Your search keyword '"Franz, H. B."' showing total 151 results

1. Indigenous and exogenous organics and surface–atmosphere cycling inferred from carbon and oxygen isotopes at Gale crater

Author

Franz, H. B., Mahaffy, P. R., Webster, C. R., Flesch, G. J., Raaen, E., Freissinet, C., Atreya, S. K., House, C. H., McAdam, A. C., Knudson, C. A., Archer, Jr., P. D., Stern, J. C., Steele, A., Sutter, B., Eigenbrode, J. L., Glavin, D. P., Lewis, J. M. T., Malespin, C. A., Millan, M., Ming, D. W., Navarro-González, R., and Summons, R. E.

Published

2020

2. Detection of Siderite (FeCO3) in Glen Torridon Samples by the Mars Science Laboratory Rover

Author

Archer, P. D, Rampe, E. B, Clark, J. V, Tu, V, Sutter, B, Vaniman, D, Ming, D. W, Franz, H. B, McAdam, A. C, Bristow, T. F, Achilles, C. N, Chipera, S. J, Morrison, S. M, Thorpe, M. T, Marais, D. J. Des, Downs, R. T, Hazen, R. M, Morris, R. V, Treiman, A. H, Webster, C. R, and Yen, A. S

Subjects

Space Sciences (General)

Abstract

Siderite (FeCO3) has been detected in Gale Crater for the first time by the Mars Science Laboratory (MSL) Curiosity and is seen in multiple samples in the Glen Torridon (GT) region. The identification of siderite is based on evolved gas analysis (EGA) data from the Sample Analysis at Mars (SAM) instrument and X-ray diffraction (XRD) data from the Chemistry and Mineralogy (CheMin) instrument. Curiosity descended off of the Vera Rubin ridge (VRR) into the Glen Torridon region on Sol 2300. Glen Torridon is of particular interest because a strong clay mineral signature had been detected by orbital instruments [1]. To date, four drilled samples have been collected at two different drill locations: Kilmarie and Aberlady from adjacent blocks at the base of the south side of VRR in the Jura member and Glen Etive 1 and 2 on the same block in the Knockfarril member.

Published

2020

3. Mineralogical and Geochemical Trends of the Murray Mudstones, Gale Crater: A Combined Sample Analysis at Mars-Evolved Gas Analyzer and Chemistry and Mineralogy Instrument Assessment

Author

Sutter, B, McAdam, A. C, Rampe, E. B, Archer, P. D, Ming, D. W, Mahaffy, P. R, Navarro-Gonzalez, R, Stern, J. C, Eigenbrode, J. L, and Franz, H. B

Subjects

Geophysics, Lunar And Planetary Science And Exploration

Abstract

The Murray formation is predominantly composed of lacustrine mudstone that forms the basal layer of Aeolis Mons (informally Mt. Sharp) in Gale Crater, Mars. The Murray formation has distinct iron and sulfur mineralogical variation within its stratigraphy detectable by the Chemistry Mineralogy (Che-Min) instrument consisting of magnetite/hematite in the lower Murray and higher hematite, CaSO4, and smectite content in the upper Murray. The objectives of this work were to evaluate the Sample Analysis at Mars Evolved Gas Analyzer (SAM-EGA) data to 1) Determine what SAM-EGA-detectable phases correlate or do not correlate with the Murray mineralogical composition detected by CheMin and 2) Utilize CheMin/SAM results to propose possible formation scenarios for the observed Murray mudstone mineralogy.

Published

2019

4. Evolved Gas Analyses of Mudstones from the Vera Rubin Ridge

Author

McAdam, A. C, Sutter, B, Archer, P. D, Franz, H. B, Eigenbrode, J. L, Stern, J. C, Wong, G. M, Lewis, J.M.T, Knudson, C. A, Andrejkovicova, S, Hogancamp, J. V, Achilles, C. N, Ming, D. W, Morris, R. V, Rampe, E. B, Bristow, T. F, Navarro-Gonzalez, R, and Mahaffy, P. R

Subjects

Space Sciences (General)

Abstract

The Sample Analysis at Mars (SAM) instrument suite on the Mars Science Laboratory (MSL) rover has been essential in understanding volatile-bearing phases in Gale Crater materials. SAM’s evolved gas analysis mass spectrometry (EGA-MS) has detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, and other trace gases, including organic fragments, in many samples. The identity and evolution temperature of evolved gases can support CheMin instrument mineral detection and place constraints on trace volatile-bearing phases or phases difficult to characterize with X-ray diffraction (e.g., amorphous phases). For the past ~500 sols, MSL has been exploring the Vera Rubin Ridge (VRR), which exhibits a striking hematite signature in orbital remote sensing data, in order to understand the depositional and diagenetic history recorded in the rocks and how it relates to the underlying Murray Formation. Four rock samples were drilled, one from the Blunts Point Member (Duluth, DU), one from the Pettegrrove Point Member (Stoer, ST), and two from the Jura Member. The Jura Member displays differences in color, summarized as grey and red, and a key goal was to constrain the cause of this color difference and the associated implications for depositional or post-depositional conditions. To investigate, a grey (Highfield, HF) and a red (Rock Hall, RH) Jura sample were drilled. Here we will give an overview of results from SAM EGA-MS analyses of VRR materials, with some comparisons to analyses of samples of the underlying Murray.

Published

2019

5. The imprint of atmospheric evolution in the D/H of Hesperian clay minerals on Mars

Author

the MSL Science Team, Mahaffy, P. R., Webster, C. R., Stern, J. C., Brunner, A. E., Atreya, S. K., Conrad, P. G., Domagal-Goldman, S., Eigenbrode, J. L., Flesch, G. J., Christensen, L. E., Franz, H. B., Freissinet, C., Glavin, D. P., Grotzinger, J. P., Jones, J. H., Leshin, L. A., Malespin, C., McAdam, A. C., Ming, D. W., Navarro-Gonzalez, R., Niles, P. B., Owen, T., Pavlov, A. A., Steele, A., Trainer, M. G., Williford, K. H., and Wray, J. J.

Published

2015

6. Sedimentary Organics in Glen Torridon, Gale Crater, Mars: Results From the SAM Instrument Suite and Supporting Laboratory Analyses

Author

Millan, M., primary, Williams, A. J., additional, McAdam, A. C., additional, Eigenbrode, J. L., additional, Steele, A., additional, Freissinet, C., additional, Glavin, D. P., additional, Szopa, C., additional, Buch, A., additional, Summons, R. E., additional, Lewis, J. M. T., additional, Wong, G. M., additional, House, C. H., additional, Sutter, B., additional, McIntosh, O., additional, Bryk, A. B., additional, Franz, H. B., additional, Pozarycki, C., additional, Stern, J. C., additional, Navarro‐Gonzalez, R., additional, Archer, D. P., additional, Fox, V., additional, Bennett, K., additional, Teinturier, S., additional, Malespin, C., additional, Johnson, S. S., additional, and Mahaffy, P. R., additional

Published

2022

7. Constraining Alteration Processes Along the Siccar Point Group Unconformity, Gale Crater, Mars: Results From the Sample Analysis at Mars Instrument

Author

Sutter, B., primary, McAdam, A. C., additional, Wong, G. M., additional, Clark, J. V., additional, Archer, P. D., additional, Franz, H. B., additional, Gasda, P. J., additional, Ming, D. W., additional, Yen, A., additional, Lewis, J. M. T., additional, Schwenzer, S. P., additional, Turner, S. M. R., additional, Rampe, E. B., additional, Eigenbrode, J. L., additional, Stern, J. C., additional, Thompson, L. M., additional, Dehouck, E., additional, Bedford, C., additional, Banham, S., additional, Bryk, A. B., additional, O’Connell‐Cooper, C., additional, House, C. S., additional, Millan, M., additional, Freissinet, C., additional, Navarro‐Gonzalez, R., additional, Mahaffy, P. R., additional, and Malespin, C. A., additional

Published

2022

8. Volatile and Organic Compositions of Sedimentary Rocks in Yellowknife Bay, Gale Crater, Mars

Author

MSL Science Team, Ming, D. W., Archer, P. D., Glavin, D. P., Eigenbrode, J. L., Franz, H. B., Sutter, B., Brunner, A. E., Stern, J. C., Freissinet, C., McAdam, A. C., Mahaffy, P. R., Cabane, M., Coll, P., Campbell, J. L., Atreya, S. K., Niles, P. B., Bell, J. F., Bish, D. L., Brinckerhoff, W. B., Buch, A., Conrad, P. G., Des Marais, D. J., Ehlmann, B. L., Fairén, A. G., Farley, K., Flesch, G. J., Francois, P., Gellert, R., Grant, J. A., Grotzinger, J. P., Gupta, S., Herkenhoff, K. E., Hurowitz, J. A., Leshin, L. A., Lewis, K. W., McLennan, S. M., Miller, K. E., Moersch, J., Morris, R. V., Navarro-González, R., Pavlov, A. A., Perrett, G. M., Pradler, I., Squyres, S. W., Summons, R. E., Steele, A., Stolper, E. M., Sumner, D. Y., Szopa, C., Teinturier, S., Trainer, M. G., Treiman, A. H., Vaniman, D. T., Vasavada, A. R., Webster, C. R., Wray, J. J., and Yingst, R. A.

Published

2014

9. Evolved Gas Analyses of Sedimentary Rocks From the Glen Torridon Clay‐Bearing Unit, Gale Crater, Mars: Results From the Mars Science Laboratory Sample Analysis at Mars Instrument Suite

Author

McAdam, A. C., primary, Sutter, B., additional, Archer, P. D., additional, Franz, H. B., additional, Wong, G. M., additional, Lewis, J. M. T., additional, Clark, J. V., additional, Millan, M., additional, Williams, A. J., additional, Eigenbrode, J. L., additional, Knudson, C. A., additional, Freissinet, C., additional, Glavin, D. P., additional, Stern, J. C., additional, Navarro‐González, R., additional, Achilles, C. N., additional, Ming, D. W., additional, Morris, R. V., additional, Bristow, T. F., additional, Rampe, E. B., additional, Thorpe, M. T., additional, House, C. H., additional, Andrejkovičová, S., additional, Bryk, A. B., additional, Fox, V. K., additional, Johnson, S. S., additional, Mahaffy, P. R., additional, and Malespin, C. A., additional

Published

2022

10. Volatile, Isotope, and Organic Analysis of Martian Fines with the Mars Curiosity Rover

Author

Leshin, L. A., Mahaffy, P. R., Webster, C. R., Cabane, M., Coll, P., Conrad, P. G., Archer, P. D., Atreya, S. K., Brunner, A. E., Buch, A., Eigenbrode, J. L., Flesch, G. J., Franz, H. B., Freissinet, C., Glavin, D. P., McAdam, A. C., Miller, K. E., Ming, D. W., Morris, R. V., Navarro-González, R., Niles, P. B., Owen, T., Pepin, R. O., Squyres, S., Steele, A., Stern, J. C., Summons, R. E., Sumner, D. Y., Sutter, B., Szopa, C., Teinturier, S., Trainer, M. G., Wray, J. J., and Grotzinger, J. P.

Published

2013

11. Unexplained Oxygen Variability: New Results on Molecular Oxygen in the Lower Martian Atmosphere from Chemcam and Supercam Passive Sky Observations

Author

Mcconnochie, T., Trainer, Melissa G., Smith, M., Guzewich, S., Franz, H. B., Newman, C., Lo, D., Atreya, S., Moores, J., Sapers, H., Lemmon, Mark, Wolff, Michael, Montmessin, Franck, Knutsen, Elise Wright, Fouchet, Thierry, Bertrand, Tanguy, Gasnault, Olivier, Lasue, Jérémie, Forni, O., Pilleri, Paolo, Maurice, Sylvestre, Legett, Carey, Newell, Raymond, Venhaus, Dawn, Lanza, Nina, Wiens, R., Hecht, M., Zorzano, M.-P., Khayat, A., Lefèvre, Franck, Daerden, Frank, Fedorova, Anna, Trokhimovskiy, Alexander, Space Science Institute [Boulder] (SSI), NASA Goddard Space Flight Center (GSFC), Aeolis Research, University of Michigan [Ann Arbor], University of Michigan System, Centre for Research in Earth and Space Science [Toronto] (CRESS), York University [Toronto], PLANETO - LATMOS, Laboratoire Atmosphères, Milieux, Observations Spatiales (LATMOS), Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université de Versailles Saint-Quentin-en-Yvelines (UVSQ)-Institut national des sciences de l'Univers (INSU - CNRS)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Laboratoire d'études spatiales et d'instrumentation en astrophysique = Laboratory of Space Studies and Instrumentation in Astrophysics (LESIA), Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire de Paris, Université Paris sciences et lettres (PSL)-Université Paris sciences et lettres (PSL)-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS)-Université Paris Cité (UPCité), 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), Los Alamos National Laboratory (LANL), Purdue University [West Lafayette], MIT Haystack Observatory, Massachusetts Institute of Technology (MIT), Centro de Astrobiologia [Madrid] (CAB), Instituto Nacional de Técnica Aeroespacial (INTA)-Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Center for Research and Exploration in Space Science and Technology [GSFC] (CRESST), Belgian Institute for Space Aeronomy / Institut d'Aéronomie Spatiale de Belgique (BIRA-IASB), Space Research Institute of the Russian Academy of Sciences (IKI), and Russian Academy of Sciences [Moscow] (RAS)

Subjects

[SDU]Sciences of the Universe [physics]

Abstract

International audience

Published

2022

12. Large Sulphur Isotope Fractionations in Martian Sediments at Gale Crater

Author

Franz, H. B, McAdam, A. C, Ming, D. W, Freissinet, C, Mahaffy, Paul, Eldridge, D. L, Fischer, W. W, Grotzinger, J. P, House, C. H, Hurowitz, J. A, McLennan, S. M, Schwenzer, S. P, Vaniman, D. T, Archer, P. D. Jr, Atreya, S. K, Conrad, P. G, Dottin, J. W. III, Eigenbrode, J. L, Farley, K. A, Glavin, D. P, Johnson, S. S, Knudson, C. A, Morris, R. V, Navarro-Gonzalez, R, Pavlov, A. A, Plummer, R, Rampe, E. B, Stern, J. C, Steele, A, Summons, R. E, and Sutter, B

Subjects

Lunar And Planetary Science And Exploration

Abstract

Variability in the sulfur isotopic composition in sediments can reflect atmospheric, geologic and biological processes. Evidence for ancient fluvio-lacustrine environments at Gale crater on Mars and a lack of efficient crustal recycling mechanisms on the planet suggests a surface environment that was once warm enough to allow the presence of liquid water, at least for discrete periods of time, and implies a greenhouse effect that may have been influenced by sulfur-bearing volcanic gases. Here we report in situ analyses of the sulfur isotopic compositions of SO2 volatilized from ten sediment samples acquired by NASA's Curiosity rover along a 13 km traverse of Gale crater. We find large variations in sulfur isotopic composition that exceed those measured for Martian meteorites and show both depletion and enrichment in S-34. Measured values of δS-34 range from -47 +/- 14% to 28 +/- 7%, similar to the range typical of terrestrial environments. Although limited geochronological constraints on the stratigraphy traversed by Curiosity are available, we propose that the observed sulfur isotopic signatures at Gale crater can be explained by equilibrium fractionation between sulfate and sulfide in an impact-driven hydrothermal system and atmospheric processing of sulfur-bearing gases during transient warm periods.

Published

2017

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 from Yellowknife Bay to the Namib Dune

Author

Sutter, B, McAdam, A. C, Mahaffy, P. R, Ming, D. W, Edgett, K. S, Rampe, E. B, Eigenbrode, J. L, Franz, H. B, Freissinet, C, Grotzinger, J. P, Steele, A, House, C. H, Archer, P. D, Malespin, C. A, Navarro-González, R, Stern, J. C, Bell, J. F, Calef, F. J, Gellert, R, Glavin, D. P, Thompson, L. M, and Yen, A. S

Subjects

Lunar And Planetary Science And Exploration

Abstract

The sample analysis at Mars instrument evolved gas analyzer (SAM-EGA) has detected evolved water, H2, SO2, H2S, NO, CO2, CO, O2, and HCl from two eolian sediments and nine sedimentary rocks from Gale Crater, Mars. These evolved gas detections indicate nitrates, organics, oxychlorine phase, and sulfates are widespread with phyllosilicates and carbonates occurring in select Gale Crater materials. Coevolved CO2 (160 +/- 248-2373 +/- 820 μgC(CO2)/g) and CO (11 +/- 3-320 +/- 130 μgC(CO)/g) suggest that organic C is present in Gale Crater materials. Five samples evolved CO2 at temperatures consistent with carbonate (0.32 +/- 0.05-0.70 +/- 0.1 wt % CO3). Evolved NO amounts to 0.002 +/- 0.007-0.06 +/- 0.03 wt % NO3. Evolution of O2 suggests that oxychlorine phases (chlorate/perchlorate) (0.05 +/- 0.025-1.05 +/- 0.44 wt % ClO4) are present, while SO2 evolution indicates the presence of crystalline and/or poorly crystalline Fe and Mg sulfate and possibly sulfide. Evolved H2O (0.9 +/- 0.3-2.5 +/- 1.6 wt % H2O) is consistent with the presence of adsorbed water, hydrated salts, interlayer/structural water from phyllosilicates, and possible inclusion water in mineral/amorphous phases. Evolved H2 and H2S 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

2017

14. Bulk Hydrogen Content OF High-Silica Rocks in Gale Crater With the Active Dynamic Albedo of Neutrons Experiment

Author

Gabriel, T. S. J, Hardgrove, C, Litvak, M, Mitrofanov, I, Boynton, W. V, Fedosov, F, Golovin, D, Jun, I, Mischna, M, Tate, C. G, Moersch, J, Harshman, K, Kozyrev, A. S, Malakhov, A, Mokrousov, M, Nikiforov, S, Sanin, A. B, Vostrukhin, A, Archer, P. D., Jr, Franz, H. B, and Thompson, L

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Mars Science Laboratory (MSL) Curiosity rover recently traversed over plateaus of mafic aeolian sandstones (the 'Stimson' formation) that overlie mudstones (the 'Murray' formation). Within the Stimson formation we observed many lighter-toned, halo-forming features, that are potentially indicative of fluid alteration (see Fig. 1). These halo features extend for tens of meters laterally and are approx.1 meter wide. The halo features were characterized by Curiosity's geochemical instruments: Alpha Proton X-Ray Spectrometer (APXS), Chemin, Chemcam and Sample Analysis at Mars (SAM). With respect to the host (unaltered) Stimson rocks, fracture halos were significantly enriched in silicon and low in iron [1]. Changes in hydrogen abundance (due to its large neutron scattering cross section) greatly influence the magnitude of the thermal neutron response from the Dynamic Albedo of Neutrons (DAN) instrument [2]. There are also some elemental species, e.g. chlorine, iron, and nickel, that have significant microscopic neutron absorption cross sections. These elements can be abundant and variable results provide a useful estimate of the lower bound for bulk hydrogen content (assuming a homogeneous distribution).

Published

2017

15. Constraints on the Mineralogy of Gale Crater Mudstones from MSL SAM Evolved Water

Author

McAdam, A. C, Sutter, B, Franz, H. B, Hogancamp, J. V. (Clark), Knudson, C. A, Andrejkovicova, S, Archer, P. D, Eigenbrode, J. L, Ming, D. W, and Mahaffy, P. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) and Chemistry and Mineralogy (CheMin) instruments on the Mars Science Laboratory (MSL) have analysed more than 150 micron fines from 14 sites at Gale Crater. Here we focus on the mudstone samples. Two were drilled from sites John Klein (JK) and Cumberland (CB) in the Sheepbed mudstone. Six were drilled from Murray Formation mudstone: Confidence Hills (CH), Mojave (MJ), Telegraph Peak (TP), Buckskin (BK), Oudam (OU), Marimba (MB). SAM's evolved gas analysis mass spectrometry (EGA-MS) detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, and other trace gases, including organic fragments. The identity and evolution temperature of evolved gases can support CheMin mineral detection and place constraints on trace volatile-bearing phases or phases difficult to characterize with X-ray diffraction (e.g., amorphous phases). Here we will focus on SAM H2O data and comparisons to SAM-like analyses of key reference materials.

Published

2017

16. Aktuelle diagnostische Möglichkeiten bei geburtsbedingter analer Inkontinenz

Author

Franz, H. B. G., Stuhldreier, G., Müller-Schimpfle, M., Wiesner, A., Künzel, Wolfgang, editor, and Kirschbaum, Michael, editor

Published

1997

17. Gynäkologische Verletzungen, Versorgung / Trauma to the Vulva and Vagina

Author

Franz, H. B. G. and Hartel, W., editor

Published

2001

18. Volatile Analysis by Pyrolysis of Regolith (Vapor) for Planetary Resource Prospecting

Author

Glavin, D. P, Malespin, C. A, Ten Kate, I. L, Mcadam, A, Getty, S. A, Mumm, E, Franz, H. B, Southard, A. E, Bleacher, J. E, and Mahaffy, P. R

Subjects

Lunar And Planetary Science And Exploration, Exobiology

Abstract

Measuring the chemical composition of planetary bodies and their atmospheres is key to understanding the formation of the Solar System and the evolution of the planets and their moons. In situ volatile measurements enable a ground-truth assessment of the distribution and abundance of resources such as water-ice and oxygen, important for a sustained human presence on the Moon and beyond. The Volatile Analysis by Pyrolysis of Regolith (VAPoR) instrument is a compact pyrolysis mass spectrometer designed to detect volatiles released from solid samples that are heated to elevated temperatures and is one technique that should be considered for resource prospecting on the Moon, Mars, and asteroids.

Published

2016

19. In Situ Measurement of Atmospheric Krypton and Xenon on Mars with Mars Science Laboratory

Author

Conrad, P. G, Malespin, C. A, Franz, H. B, Pepin, R. O, Trainer, M. G, Schwenzer, S. P, Atreya, S. K, Freissinet, C, Jones, J. H, Manning, H, Owen, T, Pavlov, A. A, Wiens, R. C, Wong, M. H, and Mahaffy, P. R

Subjects

Solar Physics, Statistics And Probability, Inorganic, Organic And Physical Chemistry, Lunar And Planetary Science And Exploration

Abstract

Mars Science Laboratorys Sample Analysis at Mars (SAM) investigation has measured all of the stable isotopes of the heavy noble gases krypton and xenon in the martian atmosphere, in situ, from the Curiosity Rover at Gale Crater, Mars. Previous knowledge of martian atmospheric krypton and xenon isotope ratios has been based upon a combination of the Viking missions krypton and xenon detections and measurements of noble gas isotope ratios in martian meteorites. However, the meteorite measurements reveal an impure mixture of atmospheric, mantle, and spallation contributions. The xenon and krypton isotopic measurements reported here include the complete set of stable isotopes, unmeasured by Viking. The new results generally agree with Mars meteorite measurements but also provide a unique opportunity to identify various non-atmospheric heavy noble gas components in the meteorites. Kr isotopic measurements define a solar-like atmospheric composition, but deviating from the solar wind pattern at 80Kr and 82Kr in a manner consistent with contributions originating from neutron capture in Br. The Xe measurements suggest an intriguing possibility that isotopes lighter than 132Xe have been enriched to varying degrees by spallation and neutron capture products degassed to the atmosphere from the regolith, and a model is constructed to explore this possibility. Such a spallation component, however, is not apparent in atmospheric Xe trapped in the glassy phases of martian meteorites.

Published

2016

20. Reactions Involving Calcium and Magnesium Sulfates as Potential Sources of Sulfur Dioxide During MSL SAM Evolved Gas Analyses

Author

McAdam, A. C, Knudson, C. A, Sutter, B, Franz, H. B, Archer, P. D., Jr, Eigenbrode, J. L, Ming, D. W, Morris, R. V, Hurowitz, J. A, Mahaffy, P. R, and Navarro-Gonzalez, R

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) and Chemistry and Mineralogy (CheMin) instruments on the Mars Science Laboratory (MSL) have analyzed several subsamples of <150 micron fines from ten sites at Gale Crater. Three were in Yellowknife Bay: the Rocknest aeolian bedform (RN) and drilled Sheepbed mudstone from sites John Klein (JK) and Cumberland (CB). One was drilled from the Windjana (WJ) site on a sandstone of the Kimberly formation. Four were drilled from sites Confidence Hills (CH), Mojave (MJ), Telegraph Peak (TP) and Buckskin (BK) of the Murray Formation at the base of Mt. Sharp. Two were drilled from sandstones of the Stimson formation targeting relatively unaltered (Big Sky, BY) and then altered (Greenhorn, GH) material associated with a light colored fracture zone. CheMin analyses provided quantitative sample mineralogy. SAM's evolved gas analysis mass spectrometry (EGA-MS) detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, and other trace gases. This contribution will focus on evolved SO2. All samples evolved SO2 above 500 C. The shapes of the SO2 evolution traces with temperature vary between samples but most have at least two "peaks' within the wide high temperature evolution, from approx. 500-700 and approx. 700-860 C (Fig. 1). In many cases, the only sulfur minerals detected with CheMin were Ca sulfates (e.g., RN and GH), which should thermally decompose at temperatures above those obtainable by SAM (>860 C). Sulfides or Fe sulfates were detected by CheMin (e.g., CB, MJ, BK) and could contribute to the high temperature SO2 evolution, but in most cases they are not present in enough abundance to account for all of the SO2. This additional SO2 could be largely associated with x-ray amorphous material, which comprises a significant portion of all samples. It can also be attributed to trace S phases present below the CheMin detection limit, or to reactions which lower the temperatures of SO2 evolution from sulfates that are typically expected to thermally decompose at temperatures outside the SAM temperature range (e.g., Ca and Mg sulfates). Here we discuss the results of SAM-like laboratory analyses targeted at understanding this last possibility, focused on understanding if reactions of HCl or an HCl evolving phase (oxychlorine phases, chlorides, etc.) and Ca and Mg sulfates can result in SO2 evolution in the SAM temperature range.

Published

2016

21. First Detection of Non-Chlorinated Organic Molecules Indigenous to a Martian Sample

Author

Freissinet, C, Glavin, D. P, Buch, A, Szopa, C, Summons, R. E, Eigenbrode, J. L, Archer, P. D., Jr, Brinckerhoff, W. B, Brunner, A. E, Cabane, M, Franz, H. B, Kashyap, S, Malespin, C. A, Martin, M, Millan, M, Miller, K, Navarro-González, R, Prats, B. D, Steele, A, Teinturier, S, and Mahaffy, P. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument onboard Curiosity can perform pyrolysis of martian solid samples, and analyze the volatiles by direct mass spectrometry in evolved gas analysis (EGA) mode, or separate the components in the GCMS mode (coupling the gas chromatograph and the mass spectrometer instruments). In addition, SAM has a wet chemistry laboratory designed for the extraction and identification of complex and refractory organic molecules in the solid samples. The chemical derivatization agent used, N-methyl-N-tert-butyldimethylsilyl- trifluoroacetamide (MTBSTFA), was sealed inside seven Inconel metal cups present in SAM. Although none of these foil-capped derivatization cups have been punctured on Mars for a full wet chemistry experiment, an MTBSTFA leak was detected and the resultant MTBSTFA vapor inside the instrument has been used for a multi-sol MTBSTFA derivatization (MD) procedure instead of direct exposure to MTBSTFA liquid by dropping a solid sample directly into a punctured wet chemistry cup. Pyr-EGA, Pyr-GCMS and Der-GCMS experiments each led to the detection and identification of a variety of organic molecules in diverse formations of Gale Crater.

Published

2016

22. Modeling of Sulfide Microenvironments on Mars

Author

Schwenzer, S. P, Bridges, J. C, McAdam, A, Steer, E. D, Conrad, P. G, Kelley, S. P, Wiens, R. C, Mangold, N, Grotzinger, J, Eigenbrode, J. L, Franz, H. B, and Sutter, B

Subjects

Lunar And Planetary Science And Exploration

Abstract

Yellowknife Bay (YKB; sol 124-198) is the second site that the Mars Science Laboratory Rover Curiosity investigated in detail on its mission in Gale Crater. YKB represents lake bed sediments from an overall neutral pH, low salinity environment, with a mineralogical composition which includes Ca-sulfates, Fe oxide/hydroxides, Fe-sulfides, amorphous material, and trioctahedral phyllosilicates. We investigate whether sulfide alteration could be associated with ancient habitable microenvironments in the Gale mudstones. Some textural evidence for such alteration may be pre-sent in the nodules present in the mudstone.

Published

2016

23. MARS ATMOSPHERE: The imprint of atmospheric evolution in the D/H of Hesperian clay minerals on Mars

Author

Mahaffy, P. R., Webster, C. R., Stern, J. C., Brunner, A. E., Atreya, S. K., Conrad, P. G., Domagal-Goldman, S., Eigenbrode, J. L., Flesch, G. J., Christensen, L. E., Franz, H. B., Freissinet, C., Glavin, D. P., Grotzinger, J. P., Jones, J. H., Leshin, L. A., Malespin, C., McAdam, A. C., Ming, D. W., Navarro-Gonzalez, R., Niles, P. B., Owen, T., Pavlov, A. A., Steele, A., Trainer, M. G., Williford, K. H., and Wray, J. J.

Published

2015

24. Iron-Rich Carbonates as the Potential Source of Evolved CO2 Detected by the Sample Analysis at Mars (SAM) Instrument in Gale Crater

Author

Sutter, B, Heil, E, Rampe, E. B, Morris, R. V, Ming, D. W, Archer, P. D, Eigenbrode, J. L, Franz, H. B, Glavin, D. P, McAdam, A. C, Navarro-Gonzalez, R, Niles, P. B, Mahaffy, P. R, Stern, J. C, and Mertzman, S

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument detected at least 4 distinct CO2 release during the pyrolysis of a sample scooped from the Rocknest (RN) eolian deposit. The highest peak CO2 release temperature (478-502 C) has been attributed to either a Fe-rich carbonate or nano-phase Mg-carbonate. The objective of this experimental study was to evaluate the thermal evolved gas analysis (T/EGA) characteristics of a series of terrestrial Fe-rich carbonates under analog SAM operating conditions to compare with the RN CO2 releases. Natural Fe-rich carbonates (<53 microns) with varying Fe amounts (Fe(0.66)X(0.34)- to Fe(0.99)X(0.01)-CO3, where X refers to Mg and/or Mn) were selected for T/EGA. The carbonates were heated from 25 to 715 C (35 C/min) and evolved CO2 was measured as a function of temperature. The highest Fe containing carbonates (e.g., Fe(0.99)X(0.01)-CO3) yielded CO2 peak temperatures between 466-487 C, which is consistent with the high temperature RN CO2 release. The lower Fe-bearing carbonates (e.g., Fe(0.66)X(0.34)CO3) did not have peak CO2 release temperatures that matched the RN peak CO2 temperatures; however, their entire CO2 releases did occur within RN temperature range of the high temperature CO2 release. Results from this laboratory analog analysis demonstrate that the high temperature RN CO2 release is consistent with Fe-rich carbonate (approx.0.7 to 1 wt.% FeCO3). The similar RN geochemistry with other materials in Gale Crater and elsewhere on Mars (e.g., Gusev Crater, Meridiani) suggests that up to 1 wt. % Fe-rich carbonate may occur throughout the Gale Crater region and could be widespread on Mars. The Rocknest Fe-carbonate may have formed from the interaction of reduced Fe phases (e.g., Fe2+ bearing olivine) with atmospheric CO2 and transient water. Alternatively, the Rocknest Fe-carbonate could be derived by eolian processes that have eroded distally exposed deep crustal material that possesses Fe-carbonate that may have formed through metamorphic and/or metasomatic processes.

Published

2015

25. Isotopic Composition of Carbon Dioxide Released from Confidence Hills Sediment as Measured by the Sample Analysis at Mars (SAM) Quadrupole Mass Spectrometer

Author

Franz, H. B, Mahaffy, P. R, Stern, J, Archer, P., Jr, Conrad, P, Eigenbrode, J, Freissinet, C, Glavin, D, Grotzinger, J. P, Jones, J, Ming, D, McAdam, A, Morris, R, Navarro-Gozalez, R, Owen, T, Steele, A, Summons, R, Sutter, B, and Webster, C. R

Subjects

Geophysics

Abstract

In October 2014, the Mars Science Laboratory (MSL) "Curiosity" rover drilled into the sediment at the base of Mount Sharp in a location namsed Cionfidence Hills (CH). CH marked the fifth sample pocessed by the Sample Analysis at Mars (SAM) instrument suite since Curiosity arrived in Gale Crater, with previous analyses performed at Rocknest (RN), John Klein (JK), Cumberland (CB), and Windjana (WJ). Evolved gas analysis (EGA) of all samples has indicated H2O as well as O-, C- and S-bearing phases in the samples, often at abundances that would be below the detection limit of the CheMin instrument. By examining the temperatures at which gases are evolved from samples, SAM EGA data can help provide clues to the mineralogy of volatile-bearing phases when their identities are unclear to CheMin. SAM may also detect gases evolved from amorphous material in solid samples, which is not suitable for analysis by CheMin. Finally, the isotopic composition of these gases may suggest possible formation scenarios and relationships between phases. We will discuss C isotope ratios of CO2 evolved from the CH sample as measured with SAM's quadrupole mass spectrometer (QMS) and draw comparisons to samples previously analyzed by SAM.

Published

2015

26. Correlations Between Surficial Sulfur and a REE Crustal Assimilation Signature in Martian Shergottites

Author

Jones, J. H and Franz, H. B

Subjects

Lunar And Planetary Science And Exploration

Abstract

Compared to terrestrial basalts, the Martian shergottite meteorites have an extraordinary range of Sr and Nd isotopic signatures. In addition, the S isotopic compositions of many shergottites show evidence of interaction with the Martian surface/ atmosphere through mass-independent isotopic fractionations (MIF, positive, non-zero delta(exp 33)S) that must have originated in the Martian atmosphere, yet ultimately were incorporated into igneous sulfides (AVS - acid-volatile sulfur). These positive delta(exp 33)S signatures are thought to be governed by solar UV photochemical processes. And to the extent that S is bound to Mars and not lost to space from the upper atmosphere, a positive delta(exp 33)S reservoir must be mass balanced by a complementary negative reservoir.

Published

2015

27. Major Volatiles from MSL SAM Evolved Gas Analyses: Yellowknife Bay Through Lower Mount Sharp

Author

McAdam, A. C, Archer, P. D., Jr, Sutter, B, Franz, H. B, Eigenbrode, J. L, Ming, D. W, Morris, R. V, Niles, P. B, Stern, J. C, Freissinet, C, Glavin, D. P, Atreya, S. K, Bish, D. L, Blake, D. F, Mahaffy, P. R, Navarro-Gonzalez, R, McKay, C. P, and Wilhelm, M. B

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) and Chemistry and Mineralogy (CheMin) instruments on the Mars Science Laboratory (MSL) analysed several subsamples of <150 μm fines from five sites at Gale Crater. Three were in Yellowknife Bay: the Rocknest aeolian bedform ("RN") and drilled Sheepbed mudstone from sites John Klein ("JK") and Cumberland ("CB"). One was drilled from the Windjana ("WJ") site on a sandstone of the Kimberly formation investigated on route to Mount Sharp. Another was drilled from the Confidence Hills ("CH") site on a sandstone of the Murray Formation at the base of Mt. Sharp (Pahrump Hills). Outcrops are sedimentary rocks that are largely of fluvial or lacustrine origin, with minor aeolian deposits.. SAM's evolved gas analysis (EGA) mass spectrometry detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, and other trace gases, including organic fragments. The identity and evolution temperature (T) of evolved gases can support CheMin mineral detection and place constraints on trace volatile-bearing phases or phases difficult to characterize with XRD (e.g., X-ray amorphous phases). They can also give constraints on sample organic chemistry. Here, we discuss trends in major evolved volatiles from SAM EGA analyses to date.

Published

2015

28. Volatile and Organic Compositions of Sedimentary Rocks in Yellowknife Bay, Gale Crater, Mars

Author

Ming, D. W., Archer, P. D., Jr., Glavin, D. P., Eigenbrode, J. L., Franz, H. B., Sutter, B., Brunner, A. E., Stern, J. C., Freissinet, C., McAdam, A. C., Mahaffy, P. R., Cabane, M., Coll, P., Campbell, J. L., Atreya, S. K., Niles, P. B., Bell, J. F., III, Bish, D. L., Brinckerhoff, W. B., Buch, A., Conrad, P. G., Des Marais, D. J., Ehlmann, B. L., Fairén, A. G., Farley, K., Flesch, G. J., Francois, P., Gellert, R., Grant, J. A., Grotzinger, J. P., Gupta, S., Herkenhoff, K. E., Hurowitz, J. A., Leshin, L. A., Lewis, K. W., McLennan, S. M., Miller, K. E., Moersch, J., Morris, R. V., Navarro-González, R., Pavlov, A. A., Perrett, G. M., Pradler, I., Squyres, S. W., Summons, R. E., Steele, A., Stolper, E. M., Sumner, D. Y., Szopa, C., Teinturier, S., Trainer, M. G., Treiman, A. H., Vaniman, D. T., Vasavada, A. R., Webster, C. R., Wray, J. J., and Yingst, R. A.

Published

2014

29. Pyrolysis of Oxalate, Acetate, and Perchlorate Mixtures and the Implications for Organic Salts on Mars

Author

Lewis, J. M. T., primary, Eigenbrode, J. L., additional, Wong, G. M., additional, McAdam, A. C., additional, Archer, P. D., additional, Sutter, B., additional, Millan, M., additional, Williams, R. H., additional, Guzman, M., additional, Das, A., additional, Rampe, E. B., additional, Achilles, C. N., additional, Franz, H. B., additional, Andrejkovičová, S., additional, Knudson, C. A., additional, and Mahaffy, P. R., additional

Published

2021

30. The Imprint of Atmospheric Evolution in the D/H of Hesperian Clay Minerals on Mars

Author

Mahaffy, P. R, Webster, C. R, Stern, J. C, Brunner, A. E, Atreya, S. K, Conrad, P. G, Domagal-Goldman, S, Eigenbrode, J. L, Flesch, G. J, Christensen, L. E, Franz, H. B, Glavin, D. P, Jones, J. H, McAdam, A. C, Pavlov, A. A, Trainer, M. G, and Williford, K. H

Subjects

Lunar And Planetary Science And Exploration

Abstract

The deuterium-to-hydrogen (D/H) ratio in strongly bound water or hydroxyl groups in ancient Martian clays retains the imprint of the water of formation of these minerals. Curiosity's Sample Analysis at Mars (SAM) experiment measured thermally evolved water and hydrogen gas released between 550 degrees Centigrade and 950 degrees Centigrade from samples of Hesperian-era Gale crater smectite to determine this isotope ratio. The D/H value is 3.0 (plus or minus 0.2) times the ratio in standard mean ocean water. The D/H ratio in this approximately 3-billion-year-old mudstone, which is half that of the present Martian atmosphere but substantially higher than that expected in very early Mars, indicates an extended history of hydrogen escape and desiccation of the planet.

Published

2014

31. Reduced and Oxidized Sulfur Compounds Detected by Evolved Gas Analyses of Materials from Yellowknife Bay, Gale Crater, Mars

Author

McAdam, A. C, Franz, H. B, Archer, P. D., Jr, Sutter, B, Eigenbrode, J. L, Freissinet, C, Atreya, S. K, Bish, D. L, Blake, D. F, Brunner, A, Mahaffy, P. R, Ming, D. W, Morris, R. V, Navarro-Gonzalez, R, Rampe, E. B, Steele, A, and Wray, J. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

Sulfate minerals have been directly detected or strongly inferred from several Mars datasets and indicate that aqueous alteration of martian surface materials has occurred. Indications of reduced sulfur phases (e.g., sulfides) from orbital and in situ investigations of martian materials have been fewer in number, but these phases are observed in martian meteorites and are likely because they are common minor phases in basaltic rocks. Here we discuss potential sources for the S-bearing compounds detected by the Mars Science Laboratory (MSL) Sample Analysis at Mars (SAM) instrument’s evolved gas analysis (EGA) experiments.

Published

2014

32. Searching for Reduced Carbon on the Surface of Mars: The SAM Combustion Experiment

Author

Stern, J. C, Malespin, C. A, Mahaffy, P. R, Webster, C. R, Eigenbrode, J. L, Archer, P. D., Jr, Brunner, A. E, Freissinet, C, Franz, H. B, Glavin, D. P, Graham, H. V, McAdam, A. C, Ming, D. W, Navarro-Gonzalez, R, Niles, P. B, Steele, A, Sutter, B, and Trainer, M. G

Subjects

Lunar And Planetary Science And Exploration

Abstract

The search for reduced carbon has been a major focus of past and present missions to Mars. Thermal evolved gas analysis was used by the Viking and Phoenix landers and is currently in use by the Sample Analysis at Mars (SAM) instrument suite on the Mars Science Laboratory (MSL) to characterize volatiles evolved from solid samples, including those associated with reduced organic species. SAM has the additional capability to perform a combustion experiment, in which a sample of Mars regolith is heated in the presence of oxygen and the composition of the evolved gases is measured using quadrupole mass spectrometry (QMS) and tunable laser spectrometry (TLS) [1]. Organics detection on the Martian surface has been complicated by oxidation and destruction during heating by soil oxidants [2], including oxychlorine compounds, and terrestrial organics in the SAM background contributed by one of the SAM wet chemistry reagents MTBSTFA (N-Methyl-N-tertbutyldimethylsilyl- trifluoroacetamide) [3,4]. Thermal Evolved Gas Analysis (TEGA) results from Phoenix show a mid temperature CO2 release between 400 C - 680 C speculated to be carbonate, CO2 adsorbed to grains, or combustion of organics by soil oxidants [5]. Low temperature CO2 evolutions (approx. 200 C - 400 C) were also present at all three sites in Gale Crater where SAM Evolved Gas Analysis (EGA) was performed, and potential sources include combustion of terrestrial organics from SAM, as well as combustion and/or decarboxylation either indigenous martian or exogenous organic carbon [4,6]. By performing an experiment to intentionally combust all reduced materials in the sample, we hope to compare the bulk abundance of CO2 and other oxidized species evolved by combustion to that evolved during an EGA experiment to estimate how much CO2 could be contributed by reduced carbon sources. In addition, C, O, and H isotopic compositions of CO2 and H2O measured by TLS can contribute information regarding the potential sources of these volatiles.

Published

2014

33. The Investigation of Magnesium Perchlorate/Iron Phase-mineral Mixtures as a Possible Source of Oxygen and Chlorine Detected by the Sample Analysis at Mars (SAM) Instrument in Gale Crater, Mars

Author

Sutter, B, Heil, E, Archer, P. D, Ming, D. W, Eigenbrode, J. L, Franz, H. B, Glavin, D. P, McAdam, A. C, Mahaffy, P. R, Niles, P. B, Stern, J. C, Navarro-Gonzalez, R, and McKay, C. P

Subjects

Space Sciences (General)

Abstract

The Sample Analysis at Mars (SAM) instrument onboard the Curiosity rover detect-ed O2 and HCl gas releases from the Rocknest (RN) eolian bedform and the John Klein (JK) and Cumber-land (CB) drill hole materials in Gale Crater (Fig. 1) [1,2]. Chlorinated hydrocarbons have also been detect-ed by the SAM quadrupole mass spectrometer (QMS) and gas chromatography/mass spectrometer (GCMS) [1,2,3,4]. These detections along with the detection of perchlorate (ClO4(-)) by the Mars Phoenix Lander's Wet Chemistry Laboratory (WCL) [5] suggesting perchlo-rate is a possible candidate for evolved O2 and chlorine species. Laboratory thermal analysis of individual per-chlorates has yet to provide an unequivocal tempera-ture match to the SAM O2 and HCl release data [1,2]. Catalytic reactions of Fe phases in the Gale Crater ma-terial with perchlorates can potentially reduce the de-composition temperatures of these otherwise pure per-chlorate/chlorate phases [e.g., 6,7]. Iron mineralogy found in the Rocknest materials when mixed with Ca-perchlorate was found to cause O2 release temperatures to be closer match to the SAM O2 release data and enhance HCl gas releases. Exact matches to the SAM data has unfortnunately not been achieved with Ca-perchlorate-Fe-phase mixtures [8]. The effects of Fe-phases on magnesium perchlorate thermal decomposi-tion release of O2 and HCl have not been evaluated and may provide improved matches to the SAM O2 and HCl release data. This work will evaluate the thermal decomposition of magnesium perchlorate mixed with fayalite/magnetite phase and a Mauna Kea palagonite (HWMK 919). The objectives are to 1) summarize O2 and HCl releases from the Gale Crater materials, and 2) evaluate the O2 and HCl releases from the Mg-perchlorate + Fe phase mixtures to determine if Mg-perchlorate mixed with Fe-phases can explain the Gale Crater O2 and HCl releases.

Published

2014

34. The Combustion Experiment on the Sample Analysis at Mars (SAM) Instrument Suite on the Curiosity Rover

Author

Stern, J. C, Malespin, C. A, Eigenbrode, J. L, Graham, H. V, Archer, P. D., Jr, Brunner, A. E, Freissinet, C, Franz, H. B, Fuentes, J, Glavin, D. P, Leshin, L. A, Mahaffy, P. R, McAdam, A. C, Ming, D. W, Navvaro-Gonzales, R, Niles, P. B, and Steele, A

Subjects

Lunar And Planetary Science And Exploration

Abstract

The combustion experiment on the Sample Analysis at Mars (SAM) suite on Curiosity will heat a sample of Mars regolith in the presence of oxygen and measure composition of the evolved gases using quadrupole mass spectrometry (QMS) and tunable laser spectrometry (TLS). QMS will enable detection of combustion products such as CO, CO2, NO, and other oxidized species, while TLS will enable precise measurements of the abundance and carbon isotopic composition (delta(sup 13)C) of the evolved CO2 and hydrogen isotopic composition (deltaD) of H2O. SAM will perform a two-step combustion to isolate combustible materials below approx.550 C and above approx.550 C. The combustion experiment on SAM, if properly designed and executed, has the potential to answer multiple questions regarding the origins of volatiles seen thus far in SAM evolved gas analysis (EGA) on Mars. Constraints imposed by SAM and MSL time and power resources, as well as SAM consumables (oxygen gas), will limit the number of SAM combustion experiments, so it is imperative to design an experiment targeting the most pressing science questions. Low temperature combustion experiments will primarily target the quantification of carbon (and nitrogen) contributed by SAM wet chemistry reagants MTBSTFA (N-Methyl-N-tert-butyldimethylsilyltrifluoroacetamide) and DMF (Dimethylformamide), which have been identified in the background of blank and sample runs and may adsorb to the sample while the cup is in the Sample Manipulation System (SMS). In addition, differences between the sample and "blank" may yield information regarding abundance and delta(sup 13)C of bulk (both organic and inorganic) martian carbon. High temperature combustion experiments primarily aim to detect refractory organic matter, if present in Cumberland fines, as well as address the question of quantification and deltaD value of water evolution associated with hydroxyl hydrogen in clay minerals.

Published

2014

35. Detection of Nitric Oxide by the Sample Analysis at Mars (SAM) Instrument Implications for the Presence of Nitrates

Author

Navarro-Gonzalez, R, Stern, J, Freissinet, C, Franz, H. B, Eigenbrode, J. L, McKay, C. P, Coll, P, Sutter, B, Archer, D, McAdam, A, Cabane, M, Ming, D. W, Glavin, D, Leshin, L, Wong, M, Atreya, S, Wray, J. J, Steele, A, Buch, A, Prats, B. D, Szopa, C, Coscia, D, Teinturier, S, Conrad, P, Owen, T. C, Mahaffy, P, and Grotzinger, J. P

Subjects

Lunar And Planetary Science And Exploration

Abstract

One of the main goals of the Mars Science Laboratory is to determine whether the planet ever had environmental conditions able to support microbial life. Nitrogen is a fundamental element for life, and is present in structural (e.g., proteins), catalytic (e.g., enzymes and ribozymes), energy transfer (e.g., ATP) and information storage (RNA and DNA) biomolecules. Planetary models suggest that molecular nitrogen was abundant in the early Martian atmosphere, but was rapidly lost to space by photochemistry, sputtering impact erosion, and oxidized and deposited to the surface as nitrate. Nitrates are a fundamental source for nitrogen to terrestrial microorganisms. Therefore, the detection of nitrates in soils and rocks is important to assess the habitability of a Martian environment. SAM is capable of detecting nitrates by their thermal decomposition into nitric oxide, NO. Here we analyze the release of NO from soils and rocks examined by the SAM instrument at Gale crater, and discuss its origin.

Published

2014

36. SAM-Like Evolved Gas Analyses of Phyllosilicate Minerals and Applications to SAM Analyses of the Sheepbed Mudstone, Gale Crater, Mars

Author

McAdam, A. C, Franz, H. B, Mahaffy, P. R, Eigenbrode, J. L, Stern, J. C, Brunner, B, Sutter, B, Archer, P. D, Ming , D. W, Morris, R. V, Bish, D. L, and Atreya, S. K

Subjects

Lunar And Planetary Science And Exploration

Abstract

While in Yellowknife Bay, the Mars Science Laboratory Curiosity rover collected two drilled samples, John Klein (hereafter "JK") and Cumberland ("CB"), from the Sheepbed mudstone, as well as a scooped sample from the Rocknest aeolian bedform ("RN"). These samples were sieved by Curiosity's sample processing system and then several subsamples of these materials were delivered to the Sample Analysis at Mars (SAM) instrument suite and the CheMin X-ray diffraction/X-ray fluorescence instrument. CheMin provided the first in situ X-ray diffraction-based evidence of clay minerals on Mars, which are likely trioctahedral smectites (e.g., Fe-saponite) and comprise ~20 wt% of the mudstone samples [1]. SAM's evolved gas analysis (EGA) mass spectrometry analyses of JK and CB subsamples, as well as RN subsamples, detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, OCS, CS2 and other trace gases evolved during pyrolysis. The identity of evolved gases and temperature( s) of evolution can augment mineral detection by CheMin and place constraints on trace volatile-bearing phases present below the CheMin detection limit or those phases difficult to characterize with XRD (e.g., X-ray amorphous phases). Here we will focus on the SAM H2O data, in the context of CheMin analyses, and comparisons to laboratory SAM-like analyses of several phyllosilicate minerals including smectites.

Published

2014

37. Carbon and Sulfur Isotopic Composition of Yellowknife Bay Sediments: Measurements by the Sample Analysis at Mars (SAM) Quadrupole Mass Spectrometer

Author

Franz, H. B, Mahaffy, P. R, Stern, J. C, Eigenbrode, J. L, Steele, A, Ming, D. W, McAdam, A. C, Freissinet, C, Glavin, D. P, Archer, P. D, Brunner, A. E, Grotzinger,J. P, Jones, J. H, Leshin, L. A, Miller, K, Morris, R. V, Navarro-Gonzalez, R, Niles, P. B, Owen, T. C, Summons, R. E, Sutter, B, and Webster, C. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

Since landing at Gale Crater in Au-gust 2012, the Sample Analysis at Mars (SAM) instru-ment suite on the Mars Science Laboratory (MSL) “Curiosity” rover has analyzed solid samples from the martian regolith in three locations, beginning with a scoop of aeolian deposits from the Rocknest (RN) sand shadow. Curiosity subsequently traveled to Yellowknife Bay, where SAM analyzed samples from two separate holes drilled into the Sheepbed Mudstone, designated John Klein (JK) and Cumberland (CB). Evolved gas analysis (EGA) of all samples revealed the presence of H2O as well as O-, C- and S-bearing phas-es, in most cases at abundances below the detection limit of the CheMin instrument. In the absence of definitive mineralogical identification by CheMin, SAM EGA data can help provide clues to the mineralogy of volatile-bearing phases through examination of tem-peratures at which gases are evolved from solid sam-ples. In addition, the isotopic composition of these gas-es may be used to identify possible formation scenarios and relationships between phases. Here we report C and S isotope ratios for CO2 and SO2 evolved from the JK and CB mudstone samples as measured with SAM’s quadrupole mass spectrometer (QMS) and draw com-parisons to RN.

Published

2014

38. Detection and Quantification of Nitrogen Compounds in the First Drilled Martian Solid Samples by the Sample Analysis at Mars (SAM) Instrument Suite on the Mars Science Laboratory (MSL)

Author

Stern, J. C, Navarro-Gonzales, R, Freissinet, C, McKay, C. P, Archer, P. D., Jr, Buch, A, Brunner, A. E, Coll, P, Eigenbrode, J. L, Franz, H. B, Glavin, D. P, McAdam, A. C, Ming, D, Steele, A, Sutter, B, Szopa, C, Wray, J. J, Conrad, P, and Mahaffy, P. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument suite on the Mars Science Laboratory (MSL) Curiosity Rover detected both reduced and oxidized nitrogen-bearing compounds during the pyrolysis of surface materials at Yellowknife Bay in Gale Crater. Preliminary detections of nitrogen species include NO, HCN, ClCN, CH3CN, and TFMA (trifluoro-N-methyl-acetamide). Confirmation of indigenous Martian N-bearing compounds requires quantifying N contribution from the terrestrial derivatization reagents (e.g. N-methyl-N-tertbutyldimethylsilyltrifluoroacetamide, MTBSTFA and dimethylformamide, DMF) carried for SAM's wet chemistry experiment that contribute to the SAM background. Nitrogen species detected in the SAM solid sample analyses can also be produced during laboratory pyrolysis experiments where these reagents are heated in the presence of perchlorate, a compound that has also been identified by SAM in Mars solid samples.

Published

2014

39. Sulphur-bearing Compounds Detected by MSL SAM Evolved Gas Analysis of Materials from Yellowknife Bay, Gale Crater, Mars

Author

McAdam, A. C, Franz, H. B, Archer, P. D. Jr, Sutter, B, Eigenbrode, J. L, Freissinet, C, Atreya, S. K, Bish, D. L, Blake, D. F, Brunner, A, Mahaffy, P. R, Ming, D. W, Morris, R. V, Navarro-Gonzalez, R, Rampe, E. B, Steele, A, and Wray, J. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) and Chemistry and Mineralogy (CheMin) instruments on the Mars Science Laboratory (MSL) analysed several subsamples of sample fines (<150 μm) from three sites in Yellowknife Bay, an aeolian bedform termed Rocknest (hereafter "RN") and two samples drilled from the Sheepbed mudstone at sites named John Klein ("JK") and Cumberland ("CB"). SAM's evolved gas analysis (EGA) mass spectrometry detected H2O, CO2, O2, H2, SO2, H2S, HCl, NO, OCS, CS2 and other trace gases. The identity of evolved gases and temperature (T) of evolution can support mineral detection by CheMin and place constraints on trace volatile-bearing phases present below the CheMin detection limit or difficult to characterize with XRD (e.g., X-ray amorphous phases). Here, we focus on potential constraints on phases that evolved SO2, H2S, OCS, and CS2 during thermal analysis.

Published

2014

40. Organic Molecules in the Sheepbed Mudstone, Gale Crater, Mars

Author

Freissinet, C, Glavin, D. P, Mahaffy, P. R, Miller, K. E, Eigenbrode, J. L, Summons, R. E, Brunner, A. E, Buch, A, Szopa, C, Archer, P. D, Franz, H. B, and Steele, A

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument on the Curiosity rover is designed to determine the inventory of organic and inorganic volatiles thermally released from solid samples using a combination of evolved gas analysis (EGA), gas chromatography mass spectrometry (GCMS), and tunable laser spectroscopy. Here we report on various chlorinated hydrocarbons (chloromethanes, chlorobenzene and dichloroalkanes) detected at elevated levels above instrument background at the Cumberland (CB) drill site, and discuss their possible sources.

Published

2014

41. Proktologie für den Gynäkologen

Author

Franz, H. B. G.

Published

2005

42. Formation of Tridymite and Evidence for a Hydrothermal History at Gale Crater, Mars

Author

Yen, A. S., primary, Morris, R. V., additional, Ming, D. W., additional, Schwenzer, S. P., additional, Sutter, B., additional, Vaniman, D. T., additional, Treiman, A. H., additional, Gellert, R., additional, Achilles, C. N., additional, Berger, J. A., additional, Blake, D. F., additional, Boyd, N. I., additional, Bristow, T. F., additional, Chipera, S., additional, Clark, B. C., additional, Craig, P. I., additional, Downs, R. T., additional, Franz, H. B., additional, Gabriel, T., additional, McAdam, A. C., additional, Morrison, S. M., additional, O’Connell‐Cooper, C. D., additional, Rampe, E. B., additional, Schmidt, M. E., additional, Thompson, L. M., additional, and VanBommel, S. J., additional

Published

2021

43. Possible Detection of Nitrates on Mars by the Sample Analysis at Mars (SAM) Instrument

Author

Navarro-Gonzalez, R, Stern, J, Sutter, B, Archer, D, McAdam, A, Franz, H. B, McKay, C. P, Coll, P, Cabane, M, Ming, D. W, Brunner, A. E, Glavin, D, Eigenbrode, J. L, Jones, J. H, Freissinet, C, Leshin, L, Wong, M, Atreya, S, Wray, J. J, Steele, A, Buch, A, Prats, B. D, Szopa, C, Conrad, P, and Mahaffy, P

Subjects

Geophysics

Abstract

Planetary models suggest that nitrogen was abundant in the early Martian atmosphere as dinitrogen (N2). However, it has been lost by sputtering and photochemical loss to space [1, 2], impact erosion [3], and chemical oxidation to nitrates [4]. Nitrates, produced early in Mars history, are later decomposed back into N2 by the current impact flux [5], making possible a nitrogen cycle on Mars. It is estimated that a layer of about 3 m of pure NaNO3 should be distributed globally on Mars [5]. Nitrates are a fundamental source for nitrogen to terrestrial microorganisms. Therefore, the detection of soil nitrates is important to assess habitability in the Martian environment. The only previous mission that was designed to search for soil nitrates was the Phoenix mission but was unable to detect evolved N-containing species by TEGA and the MECA WCL [6]. Nitrates have been tentatively identified in the Nakhla meteorite [7]. The purpose of this work is to determine if nitrates were detected in first solid sample (Rocknest) in Gale Crater examined by the SAM instrument.

Published

2013

44. Detection of Reduced Nitrogen Compounds at Rocknest Using the Sample Analysis At Mars (SAM) Instrument on the Mars Science Laboratory (MSL)

Author

Stern, J. C, Steele, A, Brunner, A, Coll, P, Eigenbrode, J, Franz, H. B, Freissinet, C, Glavin, D, Jones, J. H, Navarro-Gonzalez, R, Mahaffy, P. R, McAdam, A. C, McKay, C, and Wray, J

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument suite on the Mars Science Laboratory (MSL) Curiosity Rover detected nitrogen-bearing compounds during the pyrolysis of Rocknest material at Gale Crater. Hydrogen cyanide and acetonitrile were identified by the quadrupole mass spectrometer (QMS) both in direct evolved gas analysis (EGA). SAM carried out four separate analyses from Rocknest Scoop 5. A significant low temperature release was present in Rocknest runs 1-4, while a smaller high temperature release was also seen in Rocknest runs 1-3. Here we evaluate whether these compounds are indigenous to Mars or a pyrolysis product resulting from known terrestrial materials that are part of the SAM derivatization.

Published

2013

45. The Search for Ammonia in Martian Soils with Curiosity's SAM Instrument

Author

Wray, James J, Archer, P. D, Brinckerhoff, W. B, Eigenbrode, J. L, Franz, H. B, Freissinet, C, Glavin, D. P, Mahaffy, P. R, McKay, C. P, Navarro-Gonzalez, R, Steele, A, and Webster, C. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

Nitrogen is the second or third most abundant constituent of the Martian atmosphere [1,2]. It is a bioessential element, a component of all amino acids and nucleic acids that make up proteins, DNA and RNA, so assessing its availability is a key part of Curiosity's mission to characterize Martian habitability. In oxidizing desert environments it is found in nitrate salts that co-occur with perchlorates [e.g., 3], inferred to be widespread in Mars soils [4-6]. A Mars nitrogen cycle has been proposed [7], yet prior missions have not constrained the state of surface N. Here we explore Curiosity's ability to detect N compounds using data from the rover's first solid sample. Companion abstracts describe evidence for nitrates [8] and for nitriles (C(triple bond)N) [9]; we focus here on nonnitrile, reduced-N compounds as inferred from bonded N-H. The simplest such compound is ammonia (NH3), found in many carbonaceous chondrite meteorites in NH4(+) salts and organic compounds [e.g., 10].

Published

2013

46. Carbon Isotopic Composition of CO2 Evolved During Perchlorate-Induced Reactions in Mars Analog Materials: Interpreting SAM/MSL Rocknest Data

Author

Stern, J. C, McAdam, A. C, Archer, P. D. Jr, Bower, H, Buch, A, Eigenbrode, J, Freissinet, C, Franz, H. B, Glavin, D, Jones, J. H, Mahaffy, P. R, Ming, D. W, Niles, P. B, Steele, A, and Sutter, B

Subjects

Lunar And Planetary Science And Exploration

Published

2013

47. Curiosity's Sample Analysis at Mars (SAM) Investigation: Overview of Results from the First 120 Sols on Mars

Author

Mahaffy, P. R, Cabane, M, Webster, C. R, Archer, P. D, Atreya, S. K, Benna, M, Brinckerhoff, W. B, Brunner, A. E, Buch, A, Coll, P, Conrad, P. G, Coscia, D, Dobson, N, Dworkin, J. P, Eigenbrode, J. L, Farley, K. A, Flesch, G, Franz, H. B, Freissinet, C, Gorevan, S, Glavin, D. P, Grotzinger, J. P, Harpold, D. N, Hengemihle, J, and Jaeger, F

Subjects

Space Sciences (General)

Abstract

During the first 120 sols of Curiosity s landed mission on Mars (8/6/2012 to 12/7/2012) SAM sampled the atmosphere 9 times and an eolian bedform named Rocknest 4 times. The atmospheric experiments utilized SAM s quadrupole mass spectrometer (QMS) and tunable laser spectrometer (TLS) while the solid sample experiments also utilized the gas chromatograph (GC). Although a number of core experiments were pre-programmed and stored in EEProm, a high level SAM scripting language enabled the team to optimize experiments based on prior runs.

Published

2013

48. Possible Detection of Perchlorates by Evolved Gas Analysis of Rocknest Soils: Global Implication

Author

Archer, P. D., Jr, Sutter, B, Ming, D. W, McKay, C. P, Navarro-Gonzalez, R, Franz, H. B, McAdam, A, and Mahaffy, P. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Sample Analysis at Mars (SAM) instrument suite on board the Mars Science Laboratory (MSL) recently ran four samples from an aeolian bedform named Rocknest. Rocknest was selected as the source of the first samples analyzed because it is representative of both windblown material in Gale crater as well as the globally-distributed dust. The four samples analyzed by SAM were portioned from the fifth scoop at this location. The material delivered to SAM passed through a 150 m sieve and should have been well mixed during the sample acquisition/ preparation/handoff process. Rocknest samples were heated to ~835 C at a 35 C/minute ramp rate with a He carrier gas flow rate of ~1.5 standard cubic centimeters per minute and at an oven pressure of ~30 mbar. Evolved gases were detected by a quadrupole mass spectrometer (QMS).

Published

2013

49. Carbon and Sulfur Isotopic Composition of Rocknest Soil as Determined with the Sample Analysis at Mars(SAM) Quadrupole Mass Spectrometer

Author

Franz, H. B, McAdam, C, Stern, J. C, Archer, P. D., Jr, Sutter, B, Grotzinger, J. P, Jones, J. H, Leshin, L. A, Mahaffy, P. R, Ming, D. W, Morris, R. V, Niles, P. B, Owen, T. C, Raaen, E, Steele, A, and Webster, C. R

Subjects

Geophysics

Abstract

The Sample Analysis at Mars (SAM) instrument suite on the Mars Science Laboratory (MSL) Curiosity rover got its first taste of solid Mars in the form of loose, unconsolidated materials (soil) acquired from an aeolian bedform designated Rocknest. Evolved gas analysis (EGA) revealed the presence of H2O as well as O-, C- and S-bearing phases in these samples. CheMin did not detect crystalline phases containing these gaseous species but did detect the presence of X-ray amorphous materials. In the absence of definitive mineralogical identification by CheMin, SAM EGA data can provide clues to the nature and/or mineralogy of volatile-bearing phases through examination of temperatures at which gases are evolved from solid samples. In addition, the isotopic composition of these gases, particularly when multiple sources contribute to a given EGA curve, may be used to identify possible formation scenarios and relationships between phases. Here we report C and S isotope ratios for CO2 and SO2 evolved from Rocknest soil samples as measured with SAM's quadrupole mass spectrometer (QMS).

Published

2013

50. Hydrogen Isotopic Composition of Water in the Martian Atmosphere and Released from Rocknest Fines

Author

Leshin, L. A, Webster, C. R, Mahaffy, P. R, Flesh, G. J, Christensen, L. E, Stern, J. C, Franz, H. B, McAdam, A. C, Niles, P. B, Archer, P. B., Jr, Sutter, B, Jones, J. H, Ming, D. W, Atreya, S. K, Owen, T. C, and Conrad, P

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Mars Science Laboratory Curiosity rover sampled the aeolian bedform called Rocknest as its first solid samples to be analyzed by the analytical instruments CheMin and SAM. The instruments ingested aliquots from a sieved sample of less than 150 micrometer grains. As discussed in other reports at this conference [e.g., 1], CheMin discovered many crystalline phases, almost all of which are igneous minerals, plus some 10s of percent of x-ray amorphous material. The SAM instrument is focused on understanding volatiles and possible organics in the fines, performing evolved gas analysis (EGA) with the SAM quadrapole mass spectrometer (QMS), isotope measurements using both the QMS and the tunable laser spectrometer (TLS), which is sensitive to CO2, water and methane, and organics with the gas chromatograph mass spectrometer (GCMS). As discussed in the abstract by Franz et al. [2] and others, EGA of Rocknest fines revealed the presence of significant amounts of H2O as well as O-, C- and S-bearing materials. SAM has also tasted the martian atmosphere several times, analyzing the volatiles in both the TLS and QMS [e.g., 3,4]. This abstract will focus on presentation of initial hydrogen isotopic data from the TLS for Rocknest soils and the atmosphere, and their interpretation. Data for CO2 isotopes and O isotopes in water are still being reduced, but should be available by at the conference.

Published

2013