Arthur, Downs, Robert T, Bristow, Thomas, Rampe, Elizabeth B, Blake, David F, Vaniman, David, Achilles, Cherie N, Ming, Douglas W, Yen, Albert S, Treiman, Allan H, Morris, Richard V, Chipera, Steve, Criag, Patricia, Tu, Valeria, Castle, Nicholas, Sarrazin, Phillippe, Des Marais, David J, and Hazen, Robert

Subjects
Lunar And Planetary Science And Exploration
Published
2018

17. Reworking and Diagenesis of Martian Soil: Pathway to Murray Formation Sediments?

Author

Yen, Albert S, Ming, Douglas W, Achilles, Cherie, Berger, Jeff A, Clark, Benton C, Downs, Robert T, Gellert, Ralf, Morris, Richard V, Morrison, Shaunna M, O'Connell-Cooper, Catherine, Rampe, Elizabeth B, Salvatore, Mark R, Sullivan, Robert J, and Thompson, Lucy M

Subjects
Lunar And Planetary Science And Exploration, Exobiology
Abstract

In Gale crater, the Curiosity Mars rover has climbed over 300 meters of the Murray formation from the base of the Pahrump Hills to the crest of Vera Rubin Ridge. We discuss the possibility that fine-grained mudstone of the Murray formation is a diagenetic product of sediments with a chemical and mineralogical composition similar to present-day martian soil. Typical (low Ca-sulfate) Murray samples have Na2O, Al2O3, SiO2, SO3, TiO2 and FeOT concentrations within 10% (relative) of average martian soil. These oxides constitute ~85% of each sample. The Al/Si and Ti/Si ratios of Murray samples are comparable to average martian soil but distinct from other martian geologic units. Percentage difference in P2O5, Cl, K2O, Cr2O3, MnO, Ni, Zn, Br, and Ge between soil and Murray samples generally exceed 10%, but these elements and oxides amount to less than 4% of the samples. These constituents are highly variable in Murray mudstone and may reflect mobility in fluid interactions. Large discrepancies in MgO and CaO with ~50% lower concentrations in the Murray samples (~2% absolute differences) are indicative of open-system alteration if the Murray mudstone originated from soil-like material. Mineralogically, martian soil is dominated by plagioclase feldspar, pyroxenes, and olivine with minor hematite, magnetite, and Ca-sulfate. In comparison, Murray samples generally have less feldspar and pyroxene, little to no olivine, more iron oxides and Ca-sulfates, and Fe-containing phyllosilicates. If Murray mudstone originated from a Mars soil composition, aqueous alteration could have converted olivine and pyroxenes to iron oxides and phyllosilicates. Intermixed or zoned plagioclase feldspars could have lost a larger portion of calcic constituents, consistent with susceptibility to weathering, resulting in a change from ~An55 (soil) to ~An40 (Murray). This alteration could be consistent with the major element chemistry, including the small decrease in MgO and CaO. A subsequent influx of minor/trace elements and Ca-sulfate, e.g. from groundwater, would be required. In this diagenetic scenario, the bulk of the alteration would have been nearly isochemical, suggesting limited mineral segregation and aqueous alteration during transport from the drainage basin or a significant direct aeolian contribution to the Murray sediments.

Published
2018

19. An Experimental Flow-Through Assessment of Acidic Fe/Mg Smectite Formation on Early Mars

Author

Sutter, Brad, Peretyazhko, Tanya, Garcia, Angela H, and Ming, Douglas W

Subjects
Lunar And Planetary Science And Exploration
Abstract

Orbital observations have detected the phyllosilicate smectite in layered material hundreds of meters thick, intracrater depositional fans, and plains sediments on Mars; however, the detection of carbonate deposits is limited. Instead of neutral/alkaline conditions during the Noachian, early Mars may have experienced mildly acidic conditions derived from volcanic acid-sulfate solutions that allowed Fe/Mg smectite formation but prevented widespread carbonate formation. The detection of acid sulfates (e.g., jarosite) associated with smectite in Mawrth Vallis supports this hypothesis. Previous work demonstrated smectite (saponite) formation in closed hydrologic systems (batch reactor) from basaltic glass at pH 4 and 200°C (Peretyazhko et al., 2016 GCA). This work presents results from alteration of basaltic glass from alkaline to acidic conditions in open hydrologic systems (flow-through reactor). Preliminary experiments exposed basaltic glass to deionized water at 190°C at 0.25 ml/min where solution pH equilibrated to 9.5. These initial high pH experiments were conducted to evaluate the flow-through reactor system before working with lower pHs. Smectite at this pH was not produced and instead X-ray diffraction results consistent with serpentine was detected. Experiments are in progress exposing basaltic glass from pH 8 down to pH 3 to determine what range of pHs could allow for smectite formation in this experimental opensystem. The production of smectite under an experimental open-system at low pHs if successful, would support a significant paradigm shift regarding the geochemical evolution of early Mars: Early Mars geochemical solutions were mildly acidic, not neutral/alkaline. This could have profound implications regarding early martain microbiology where acid conditions instead of neutral/alkaline conditions will require further research in terrestrial analogs to address the potential for biosignature preservation on Mars.

Published
2017

20. Oxychlorine Species in Gale Crater and Broader Implications for Mars

Author

Ming, Douglas W, Sutter, Brad, Morris, Richard V, Clark, B. C, Mahaffy, P. H, Archilles, C, Wray, J. J, Fairen, A. G, Gellert, Ralf, Yen, Albert, Blake, David, Vaniman, David T, Glavin, Daniel P, Eigenbrode, Jen, Trainer, M. G, Navarro-Gonzalez, Rafael, McKay, Christopher P, Freissinet, Caroline, and Martin, Peter

Subjects
Lunar And Planetary Science And Exploration
Abstract

Of 15 samples analyzed to date, the Sample Analysis at Mars (SAM) instrument on the Mars Science Laboratory (MSL) has detected oxychlorine compounds (perchlorate or chlorate) in 12 samples. The presence of oxychlorine species is inferred from the release of oxygen at temperatures less than 600degC and HCl between 350-850degC when a sample is heated to 850degC. The O2 release temperature varies with sample, likely caused by different cations, grain size differences, or catalytic effects of other minerals. In the oxychlorine-containing samples, perchlorate abundances range from 0.06 +/- 0.03 to 1.15 +/- 0.5 wt% Cl2O7 equivalent. Comparing these results to the elemental Cl concentration measured by the Alpha Particle X-ray Spectrometer (APXS) instrument, oxychlorine species account for 5-40% of the total Cl present. The variation in oxychlorine abundance has implications for their production and preservation over time. For example, the John Klein (JK) and Cumberland (CB) samples were acquired within a few meters of each other and CB contained approximately1.2 wt% Cl2O7 equivalent while JK had approximately 0.1 wt%. One difference between the two samples is that JK has a large number of veins visible in the drill hole wall, indicating more post-deposition alteration and removal. Finally, despite Cl concentrations similar to previous samples, the last three Murray formation samples (Oudam, Marimba, and Quela) had no detectable oxygen released during pyrolysis. This could be a result of oxygen reacting with other species in the sample during pyrolysis. Lab work has shown this is likely to have occurred in SAM but it is unlikely to have consumed all the O2 released. Another explanation is that the Cl is present as chlorides, which is consistent with data from the ChemCam (Chemical Camera) and CheMin (Chemistry and Mineralogy) instruments on MSL. For example, the Quela sample has approximately1 wt% elemental Cl detected by APXS, had no detectable O2 released, and halite (NaCl) has been tentatively identified in CheMin X-ray diffraction data. These data show that oxychlorines are likely globally distributed on Mars but the distribution is heterogenous depending on the perchlorate formation mechanism (production rate), burial, and subsequent diagenesis

Published
2017

21. Oxidized and Reduced Sulfur Observed by the Sample Analysis at Mars (SAM) Instrument Suite on the Curiosity Rover Within the Glen Torridon Region at Gale Crater, Mars

Author

Wong, Gregory M., primary, Franz, Heather B., additional, Clark, Joanna V., additional, McAdam, Amy C., additional, Lewis, James M. T., additional, Millan, Maëva, additional, Ming, Douglas W., additional, Gomez, Felipe, additional, Clark, Benton, additional, Eigenbrode, Jennifer L., additional, Navarro‐González, Rafael, additional, and House, Christopher H., additional

Published
2022
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26. Origin of the Two Scales of Wind Ripples on Mars

Author

Lapotre, Mathieu G. A, Ewing, Ryan C, Lamb, Michael P, Fischer, Woodward W, Grotzinger, John P, Rubin, David M, Lewis, Kevin W, Day, Mackenzie, Gupta, Sanjeev, Banham, Steeve G, Bridges, Nathan T, DesMarais, David J, Fraeman, Abigail A, Grant, John A, Herkenhoff, Kenneth E, Ming, Douglas W, Mischna, Michael A, Rice, Melissa S, Sumner, Dawn A, Vasavada, Ashwin R, and Yingst, R. Aileen

Subjects
Lunar And Planetary Science And Exploration
Abstract

Earth's sandy deserts host two main types of bedforms - decimeter-scale ripples and larger dunes. Years of orbital observations on Mars also confirmed the existence of two modes of active eolian bedforms - meter-scale ripples, and dunes. By analogy to terrestrial ripples, which are thought to form from a grain mechanism, it was hypothesized that large martian ripples also formed from grain impacts, but spaced further apart due to elongated saltation trajectories from the lower martian gravity and different atmospheric properties. However, the Curiosity rover recently documented the coexistence of three scales of bedforms in Gale crater. Because a grain impact mechanism cannot readily explain two distinct and coeval ripple modes in similar sand sizes, a new mechanism seems to be required to explain one of the scales of ripples. Small ripples are most similar to Earth's impact ripples, with straight crests and subdued profiles. In contrast, large martian ripples are sinuous and asymmetric, with lee slopes dominated by grain flows and grainfall deposits. Thus, large martian ripples resemble current ripples formed underwater on Earth, suggesting that they may form from a fluid-drag mechanism. To test this hypothesis, we develop a scaling relation to predict the spacing of fluid-drag ripples from an extensive flume data compilation. The size of large martian ripples is predicted by our scaling relation when adjusted for martian atmospheric properties. Specifically, we propose that the wavelength of martian wind-drag ripples arises from the high kinematic viscosity of the low-density atmosphere. Because fluid density controls drag-ripple size, our scaling relation can help constrain paleoatmospheric density from wind-drag ripple stratification.

Published
2016

27. The Sample at Mars Analysis (SAM) Detections of CO2 and CO in Sedimentary Material from Gale Crater, Mars: Implications for the Presence of Organic Carbon and Microbial Habitability on Mars

Author

Sutter, Brad, Eigenbrode, Jennifer L, Steele, Andrew, and Ming, Douglas W

Subjects
Exobiology, Lunar And Planetary Science And Exploration
Abstract

Sedimentary rock samples heated to 860 degrees Centigrade in the SAM (Sample at Mars) instrument evolved CO2 and CO indicating the presence of organic-carbon(C) in Gale Crater materials. Martian or exogenous (meteoritic, interplanetary dust) CO2 and CO could be derived from combustion of simple organics (less than 300 degrees Centigrade), complex refractory organics/amorphous carbon (300-600 degrees Centigrade), and/or magmatic carbon (greater than 600 degrees Centigrade) as result of thermal decomposition of Gale Crater perchlorates, and sulfates present that produce O2. Oxidized organic compounds could also evolve CO2 and CO over broad temperature range (150 to 800 degrees Centigrade) and such organics are expected on Mars via exogenous sources. Alternatively, organic-C could also have been oxidized to carboxylic acids [e.g, mellitic acid (RCOOH), acetate (CH3CO2-), and oxalates (C2O42-)] by oxidative radiolytic weathering, or other oxidation processes. The presence of oxidized organics is consistent with the limited detection of reduced organic-C phases by the SAM-gas chromatography. Organic-C content as determined by CO2 and CO contents could range between 800 and 2400 parts per million C indicating that substantial organic-C component is present in Gale Crater. There are contributions from SAM background however, even in worst-case scenarios, this would only account for as much as half of the detected CO2 and CO. Nevertheless, if organic-C levels were assumed to have existed in a reduced form on ancient Mars and this was bioavailable C, then less than 1 percent of C in Gale Crater sediments could have supported an exclusively heterotrophic microbial population of 1 by 10 (sup 5) cells per gram sediment (assumes 9 by 10 (sup -7) microgram per cell and 0.5 micrograms C per microgram cell). While other essential nutrients (e.g., S and P) could be limiting, organic-C contents, may have been sufficient to support limited heterotrophic microbial populations on ancient Mars.

Published
2016

28. Similarities Across Mars: Acidic Fluids at Both Meridiani Planum and Gale Crater in the Formation of Magnesium-Nickel Sulfates

Author

Yen, Albert S, Ming, Douglas W, Gellert, Ralf, Mittlefehldt, David W, Vaniman, David T, Thompson, Lucy M, Morris, Richard V, Clark, Benton C, and Arvidson, Raymond

Subjects
Lunar And Planetary Science And Exploration
Abstract

In-situ identification of sulfates at the martian surface by the Mars Exploration Rovers and the Mars Science Laboratory have included calcium sulfates with various states of hydration (gypsum, bassanite, anhydrite), iron sulfates of likely fumarolic origin, massive deposits of iron hydroxysulfates indicative of an acidic history, and minor occurrences of magnesium sulfates. Recent measurements by the Opportunity and Curiosity Alpha Particle X-ray Spectrometers (APXS) have indicated the presence of Ni-substituted Mg-sulfates at the Meridiani Planum and Gale Crater landing sites. The Opportunity rover has traversed nearly 43 km and is currently exploring the impact breccias of the rim of Endeavour crater, near a location where signatures of aqueous alteration have been established from orbit. APXS analyses of subsurface materials excavated by a rover wheel show clear evidence for a Mg(Ni)-sulfate with Mg:Ni (is) approximately 100:1 (molar). On the other side of the planet, Curiosity is continuing its climb up Mount Sharp after driving (is) approximately 13 km since landing. Over the last 4 km of the traverse, there have been multiple chemical analyses of erosionally-resistant nodules and dendritic features in a finely laminated mudstone unit which also indicate Mg(Ni)-sulfate (Mg:Ni (is) approximately 30:1, molar). The geologic settings for the Endeavour rim and the Mount Sharp mudstones are clearly different, but similar formation conditions for these sulfates may be possible. Ni(2+) readily substitutes for Mg(2+) in a variety of geochemical processes due to their comparable ionic radii. The availability of soluble Ni at the time of Mg-sulfate precipitation suggests acidic solutions. The fluids responsible for alteration in the Endeavour rim and for the formation of nodules in Gale mudstones may have had similar chemical characteristics at the time the Mg-sulfates were formed.

Published
2016

29. Oxychlorine Species on Mars: Implications from Gale Crater Samples

Author

Archer, P. Douglas, Jr, Ming, Douglas W, Sutter, Brad, Morris, Richard V, Clark, B. C, Mahaffy, P. H, Wray, J. J, Fairen, A. G, Gellert, Ralf, Yen, Albert, Blake, David F, Glavin, Daniel P, Eigenbrode, Jen, Trainer, M. G, McKay, Christopher P, and Freissinet, Caroline

Subjects
Lunar And Planetary Science And Exploration
Abstract

Evidence of oxychlorine species such as perchlorates or chlorates have been detected in nearly every acquired sample analyzed on the surface of Mars. Perchlorates were first discovered by the Wet Chemistry Laboratory (WCL) instrument on the Phoenix lander in 2008. The Sample Analysis at Mars (SAM) instrument on the Mars Science Laboratory (MSL) has analyzed twelve samples from Gale Crater (as of July 2016), nine drilled samples and three scooped samples. After delivery to SAM, samples are heated to approximately 850 C and evolved gases are measured by a quadrupole mass spectrometer.

Published
2016

30. Is Tridymite at Gale Crater Evidence for Silicic Volcanism on Mars?

Author

Morris, Richard V, Vaniman, David T, Ming, Douglas W, Graff, Trevor G, Downs, Robert T, Fendrich, Kim, and Mertzman, Stanley A

Subjects
Geophysics, Lunar And Planetary Science And Exploration
Abstract

The X-ray diffraction (XRD) instrument (CheMin) onboard the MSL rover Curiosity detected 17 wt% of the SiO2 polymorph tridymite (relative to bulk sample) for the Buckskin drill sample (73 wt% SiO2) obtained from sedimentary rock in the Murray formation at Gale Crater, Mars. Other detected crystalline materials are plagioclase, sanidine, cristobalite, cation-deficient magnetite, and anhydrite. XRD amorphous material constitutes approx. 60 wt% of bulk sample, and the position of its broad diffraction peak near approx. 26 deg. 2-theta is consistent with opal-A. Tridymite is a lowpressure, high-temperature mineral (approx. 870 to 1670 deg. C) whose XRD-identified occurrence on the Earth is usually associated with silicic (e.g., rhyolitic) volcanism. High SiO2 deposits have been detected at Gale crater by remote sensing from martian orbit and interpreted as opal-A on the basis H2O and Si-OH spectral features. Proposed opal-A formation pathways include precipitation of silica from lake waters and high-SiO2 residues of acid-sulfate leaching. Tridymite is nominally anhydrous and would not exhibit these spectral features. We have chemically and spectrally analyzed rhyolitic samples from New Mexico and Iwodake volcano (Japan). The glassy (by XRD) NM samples have H2O spectral features similar to opal-A. The Iwodake sample, which has been subjected to high-temperature acid sulfate leaching, also has H2O spectral features similar to opal-A. The Iwodake sample has approx. 98 wt% SiO2 and 1% wt% TiO2 (by XRF), tridymite (>80 wt.% of crystalline material without detectable quartz by XRD), and H2O and Si-OH spectral features. These results open the working hypothesis that the opal-A-like high-SiO2 deposits at Gale crater detected from martian orbit are products of alteration associated with silicic volcanism. The presence or absence of tridymite will depend on lava crystallization temperatures (NM) and post crystallization alteration temperatures (Iwodake).

Published
2016

31. Localized and Areally Extensive Alterations in Marathon Valley, Endeavour Crater Rim, Mars

Author

Mittlefehldt, David W, Gellert, Ralf, Van Bommel, Scott, Arvidson, Raymond E, Clark, Benton C, Cohen, Barbara A, Farrand, William H, Ming, Douglas W, Schroeder, Christian, Yen, Albert S, and Jolliff, Bradley L

Subjects
Lunar And Planetary Science And Exploration
Abstract

Mars Exploration Rover Opportunity is exploring the rim of 22 km diameter, Noachian-aged Endeavour crater. Marathon Valley cuts through the central region of the western rim providing a window into the local lower rim stratigraphic record. Spectra from the Compact Reconnaissance Imaging Spectrometer for Mars show evidence for the occurrence of Fe-Mg smectite in this valley, indicating areally extensive and distinct lithologic units and/or styles of aqueous alteration. The Alpha Particle X-ray Spectrometer has determined the compositions of 59 outcrop targets on untreated, brushed and abraded surfaces. Rocks in the Marathon Valley region are soft breccias composed of mm- to cm-sized darker clasts set in a lighter-toned, finegrained matrix. They are basaltic in non-volatile-element composition and compositionally similar to breccias investigated elsewhere on the rim. Alteration styles recorded in the rocks include: (1) Enrichments in Si, Al, Ti and Cr in more reddish-colored rock, consistent with leaching of more soluble cations and/or precipitation of Si +/- Al, Ti, Cr from fluids. Coprecipitation of Ge-rich phases with Si occurred in the western area only; high water:rock is indicated. Pancam multispectral observations indicate higher nanophase ferric oxide contents, but the rocks have lower Fe contents. The highly localized nature of the red zones indicate they cannot be the source of the widespread smectite signature observed from orbit. (2) Outcrops separated by approximately 65 m show common compositional changes between brushed and abraded (approximately 1 mm deep) targets: increases in S and Mg; decreases in Al, Cl and Ca. These changes are likely due to relatively recent, surface-related alteration of valley rocks and formation of surface coatings under low water:rock. (3) One target, from the center of a region of strong CRISM smectite signature, shows modest differences in composition (higher Si, K; lower Mn) compared to most Marathon Valley rocks, while another target approximately 40 cm away on the same outcrop does not; a change towards smectite bulk compositions is not observed. The smectite signature likely resulted from alteration under low water:rock such that primary minerals were partially altered to phyllosilicates, but wholesale leaching of cations by fluids did not occur.

Published
2016

32. Investigating the Growth of Algae Under Low Atmospheric Pressures for Potential Food and Oxygen Production on Mars

Author

Cycil, Leena M., Hausrath, Elisabeth M., Ming, Douglas W., Adcock, Christopher T., Raymond, James, Remias, Daniel, and Ruemmele, Warren P.

Subjects
low pressure chamber, BLSS, life on mars, extremophilic algae, Microbiology, QR1-502, Original Research, space biology
Abstract

With long-term missions to Mars and beyond that would not allow resupply, a self-sustaining Bioregenerative Life Support System (BLSS) is essential. Algae are promising candidates for BLSS due to their completely edible biomass, fast growth rates and ease of handling. Extremophilic algae such as snow algae and halophilic algae may also be especially suited for a BLSS because of their ability to grow under extreme conditions. However, as indicated from over 50 prior space studies examining algal growth, little is known about the growth of algae at close to Mars-relevant pressures. Here, we explored the potential for five algae species to produce oxygen and food under low-pressure conditions relevant to Mars. These included Chloromonas brevispina, Kremastochrysopsis austriaca, Dunaliella salina, Chlorella vulgaris, and Spirulina plantensis. The cultures were grown in duplicate in a low-pressure growth chamber at 670 ± 20 mbar, 330 ± 20 mbar, 160 ± 20 mbar, and 80 ± 2.5 mbar pressures under continuous light exposure (62–70 μmol m–2 s–1). The atmosphere was evacuated and purged with CO2 after sampling each week. Growth experiments showed that D. salina, C. brevispina, and C. vulgaris were the best candidates to be used for BLSS at low pressure. The highest carrying capacities for each species under low pressure conditions were achieved by D. salina at 160 mbar (30.0 ± 4.6 × 105 cells/ml), followed by C. brevispina at 330 mbar (19.8 ± 0.9 × 105 cells/ml) and C. vulgaris at 160 mbar (13.0 ± 1.5 × 105 cells/ml). C. brevispina, D. salina, and C. vulgaris all also displayed substantial growth at the lowest tested pressure of 80 mbar reaching concentrations of 43.4 ± 2.5 × 104, 15.8 ± 1.3 × 104, and 57.1 ± 4.5 × 104 cells per ml, respectively. These results indicate that these species are promising candidates for the development of a Mars-based BLSS using low pressure (∼200–300 mbar) greenhouses and inflatable structures that have already been conceptualized and designed.

Published
2021
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34. Nanophase Carbonates on Mars: Does Evolved Gas Analysis of Nanophase Carbonates Reveal a Large Organic Carbon Budget in Near-Surface Martian Materials?

Author

Archer, P. Douglas, Jr, Niles, Paul B, Ming, Douglas W, Sutter, Brad, and Eigenbrode, Jen

Subjects
Lunar And Planetary Science And Exploration
Abstract

Evolved Gas Analysis (EGA), which involves heating a sample and monitoring the gases released, has been performed on Mars by the Viking gas chromatography/mass spectrometry instruments, the Thermal and Evolved Gas Analyzer (TEGA) on the Phoenix lander, and the Sample Analysis at Mars (SAM) instrument on the Mars Science Laboratory. All of these instruments detected CO2 released during sample analysis at abundances of approx. 0.1 to 5 wt% assuming a carbonate source. The source of the CO2 can be constrained by evaluating the temperature of the gas release, a capability of both the TEGA and SAM instruments. The samples analyzed by SAM show that the majority of the CO2 is released below 400C, much lower than traditional carbonate decomposition temperatures which can be as low as 400C for some siderites, with magnesites and calcites decomposing at even higher temperatures. In addition to mineralogy, decomposition temperature can depend on particle size (among other factors). If carbonates formed on Mars under low temperature and relative humidity conditions, the resulting small particle size (nanophase) carbonates could have low decomposition temperatures. We have found that calcite can be synthesized by exposing CaO to water vapor and CO2 and that the resulting mineral has an EGA peak of approx. 550C for CO2, which is about 200C lower than for other calcites. Work is ongoing to produce Fe and Mg-bearing carbonates using the same process. Current results suggest that nanophase calcium carbonates cannot explain the CO2 released from martian samples. If the decomposition temperatures of Mg and Fe-bearing nanophase carbonates are not significantly lower than 400C, other candidate sources include oxalates and carboxylated organic molecules. If present, the abundance of organic carbon in these samples could be greater than 0.1 wt % (1000s of ppm), a signficant departure from the paradigm of the organic-poor Mars based on Viking results.

Published
2015

35. Distinct Igneous APXS Rock Compositions on Mars from Pathfinder, MER and MSL

Author

Gellert, Ralf, Arvidson, Raymond, Clark, Benton, III, Ming, Douglas W, Morris, Richard V, Squyres, Steven W, and Yen, Albert S

Subjects
Lunar And Planetary Science And Exploration, Geophysics
Abstract

The alpha particle x-ray spectrometer (APXS) on all four Mars Rovers returned geochemical data from about 1000 rocks and soils along the combined traverses of over 50 kilometers. Here we discuss rocks likely of igneous origin, which might represent source materials for the soils and sediments identified along the traverses. Adirondack-type basalts, abundant in the plains of Gusev Crater, are primitive, olivine bearing basalts. They resemble in composition the basaltic soils encountered at all landing sites, except the ubiquitous elevated S, Cl and Zn in soils. They have been postulated to represent closely the average Martian crust composition. The recently identified new Martian meteorite Black Beauty has similar overall geochemical composition, very distinct from the earlier established SNC meteorites. The rim of the Noachian crater Endeavour, predating the sulfate-bearing Burns formation at Meridiani Planum, also resembles closely the composition of Adirondack basalts. At Gale Crater, the MSL Curiosity rover identified a felsic rock type exemplified by the mugearitic float rock JakeM, which is widespread along the traverse at Gale. While a surprise at that time, possibly related more evolved, alkaline rocks had been previously identified on Mars. Spirit encountered the Wishstone rocks in the Columbia Hills with approx. 6% Na2O+K2O, 15 % Al2O3 and low 12% FeO. Pathfinder rocks with elevated K and Na and >50% SiO2 were postulated to be andesitic. Recently Opportunity encountered the rock JeanBaptisteCharbonneau with >15% Al2O3, >50% SiO2 and approx. 10% FeO. A common characteristic all these rocks is the very low abundance of Cr, Ni and Zn, and an Fe/Mn ratio of about 50, indicating an unaltered Fe mineralogy. Beside these likely igneous rock types, which occurred always in several rocks, a few unique rocks were encountered, e.g. Bounce Rock, a pyroxene-bearing ejecta rock fragment resembling the Shergottite EETA 79001B meteorite. The APXS data can be used to relate the findings of all 4 landing sites, constrain the water to rock ratio of sediments or imply source rock provenance. Beyond that the capability to quantify important volatile elements like P, S, Cl, and Br have provided new insights into the chemistry and the environment present during the formation of the sediments.

Published
2015

36. Aqueous Alteration on Mars: Evidence from Landed Missions

Author

Ming, Douglas W, Morris, Richard V, Clark, Benton C., III, Yen, Albert S, and Gellert, Ralf

Subjects
Lunar And Planetary Science And Exploration, Exobiology
Abstract

Mineralogical and geochemical data returned by orbiters and landers over the past 15 years have substantially enhanced our understanding of the history of aqueous alteration on Mars. Here, we summarize aqueous processes that have been implied from data collected by landed missions. Mars is a basaltic planet. The geochemistry of most materials has not been “extensively” altered by open-system aqueous processes and have average Mars crustal compositions. There are few examples of open-system alteration, such as Gale crater’s Pahrump Hills mudstone. Types of aqueous alteration include (1) acid-sulfate and (2) hydrolytic (circum-neutral/alkaline pH) with varying water-to-rock ratios. Several hypotheses have been suggested for acid-sulfate alteration including (1) oxidative weathering of ultramafic igneous rocks containing sulfides; (2) sulfuric acid weathering of basaltic materials; (3) acid fog weathering of basaltic materials; and (4) near-neutral pH subsurface solutions rich in Fe (sup 2 plus) that rapidly oxidized to Fe (sup 3 plus) producing excess acidity. Meridiani Planum’s sulfate-rich sedimentary deposit containing jarosite is the most “famous” acid-sulfate environment visited on Mars, although ferric sulfate-rich soils are common in Gusev crater’s Columbia Hills and jarosite was recently discovered in the Pahrump Hills. An example of aqueous alteration under circum-neutral pH conditions is the formation of Fe-saponite with magnetite in situ via aqueous alteration of olivine in Gale crater’s Sheepbed mudstone. Circum-neutral pH, hydrothermal conditions were likely required for the formation of Mg-Fe carbonate in the Columbia Hills. Diagenetic features (e.g., spherules, fracture filled veins) indicate multiple episodes of aqueous alteration/diagenesis in most sedimentary deposits. However, low water-to-rock ratios are prominent at most sites visited by landed missions (e.g., limited water for reaction to form crystalline phases possibly resulting in large amounts of short-range ordered materials and little physical separation of primary and secondary materials). Most of the aqueous alteration appears to have occurred early in the planet’s history; however, minor aqueous alteration may be occurring at the surface today (e.g., thin films of water forming carbonates akin to those discovered by Phoenix).

Published
2015

37. Compositions of Diverse Noachian Lithologies at Marathon Valley, Endeavour Crater Rim, Mars

Author

Mittlefehldt, David W, Gellert, Ralf, Yen, Albert S, Ming, Douglas W, Van Bommel, Scott, Farrand, William H, Arvidson, Raymond E, and Rice, James W., Jr

Subjects
Lunar And Planetary Science And Exploration
Abstract

Mars Exploration Rover Opportunity has been exploring Meridiani Planum for 11+ years, and is presently investigating the geology of rim segments of 22 km diameter, Noachian-aged Endeavour crater. The Alpha Particle X-ray Spectrometer has determined the compositions of a pre-impact lithology and impact breccias representing ejecta from the crater. Opportunity is now investigating the head (higher elevation, western end) of Marathon Valley. This valley cuts eastward through the central portion of the Cape Tribulation rim segment and provides a window into the lower stratigraphic record of the rim. At the head of Marathon Valley is a shallow (few 10s of cm), ovoid depression approximately 27×36 m in size, named Spirit of Saint Louis, that is surrounded by approximately 20-30 cm wide zone of more reddish rocks (red zone). Opportunity has just entered a region of Marathon Valley that shows evidence for Fe-Mg smectite in Compact Reconnaissance Imaging Spectrometer for Mars spectra indicating areally extensive and distinct lithologic units and/or styles of aqueous alteration. Rocks at the head of Marathon Valley and within Spirit of Saint Louis are breccias (valley-head rocks). In some areas, layering inside Spirit of Saint Louis appears continuous with the rocks outside. The valley-head rocks are of similar, generally basaltic composition. The continuity in composition, texture and layering suggest the valley-head rocks are coeval breccias, likely from the Endeavour impact. These local breccias are similar in non-volatile-element composition to breccias investigated elsewhere on the rim. Rocks within the red zone are like those on either side in texture, but have higher Al, Si and Ge, and lower S, Mn, Fe, Ni and Zn as compared to rocks on either side. The valley-head rocks have higher S than most Endeavour rim breccias, while red zone rocks are like those latter breccias in S. Patches within the rocks outside Spirit of Saint Louis have higher Al, Si and Ge indicating red-zone-style alteration extended beyond the narrow red zone. Rocks on either side of the red zone and patches within it have the multispectral signature (determined by Panoramic Camera) of red hematite indicating an oxidizing environment. The red zone appears to be a thin alteration zone marking the border of Spirit of Saint Louis, but the origin of this morphologic feature remains obscure.

Published
2015

38. The Sample Analysis at Mars Investigation and Instrument Suite

Author

Mahaffy, Paul R., Webster, Christopher R., Cabane, Michel, Conrad, Pamela G., Coll, Patrice, Atreya, Sushil K., Arvey, Robert, Barciniak, Michael, Benna, Mehdi, Bleacher, Lora, Brinckerhoff, William B., Eigenbrode, Jennifer L., Carignan, Daniel, Cascia, Mark, Chalmers, Robert A., Dworkin, Jason P., Errigo, Therese, Everson, Paula, Franz, Heather, Farley, Rodger, Feng, Steven, Frazier, Gregory, Freissinet, Caroline, Glavin, Daniel P., Harpold, Daniel N., Hawk, Douglas, Holmes, Vincent, Johnson, Christopher S., Jones, Andrea, Jordan, Patrick, Kellogg, James, Lewis, Jesse, Lyness, Eric, Malespin, Charles A., Martin, David K., Maurer, John, McAdam, Amy C., McLennan, Douglas, Nolan, Thomas J., Noriega, Marvin, Pavlov, Alexander A., Prats, Benito, Raaen, Eric, Sheinman, Oren, Sheppard, David, Smith, James, Stern, Jennifer C., Tan, Florence, Trainer, Melissa, Ming, Douglas W., Morris, Richard V., Jones, John, Gundersen, Cindy, Steele, Andrew, Wray, James, Botta, Oliver, Leshin, Laurie A., Owen, Tobias, Battel, Steve, Jakosky, Bruce M., Manning, Heidi, Squyres, Steven, Navarro-González, Rafael, McKay, Christopher P., Raulin, Francois, Sternberg, Robert, Buch, Arnaud, Sorensen, Paul, Kline-Schoder, Robert, Coscia, David, Szopa, Cyril, Teinturier, Samuel, Baffes, Curt, Feldman, Jason, Flesch, Greg, Forouhar, Siamak, Garcia, Ray, Keymeulen, Didier, Woodward, Steve, Block, Bruce P., Arnett, Ken, Miller, Ryan, Edmonson, Charles, Gorevan, Stephen, and Mumm, Erik

Published
2012
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40. A review of sample analysis at mars-evolved gas analysis laboratory analog work supporting the presence of perchlorates and chlorates in gale crater, mars

Author

Clark, Joana, Sutter, Brad, Douglas Archer Jr, P., Ming, Douglas W., Rampe, Elizabeth, McAdam, Amy, Navarro-González, Rafael, Eigenbrode, Jennifer L., Glavin, Daniel P., Zorzano, María Paz, Martín-Torres, F. J., Morris, Richard V., Tu, Valerie, Ralston, S. J., Mahaffy, Paul, and Ministerio de Ciencia e Innovación (España)

Subjects
Perchlorates, Chlorides, Oxychlorines, Chlorates, Sample Analysis at Mars, MSL, Curiosity Gale crater
Abstract

The Sample Analysis at Mars (SAM) instrument on the Curiosity rover has detected evidence of oxychlorine compounds (i.e., perchlorates and chlorates) in Gale crater, which has implications for past habitability, diagenesis, aqueous processes, interpretation of in situ organic analyses, understanding the martian chlorine cycle, and hazards and resources for future human exploration. Pure oxychlorines and mixtures of oxychlorines with Mars-analog phases have been analyzed for their oxygen (O ) and hydrogen chloride (HCl) releases on SAM laboratory analog instruments in order to constrain which phases are present in Gale crater. These studies demonstrated that oxychlorines evolve O releases with peaks between ~200 and 600 C, although the thermal decomposition temperatures and the amount of evolved O decrease when iron phases are present in the sample. Mg and Fe oxychlorines decompose into oxides and release HCl between ~200 and 542 C. Ca, Na, and K oxychlorines thermally decompose into chlorides and do not evolve HCl by themselves. However, the chlorides (original or from oxychlorine decomposition) can react with water-evolving phases (e.g., phyllosilicates) in the sample and evolve HCl within the temperature range of SAM (

Published
2021

41. A Review of the Phyllosilicates in Gale Crater as Detected by the CheMin Instrument on the Mars Science Laboratory, Curiosity Rover

Author

Tu, Valerie M., primary, Rampe, Elizabeth B., additional, Bristow, Thomas F., additional, Thorpe, Michael T., additional, Clark, Joanna V., additional, Castle, Nicholas, additional, Fraeman, Abigail A., additional, Edgar, Lauren A., additional, McAdam, Amy, additional, Bedford, Candice, additional, Achilles, Cherie N., additional, Blake, David, additional, Chipera, Steve J., additional, Craig, Patricia I., additional, Des Marais, David J., additional, Downs, Gordon W., additional, Downs, Robert T., additional, Fox, Valerie, additional, Grotzinger, John P., additional, Hazen, Robert M., additional, Ming, Douglas W., additional, Morris, Richard V., additional, Morrison, Shaunna M., additional, Pavri, Betina, additional, Eigenbrode, Jennifer, additional, Peretyazhko, Tanya S., additional, Sarrazin, Philippe C., additional, Sutter, Brad, additional, Treiman, Allan H., additional, Vaniman, David T., additional, Vasavada, Ashwin R., additional, Yen, Albert S., additional, and Bridges, John C., additional

Published
2021
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43. Phosphates at the Surface of Mars: Primary Deposits and Alteration Products

Author

Yen, Albert S, Gellert, Ralf, Clark, Benton C, Ming, Douglas W, Mittlefehldt, David W, Arvidson, Raymond E, McSween, Harry Y., Jr, and Schroder, Christian

Subjects
Lunar And Planetary Science And Exploration
Abstract

Phosphorus is an essential element in terrestrial organisms and thus characterizing the occurrences of phosphate phases at the martian surface is crucial in the assessment of habitability. The Alpha Particle X-Ray Spectrometers onboard Spirit, Opportunity and Curiosity discovered a variety of primary and secondary phosphate phases allowing direct comparisons across the three landing sites. The Spirit rover at Gusev Crater encountered the "Wishstone/Watchtower" class of P-rich (up to 5.2 wt% P2O5) rocks interpreted to be alkaline volcanic rocks with a physical admixture of approximately 10 to 20% merrillite [Usui et al 2008]. These rocks are characterized by elevated Ti and Y and anomalously low Cr and Ni, which could largely reflect the nature of the protoliths: Evolved magmatic rocks. Many of these chemical signatures are also found in pyroclastic deposits at nearby "Home Plate" and in phosphate precipitates derived from fluid interactions with these rocks ("Paso Robles" soils). The Opportunity rover at Meridiani Planum recently analyzed approximately 4 cm clast in a fine-grained matrix, one of numerous rocks of similar appearance at the rim of Endeavour Crater. This clast, "Sarcobatus," has minor enrichments in Ca and P relative to the matrix, and like the P-rich rocks at Gusev, Sarcobatus also shows elevated Al and Ti. On the same segment of the Endeavour rim, subsurface samples were found with exceptional levels of Mn (approximately 3.5 wt% MnO). These secondary and likely aqueous deposits contain strong evidence for associated Mg-sulfate and Ca-phosphate phases. Finally, the Curiosity traverse at Gale crater encountered P-rich rocks compositionally comparable to Wishstone at Gusev, including elevated Y. Phosphorous-rich rocks with similar chemical characteristics are prevalent on Mars, and the trace and minor element signatures provide constraints on whether these are primary deposits, secondary products of physical weathering or secondary products of chemical weathering.

Published
2014

45. Aqueous Alteration of Endeavour Crater Rim Apron Rocks

Author

Mittlefehldt, David W, Ming, Douglas W, Gellert, Ralf, Clark, Benton C, Morris, Richard V, Yen, Albert S, Arvidson, Raymond E, Crumpler, Larry S, Farrand, William H, Grant, John A, Jolliff, Bradley L, Parker, Timothy J, and Peretyazhko, Tanya

Subjects
Lunar And Planetary Science And Exploration
Abstract

Mars Exploration Rover Opportunity is exploring Noachian age rocks of the rim of 22 km diameter Endeavour crater. Overlying the pre-impact lithologies and rim breccias is a thin apron of fine-grained sediments, the Grasberg fm, forming annuli on the lower slopes of rim segments. Hesperian Burns fm sandstones overly the Grasberg fm. Grasberg rocks have major element compositions that are distinct from Burns fm sandstones, especially when comparing interior compositions exposed by the Rock Abrasion Tool. Grasberg rocks are also different from Endeavour rim breccias, but have general compositional similarities to them. Grasberg sediments are plausibly fine-grained materials derived from the impact breccias. Veins of CaSO4 transect Grasberg fm rocks demonstrating post-formation aqueous alteration. Minor/trace elements show variations consistent with mobilization by aqueous fluids. Grasberg fm rocks have low Mn and high Fe/Mn ratios compared to the other lithologies. Manganese likely was mobilized and removed from the Grasberg host rock by redox reactions. We posit that Fe2+ from acidic solutions associated with formation of the Burns sulfate-rich sandstones acted as an electron donor to reduce more oxidized Mn to Mn2+. The Fe contents of Grasberg rocks are slightly higher than in other rocks suggesting precipitation of Fe phases in Grasberg materials. Pancam spectra show that Grasberg rocks have a higher fraction of ferric oxide minerals than other Endeavour rim rocks. Solutions transported Mn2+ into the Endeavour rim materials and oxidized and/or precipitated it in them. Grasberg has higher contents of the mobile elements K, Zn, Cl, and Br compared to the rim materials. Similar enrichments of mobile elements were measured by the Spirit APXS on West Spur and around Home Plate in Gusev crater. Enhancements in these elements are attributed to interactions of hydrothermal acidic fluids with the host rocks. Interactions of fluids with the Grasberg fm postdate the genesis of the Endeavour rim phyllosilicates. The aqueous alteration history of Endeavour rim rocks is complicated by different styles of alteration that have spanned the Noachian and Hesperian. Late stage acidic aqueous alteration of Grasberg fm materials is likely penecontemporaneous with the diagenesis of the sulfate-rich sediments of Meridiani Planum.

Published
2014

46. Planning Considerations Related to Collecting and Analyzing Samples of the Martian Soils

Author

Liu, Yang, Mellon, Mike T, Ming, Douglas W, Morris, Richard V, Noble, Sarah K, Sullivan, Robert J, Taylor, Lawrence A, and Beaty, David W

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Mars Sample Return (MSR) End-to-End International Science Analysis Group (E2E-iSAG [1]) established scientific objectives associ-ated with Mars returned-sample science that require the return and investigation of one or more soil samples. Soil is defined here as loose, unconsolidated materials with no implication for the presence or absence of or-ganic components. The proposed Mars 2020 (M-2020) rover is likely to collect and cache soil in addition to rock samples [2], which could be followed by future sample retrieval and return missions. Here we discuss key scientific consid-erations for sampling and caching soil samples on the proposed M-2020 rover, as well as the state in which samples would need to be preserved when received by analysts on Earth. We are seeking feedback on these draft plans as input to mission requirement formulation. A related planning exercise on rocks is reported in an accompanying abstract [3].

Published
2014

47. Alteration of Basaltic Glass to Mg/Fe-Smectite under Acidic Conditions: A Potential Smectite Formation Mechanism on Mars

Author

Peretyazhko, Tanya, Sutter, Brad, and Ming, Douglas W

Subjects
Space Sciences (General)
Abstract

Phyllosilicates of the smectite group including Mg- and Fe-saponite and Fe(III)-rich nontronite have been identified on Mars. Smectites are believed to be formed under neutral to alkaline conditions that prevailed on early Mars. This hypothesis is supported by the observation of smectite and carbonate deposits in Noachian terrain on Mars. However, smectite may have formed under mildly acidic conditions. Abundant smectite formations have been detected as layered deposits hundreds of meters thick in intracrater depositional fans and plains sediments, while no large deposits of carbonates are found. Development of mildly acidic conditions at early Mars might allow formation of smectite but inhibit widespread carbonate precipitation. Little is known regarding the mechanisms of smectite formation from basaltic glass under acidic conditions. The objective of this study was to test a hypothesis that Mars-analogue basaltic glass alters to smectite minerals under acidic conditions (pH 4). The effects of Mg and Fe concentrations and temperature on smectite formation from basaltic glass were evaluated. Phyllosilicate synthesis was performed in batch reactors (Parr acid digestion vessel) under reducing hydrothermal conditions at 200 C and 100 C. Synthetic basaltic glass with a composition similar to that of the Gusev crater rock Adirondack (Ground surface APXS measurement) was used in these experiments. Basaltic glass was prepared by melting and quenching procedures. X-ray diffraction (XRD) analysis indicated that the synthesized glass was composed of olivine, magnetite and X-ray amorphous phase. Samples were prepared by mixing 250 mg Adirondack with 0.1 M acetic acid (final pH 4). In order to study influence of Mg concentration on smectite formation, experiments were performed with addition of 0, 1 and 10 mM MgCl2. After 1, 7 and 14 day incubations the solution composition was analyzed by Inductively Coupled Plasma Mass Spectrometry (ICP-MS) and the altered glass and formed phyllosilicates were examined by XRD analysis. Mineralogical changes were significant in Adirondack incubated with 10 mM MgCl2 at pH 4 and heated at 200 C. X-ray diffraction analysis revealed formation of phyllosilicate during 14 day incubation (Figure 1). Smectite was confirmed as the phyllosilicate after treatments with glycerol and KCl and heating to 550 C. The position of 02l (4.60 A) and 060 (1.54 A) diffraction bands were indicative of trioctahedral smectite such as saponite. Analysis of solution composition demonstrated that aqueous concentration of Mg decreased from 10 mM to approx.4 mM after 7 day incubation likely due to saponite formation. Smectite also formed in Adirondack incubated with 0 mM MgCl2 at pH 4 and heated at 200 C. However, diffraction peak positions of 02l (4.52 A) and 060 (1.51 A) suggested formation of dioctahedral nontronite. The 100degC Mg and Fe(II) treated basaltic glass experiments are ongoing and results will be presented.

Published
2014

48. A review of sample analysis at mars-evolved gas analysis laboratory analog work supporting the presence of perchlorates and chlorates in gale crater, mars

Author

Ministerio de Ciencia e Innovación (España), Clark, Joana, Sutter, Brad, Douglas Archer Jr, P., Ming, Douglas W., Rampe, Elizabeth, McAdam, Amy, Navarro-González, Rafael, Eigenbrode, Jennifer L., Glavin, Daniel P., Zorzano, María Paz, Martín-Torres, F. J., Morris, Richard V., Tu, Valerie, Ralston, S. J., Mahaffy, Paul, Ministerio de Ciencia e Innovación (España), Clark, Joana, Sutter, Brad, Douglas Archer Jr, P., Ming, Douglas W., Rampe, Elizabeth, McAdam, Amy, Navarro-González, Rafael, Eigenbrode, Jennifer L., Glavin, Daniel P., Zorzano, María Paz, Martín-Torres, F. J., Morris, Richard V., Tu, Valerie, Ralston, S. J., and Mahaffy, Paul

Abstract

The Sample Analysis at Mars (SAM) instrument on the Curiosity rover has detected evidence of oxychlorine compounds (i.e., perchlorates and chlorates) in Gale crater, which has implications for past habitability, diagenesis, aqueous processes, interpretation of in situ organic analyses, understanding the martian chlorine cycle, and hazards and resources for future human exploration. Pure oxychlorines and mixtures of oxychlorines with Mars-analog phases have been analyzed for their oxygen (O ) and hydrogen chloride (HCl) releases on SAM laboratory analog instruments in order to constrain which phases are present in Gale crater. These studies demonstrated that oxychlorines evolve O releases with peaks between ~200 and 600 C, although the thermal decomposition temperatures and the amount of evolved O decrease when iron phases are present in the sample. Mg and Fe oxychlorines decompose into oxides and release HCl between ~200 and 542 C. Ca, Na, and K oxychlorines thermally decompose into chlorides and do not evolve HCl by themselves. However, the chlorides (original or from oxychlorine decomposition) can react with water-evolving phases (e.g., phyllosilicates) in the sample and evolve HCl within the temperature range of SAM (<~870 C). These laboratory analog studies support that the SAM detection of oxychlorine phases is consistent with the presence of Mg, Ca, Na, and K perchlorate and/or chlorate along with possible contributions from adsorbed oxychlorines in Gale crater samples.

Published
2021

49. Indication of drier periods on Mars from the chemistry and mineralogy of atmospheric dust

Author

Goetz, Walter, Bertelsen, Preben, Binau, Charlotte S., Gunnlaugsson, Haraldur P., Hviid, Stubbe F., Kinch, Kjartan M., Madsen, Daniel E., Madsen, Morten B., Olsen, Malte, Gellert, Ralf, Klingelhofer, Gostar, Ming, Douglas W., Morris, Richard V., Rieder, Rudolf, Rodionov, Daniel S., de Souza, Jr, Paulo A., Schroder, Christian, Squyres, Steve W., Wdowiak, Tom, and Yen, Albert

Abstract

Author(s): Walter Goetz (corresponding author) [1]; Preben Bertelsen [2]; Charlotte S. Binau [2]; Haraldur P. Gunnlaugsson [3]; Stubbe F. Hviid [1]; Kjartan M. Kinch [3]; Daniel E. Madsen [2]; Morten [...]

Published
2005
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50. Water alteration of rocks and soils on Mars at the Spirit rover site in Gusev crater

Author

Haskin, Larry A., Wang, Alian, Jolliff, Bradley L., McSween, Harry Y., Clark, Benton C., Des Marais, David J., McLennan, Scott M., Tosca, Nicholas J., Hurowitz, Joel A., Farmer, Jack D., Yen, Albert, Squyres, Steve W., Arvidson, Raymond E., Klingelhofer, Gostar, Schroder, Christian, de Souza, Jr, Paulo A., Ming, Douglas W., Gellert, Ralf, Zipfel, Jutta, Bruckner, Johannes, Bell, III, James F., Herkenhoff, Kenneth, Christensen, Phil R., Ruff, Steve, Blaney, Diana, Gorevan, Steven, Cabrol, Nathalie A., Crumpler, Larry, Grant, John, and Soderblom, Lawrence

Abstract

Author(s): Larry A. Haskin [1, 18]; Alian Wang (corresponding author) [1]; Bradley L. Jolliff [1]; Harry Y. McSween [2]; Benton C. Clark [3]; David J. Des Marais [4]; Scott M. [...]

Published
2005
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