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2. Mineralogy, provenance, and diagenesis of a potassic basaltic sandstone on Mars: CheMin X-ray diffraction of the Windjana sample (Kimberley area, Gale Crater).

Author

Treiman, Allan H, Bish, David L, Vaniman, David T, Chipera, Steve J, Blake, David F, Ming, Doug W, Morris, Richard V, Bristow, Thomas F, Morrison, Shaunna M, Baker, Michael B, Rampe, Elizabeth B, Downs, Robert T, Filiberto, Justin, Glazner, Allen F, Gellert, Ralf, Thompson, Lucy M, Schmidt, Mariek E, Le Deit, Laetitia, Wiens, Roger C, McAdam, Amy C, Achilles, Cherie N, Edgett, Kenneth S, Farmer, Jack D, Fendrich, Kim V, Grotzinger, John P, Gupta, Sanjeev, Morookian, John Michael, Newcombe, Megan E, Rice, Melissa S, Spray, John G, Stolper, Edward M, Sumner, Dawn Y, Vasavada, Ashwin R, and Yen, Albert S

Subjects
CheMin, MSL, Mars, Windjana, X‐ray diffraction, sandstone, X-ray diffraction, Astronomical and Space Sciences, Geochemistry, Geology
Abstract

The Windjana drill sample, a sandstone of the Dillinger member (Kimberley formation, Gale Crater, Mars), was analyzed by CheMin X-ray diffraction (XRD) in the MSL Curiosity rover. From Rietveld refinements of its XRD pattern, Windjana contains the following: sanidine (21% weight, ~Or95); augite (20%); magnetite (12%); pigeonite; olivine; plagioclase; amorphous and smectitic material (~25%); and percent levels of others including ilmenite, fluorapatite, and bassanite. From mass balance on the Alpha Proton X-ray Spectrometer (APXS) chemical analysis, the amorphous material is Fe rich with nearly no other cations-like ferrihydrite. The Windjana sample shows little alteration and was likely cemented by its magnetite and ferrihydrite. From ChemCam Laser-Induced Breakdown Spectrometer (LIBS) chemical analyses, Windjana is representative of the Dillinger and Mount Remarkable members of the Kimberley formation. LIBS data suggest that the Kimberley sediments include at least three chemical components. The most K-rich targets have 5.6% K2O, ~1.8 times that of Windjana, implying a sediment component with >40% sanidine, e.g., a trachyte. A second component is rich in mafic minerals, with little feldspar (like a shergottite). A third component is richer in plagioclase and in Na2O, and is likely to be basaltic. The K-rich sediment component is consistent with APXS and ChemCam observations of K-rich rocks elsewhere in Gale Crater. The source of this sediment component was likely volcanic. The presence of sediment from many igneous sources, in concert with Curiosity's identifications of other igneous materials (e.g., mugearite), implies that the northern rim of Gale Crater exposes a diverse igneous complex, at least as diverse as that found in similar-age terranes on Earth.

Published
2016

3. The origin and implications of clay minerals from Yellowknife Bay, Gale crater, Mars

Author

Bristow, Thomas F, Bish, David L, Vaniman, David T, Morris, Richard V, Blake, David F, Grotzinger, John P, Rampe, Elizabeth B, Crisp, Joy A, Achilles, Cherie N, Ming, Doug W, Ehlmann, Bethany L, King, Penelope L, Bridges, John C, Eigenbrode, Jennifer L, Sumner, Dawn Y, Chipera, Steve J, Moorokian, John Michael, Treiman, Allan H, Morrison, Shaunna M, Downs, Robert T, Farmer, Jack D, Marais, David Des, Sarrazin, Philippe, Floyd, Melissa M, Mischna, Michael A, and McAdam, Amy C

Subjects
Earth Sciences, Geochemistry, Geology, Mars, Yellowknife Bay, clay minerals, CheMin, XRD, habitability, Resources Engineering and Extractive Metallurgy, Geochemistry & Geophysics
Abstract

The Mars Science Laboratory (MSL) rover Curiosity has documented a section of fluvio-lacustrine strata at Yellowknife Bay (YKB), an embayment on the floor of Gale crater, approximately 500 m east of the Bradbury landing site. X-ray diffraction (XRD) data and evolved gas analysis (EGA) data from the CheMin and SAM instruments show that two powdered mudstone samples (named John Klein and Cumberland) drilled from the Sheepbed member of this succession contain up to ~20 wt% clay minerals. A trioctahedral smectite, likely a ferrian saponite, is the only clay mineral phase detected in these samples. Smectites of the two samples exhibit different 001 spacing under the low partial pressures of H2O inside the CheMin instrument (relative humidity

Published
2015

4. Report of the workshop for life detection in samples from Mars

Author

Kminek, Gerhard, Conley, Catherine, Allen, Carlton C, Bartlett, Douglas H, Beaty, David W, Benning, Liane G, Bhartia, Rohit, Boston, Penelope J, Duchaine, Caroline, Farmer, Jack D, Flynn, George J, Glavin, Daniel P, Gorby, Yuri, Hallsworth, John E, Mogul, Rakesh, Moser, Duane, Price, P Buford, Pukall, Ruediger, Fernandez-Remolar, David, Smith, Caroline L, Stedman, Ken, Steele, Andrew, Stepanauskas, Ramunas, Sun, Henry, Vago, Jorge L, Voytek, Mary A, Weiss, Paul S, and Westall, Frances

Subjects
Life-detection, Extraterrestrial life, Mars sample return, Planetary protection
Abstract

The question of whether there is or was life on Mars has been one of the most pivotal since Schiaparellis' telescopic observations of the red planet. With the advent of the space age, this question can be addressed directly by exploring the surface of Mars and by bringing samples to Earth for analysis. The latter, however, is not free of problems. Life can be found virtually everywhere on Earth. Hence the potential for contaminating the Mars samples and compromising their scientific integrity is not negligible. Conversely, if life is present in samples from Mars, this may represent a potential source of extraterrestrial biological contamination for Earth. A range of measures and policies, collectively termed 'planetary protection', are employed to minimise risks and thereby prevent undesirable consequences for the terrestrial biosphere. This report documents discussions and conclusions from a workshop held in 2012, which followed a public conference focused on current capabilities for performing life-detection studies on Mars samples. The workshop focused on the evaluation of Mars samples that would maximise scientific productivity and inform decision making in the context of planetary protection. Workshop participants developed a strong consensus that the same measurements could be employed to effectively inform both science and planetary protection, when applied in the context of two competing hypotheses: 1) that there is no detectable life in the samples; or 2) that there is martian life in the samples. Participants then outlined a sequence for sample processing and defined analytical methods that would test these hypotheses. They also identified critical developments to enable the analysis of samples from Mars. © 2014 The Committee on Space Research (COSPAR).

Published
2014

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

10. List of Contributors

Author

Allwood, Abigail C., primary, Arvidson, Raymond E., additional, Baglioni, Pietro, additional, Beaty, David, additional, Beegle, Luther W., additional, Berger, Jeff A., additional, Bhartia, Rohit, additional, Bibring, Jean-Pierre, additional, Bishop, Janice L., additional, Brack, André, additional, Brinckerhoff, William, additional, Brown, Adrian J., additional, Cabrol, Nathalie A., additional, Cady, Sherry L., additional, Catalano, Jeffrey G., additional, Ciarletti, Valérie, additional, Coates, Andrew J., additional, Davila, Alfonso, additional, De Sanctis, M. Cristina, additional, Elphic, Richard C., additional, Farley, Kenneth A., additional, Farmer, Jack D., additional, Flannery, David T., additional, Goesmann, Fred, additional, Grin, Edmond A., additional, Gulick, Virginia G., additional, Häder, Donat-Peter, additional, Hamilton, David, additional, Hamran, Svein-Erik, additional, Hecht, Michael H., additional, Hinman, Nancy W., additional, Hurowitz, Joel A., additional, Jaumann, Ralf, additional, Josset, Jean-Luc, additional, de la Torre Juarez, Manuel, additional, Kminek, Gerhard, additional, Korablev, Oleg, additional, Maurice, Sylvestre, additional, McEwen, Alfred S., additional, McKay, Christopher, additional, Milkovich, Sarah, additional, Mitrofanov, Igor, additional, Moersch, Jeffrey, additional, Noffke, Nora, additional, Phillips, Cynthia, additional, Quinn, Richard, additional, Raulin, François, additional, Rodionov, Daniel, additional, Rodriguez-Manfredi, Jose A., additional, Rull, Fernando, additional, Sefton-Nash, Elliot, additional, Skok, John R., additional, Sobron, Pablo, additional, Stack, Kathryn M., additional, Summers, David, additional, Summons, Roger E., additional, Svedhem, Håkan, additional, Teodoro, Luis, additional, Vago, Jorge L., additional, Walter, Malcolm R., additional, Warren-Rhodes, Kimberley, additional, Westall, Frances, additional, Wettergreen, David S., additional, Wiens, Roger C., additional, Williford, Kenneth H., additional, Winter, Diane, additional, and Zippi, Pierre, additional

Published
2018
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16. On the Past, Present, and Future Role of Biology in NASA’s Exploration of our Solar System

Author

Hand, Kevin, primary, Phillips, Cynthia B., additional, Chyba, Christopher F., additional, Toner, Brandy, additional, Katija, Kakani, additional, Orphan, Victoria, additional, Huber, Julie, additional, Cavanaugh, Colleen M., additional, Carlson, Marian, additional, Christner, Brent, additional, Templeton, Alexis, additional, Seewald, Jeffrey, additional, Hofgartner, Jason D., additional, Amend, Jan P., additional, Orcutt, Beth N., additional, Bartlett, Douglas H., additional, Falkowski, Paul, additional, Anderson, Rika, additional, Spear, John R., additional, Shank, Tim, additional, Fischer, Woodward W., additional, Hazen, Robert M., additional, Hoehler, Tori, additional, D'Hondt, Steven, additional, Pitesky, Jo, additional, Lynch, Kennda, additional, Shock, Everett L., additional, Craft, Kate, additional, Boyd, Eric, additional, House, Christopher H., additional, Reysenbach, Anna-Louise, additional, Glass, Jennifer, additional, Fike, David, additional, Baross, John A., additional, Gogarten, Johann Peter, additional, Kaçar, Betül, additional, El-Naggar, Moh, additional, Murray, Alison E., additional, Dupont, Christopher, additional, Scully, Jennifer, additional, Rothschild, Lynn, additional, Trembath-Reichert, Elizabeth, additional, Klein, Frieder, additional, Cohen, Phoebe A., additional, Gile, Gillian H., additional, Lloyd, Karen, additional, Dekas, Anne, additional, Delaney, John R., additional, Skidmore, Mark, additional, Buongiorno, Joy, additional, Rogers, Karyn, additional, Hofmann, Amy, additional, Brazelton, William J., additional, Anbar, Ariel, additional, Manalang, Dana Ann, additional, Stevenson, Bradley, additional, Neuer, Susanne, additional, Hara, Ellie, additional, Nordheim, Thomas, additional, Shapiro, Russell, additional, Bradley, Alexander S., additional, Mikucki, Jill, additional, Brown, Michael E., additional, Glamoclija, Mihaela, additional, Reyes, Carolina, additional, Sánchez-Román, Mónica, additional, Farmer, Jack D., additional, Giovannelli, Donato, additional, Suel, Gurol, additional, Trumbo, Samantha, additional, Cameron, Marissa, additional, Osburn, Magdalena, additional, Bradley, James Andrew, additional, Garcia-Pichel, Ferran, additional, Steen, Andrew D., additional, Marlow, Jeffrey, additional, Trubl, Gareth, additional, Robinson, Kirtland, additional, Caro, Tristan, additional, Fulfer, Victoria, additional, Parker, Ceth W., additional, Feyhl-Buska, Jayme, additional, and Roussel, Anaïs, additional

Published
2021
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18. 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

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
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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21. The First X-ray Diffraction Patterns of Clay Minerals from Gale Crater

Author

Bristow, Thomas, Blake, David, Bish, David L, Vaniman, David, Ming, Douglas W, Morris, Richard V, Chipera, Steve, Rampe, Elizabeth B, Farmer, Jack, D, Treiman, Allan H, Downs, Robert, Morrison, Shaunna, Achilles, Cherie, DesMarais, David J, Crisp, Joy A, Sarrazin, Philippe, Morookian, John Michael, and Grotzinger. John P

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Mars Science Laboratory (MSL) Rover, Curiosity spent approx 150 sols at Yellowknife Bay (YKB) studying a section of fluvio-lacustrine sedimentary rocks (with potential indications of volcanic influence), informally known as the Yellowknife Bay formation. YKB lies in a distal region of the Peace Vallis alluvial fan, which extends from the northern rim of Gale Crater toward the dune field at the base of Mt Sharp. Sedimentological and stratigraphic observations are consistent with the Yellowknife Bay formation being part of a distal fan deposit, which could be as young as middle Hesperian to even early Amazonian in age (approx 3.5 to 2.5 Ga). The Yellowknife Bay formation hosts a unit of mudstone called the Sheepbed member. Curiosity obtained powdered rock samples from two drill holes in the Sheepbed Member, named John Klein and Cumberland, and delivered them to instruments in Curiosity. Data from CheMin, a combined X-ray diffraction (XRD)/X-ray fluorescence instrument (XRF), has allowed detailed mineralogical analysis of mudstone powders revealing a clay mineral component of approx 20 wt.% in each sample. The clay minerals are important indicators of paleoenvironmental conditions and sensitive recorders of post-depositional alteration processes. The XRD pattern of John Klein reveals a 021 band consistent with a trioctahedral phyllosilicate. A broad peak at approx 10A with a slight inflexion at approx 12A indicates the presence of 2:1 type clay minerals in the John Klein sample. The trioctahedral nature of the clay minerals, breadth of the basal reflection, and presence of a minor component with larger basal spacing suggests that John Klein contains a trioctahedral smectite (probably saponite), whose interlayer is largely collapsed because of the low-humidity conditions. The XRD patterns show no evidence of corrensite (mixed-layer chlorite/smectite) or chlorite, which are typical diagenetic products of trioctahedral smectites when subjected to burial and heating >60degC in the presence of water. Given estimated geothermal gradients on Mars temperatures <60 degC might still be consistent with (but do not require) moderate burial. However, our ability to identify interstratified minerals is greatly limited by the lack of access to traditional treatments methods used in the lab (e.g., ethylene glycol solvation). Our preferred explanation for the origin of trioctahedral smectites in Sheepbed mudstone is in situ production via reaction of olivine, water and Si-bearing amorphous material, an important mudstone component detected by XRD. Elevated levels of magnetite in the Sheepbed and the trioctahedral monomineralic nature of the clay minerals support this model. These observations, combined with previous studies of olivine stability, support the persistence of circum-neutral hydrous conditions for thousands of years at YKB.

Published
2013

22. Characterizing the Phyllosilicates and Amorphous Phases Found by MSL Using Laboratory XRD and EGA Measurements of Natural and Synthetic Materials

Author

Rampe, Elizabeth B, Morris, Richard V, Chipera, Steve, Bish, David L, Bristow, Thomas, Archer, Paul Douglas, Blake, David, Achilles, Cherie, Ming, Douglas W, Vaniman, David, Crisp, Joy A, DesMarais, David J, Downs, Robert, Farmer, Jack D, Morookian, John Michael, Morrison, Shaunna, Sarrazin, Philippe, Spanovich, Nicole, Treiman, Allan H, and Yen, Albert S

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Curiosity Rover landed on the Peace Vallis alluvial fan in Gale crater on August 5, 2012. A primary mission science objective is to search for past habitable environments, and, in particular, to assess the role of past water. Identifying the minerals and mineraloids that result from aqueous alteration at Gale crater is essential for understanding past aqueous processes at the MSL landing site and hence for interpreting the site's potential habitability. X-ray diffraction (XRD) data from the CheMin instrument and evolved gas analyses (EGA) from the SAM instrument have helped the MSL science team identify phases that resulted from aqueous processes: phyllosilicates and amorphous phases were measure in two drill samples (John Klein and Cumberland) obtained from the Sheepbed Member, Yellowknife Bay Fm., which is believed to represent a fluvial-lacustrine environment. A third set of analyses was obtained from scoop samples from the Rocknest sand shadow. Chemical data from the APXS instrument have helped constrain the chemical compositions of these secondary phases and suggest that the phyllosilicate component is Mg-enriched and the amorphous component is Fe-enriched, relatively Si-poor, and S- and H-bearing. To refine the phyllosilicate and amorphous components in the samples measured by MSL, we measured XRD and EGA data for a variety of relevant natural terrestrial phyllosilicates and synthetic mineraloids in laboratory testbeds of the CheMin and SAM instruments. Specifically, Mg-saturated smectites and vermiculites were measured with XRD at low relative humidity to understand the behavior of the 001 reflections under Mars-like conditions. Our laboratory XRD measurements suggest that interlayer cation composition affects the hydration state of swelling clays at low RH and, thus, the 001 peak positions. XRD patterns of synthetic amorphous materials, including allophane, ferrihydrite, and hisingerite were used in full-pattern fitting (FULLPAT) models to help determine the types and abundances of amorphous phases in the martian rocks and sand shadow. These models suggest that the rocks and sand shadow are composed of approx 30% amorphous phases. Sulfate-adsorbed allophane and ferrihydrite were measured by EGA to further understand the speciation of the sulfur present in the amorphous component. These data indicate that sulfate adsorbed onto the surfaces of amorphous phases could explain a portion of the SO2 evolution in the Rocknest SAM data. The additional constraints placed on the mineralogy and chemistry of the aqueous alteration phases through our laboratory measurements can help us better understand the nature of the fluids that affected the different samples and devise a history of aqueous alteration for the Sheepbed Member of the Yellowknife Bay Fm. at Gale crater.

Published
2013

23. The Mineralogical and Chemical Case for Habitability at Yellowknife Bay, Gale Crater, Mars

Author

Blake, David Frederick, Vaniman, David, Grotzinger, John P, Conrad, Pamela Gales, Ming, Douglas W, Bish, David L, Farmer, Jack D, and Bristow, Thomas

Subjects
Exobiology, Lunar And Planetary Science And Exploration
Abstract

Sediments of the Yellowknife Bay formation (Gale crater) include the Sheepbed member, a mudstone cut by light-toned veins. Two drill samples, John Klein and Cumberland, were collected and analyzed by the CheMin XRD/XRF instrument and the Sample Analysis at Mars (SAM) evolved gas and isotopic analysis suite of instruments. Drill cuttings were also analyzed by the Alpha Particle X-ray Spectrometer (APXS) for bulk composition. The CheMin XRD analysis shows that the mudstone contains basaltic minerals (Fe-forsterite, augite, pigeonite, plagioclase), as well as Fe-oxide/hydroxides, Fe-sulfides, amorphous materials, and trioctahedral phyllosilicates. SAM evolved gas analysis of higher-temperature OH matches the CheMin XRD estimate of ~20% clay minerals in the mudstone. The light-toned veins contain Ca-sulfates; anhydrite and bassanite are detected by XRD but gypsum is also indicated from Mastcam spectral mapping. These sulfates appear to be almost entirely restricted to late-diagenetic veins. The sulfate content of the mudstone matrix itself is lower than other sediments analyzed on Mars. The presence of phyllosilicates indicates that the activity of water was high during their formation and/or transport and deposition (should they have been detrital). Lack of chlorite places limits on the maximum temperature of alteration (likely <100 C). The presence of Ca-sulfates rather than Mg- or Fe-sulfates suggests that the pore water pH was near-neutral and of relatively low ionic strength (although x-ray amorphous Mg-and Fe- sulfates could be present and undetectable by CheMin). The presence of Fe and S in both reduced and oxidized states represents chemical disequilibria that could have been utilized by chemolithoautotrophic biota, if present. When compared to the nearby Rocknest sand shadow mineralogy or the normative mineralogy of Martian soil, both John Klein and Cumberland exhibit a near-absence of olivine and a surplus of magnetite (7-9% of the crystalline component). The magnetite is interpreted as an authigenic product formed when olivine was altered to phyllosilicate. Saponitization of olivine (a process analogous to serpentinization) could have produced H2 in situ. Indeed, early diagenetic hollow nodules ("minibowls") present in the Cumberland mudstone are interpreted by some as forming when gas bubbles accumulated in the unconsolidated mudstone. Lastly, all of these early diagenetic features appear to have been preserved with minimal alteration since their formation, as indicated by the ease of drilling (weak lithification, lack of cementing phases), the presence of 20-30% amorphous material, and the late-stage fracturing with emplacement of calcium sulfate veins and minibowl infills, where they were intersected by veins. A rough estimate of the minimum duration of the lacustrine environment is provided by the minimum thickness of the Sheepbed member. Given 1.5 meters, and applying a mean sediment accumulation rate for lacustrine strata of 1 m/1000 yrs yields a duration of 1,500 years. If the aqueous environments represented by overlying strata are considered, such as Gillespie Lake and Shaler, then this duration increases. The Sheepbed mudstone meets all the requirements of a habitable environment: Aqueous deposition at clement conditions of P, T, pH, Eh and ionic strength, plus the availability of sources of chemical energy.

Published
2013

28. Multispectral Microimager for Astrobiology

Author

Sellar, R. Glenn, Farmer, Jack D, Kieta, Andrew, and Huang, Julie

Subjects
Instrumentation And Photography
Abstract

A primary goal of the astrobiology program is the search for fossil records. The astrobiology exploration strategy calls for the location and return of samples indicative of environments conducive to life, and that best capture and preserve biomarkers. Successfully returning samples from environments conducive to life requires two primary capabilities: (1) in situ mapping of the mineralogy in order to determine whether the desired minerals are present; and (2) nondestructive screening of samples for additional in-situ testing and/or selection for return to laboratories for more in-depth examination. Two of the most powerful identification techniques are micro-imaging and visible/infrared spectroscopy. The design and test results are presented from a compact rugged instrument that combines micro-imaging and spectroscopic capability to provide in-situ analysis, mapping, and sample screening capabilities. Accurate reflectance spectra should be a measure of reflectance as a function of wavelength only. Other compact multispectral microimagers use separate LEDs (light-emitting diodes) for each wavelength and therefore vary the angles of illumination when changing wavelengths. When observing a specularly-reflecting sample, this produces grossly inaccurate spectra due to the variation in the angle of illumination. An advanced design and test results are presented for a multispectral microimager which demonstrates two key advances relative to previous LED-based microimagers: (i) acquisition of actual reflectance spectra in which the flux is a function of wavelength only, rather than a function of both wavelength and illumination geometry; and (ii) increase in the number of spectral bands to eight bands covering a spectral range of 468 to 975 nm.

Published
2006

29. Microbial Paleontology, Mineralogy and Geochemistry of Modern and Ancient Thermal Spring Deposits and Their Recognition on the Early Earth and Mars'

Author

Farmer, Jack D

Subjects
Geosciences (General)
Abstract

The vision of this project was to improve our understanding of the processes by which microbiological information is captured and preserved in rapidly mineralizing sedimentary environments. Specifically, the research focused on the ways in which microbial mats and biofilms influence the sedimentology, geochemistry and paleontology of modem hydrothermal spring deposits in Yellowstone national Park and their ancient analogs. Toward that goal, we sought to understand how the preservation of fossil biosignatures is affected by 1) taphonomy- the natural degradation processes that affect an organism from the time of its death, until its discovery as a fossil and 2) diagenesis- longer-term, post-depositional processes, including cementation and matrix recrystallization, which collectively affect the mineral matrix that contains fossil biosignature information. Early objectives of this project included the development of observational frameworks (facies models) and methods (highly-integrated, interdisciplinary approaches) that could be used to explore for hydrothermal deposits in ancient terranes on Earth, and eventually on Mars.

Published
2004

30. The NASA Astrobiology Roadmap

Author

Des Marais, David J, Allamandola, Louis J, Benner, Steven A, Boss, Alan P, Deamer, David, Falkowski, Paul G, Farmer, Jack D, Hedges, S. Blair, Jakosky, Bruce M, Knoll, Andrew H, Liskowsky, David R, Meadows, Victoria S, Meyer, Michael A, Pilcher, Carl B, Nealson, Kenneth H, Spormann, Alfred M, Trent, Jonathan D, Turner, William W, Woolf, Neville J, and Yorke, Harold W

Subjects
Exobiology
Abstract

The NASA Astrobiology Roadmap provides guidance for research and technology development across the NASA enterprises that encompass the space, Earth, and biological sciences. The ongoing development of astrobiology roadmaps embodies the contributions of diverse scientists and technologists from government, universities, and private institutions. The Roadmap addresses three basic questions: How does life begin and evolve, does life exist elsewhere in the universe, and what is the future of life on Earth and beyond? Seven Science Goals outline the following key domains of investigation: understanding the nature and distribution of habitable environments in the universe, exploring for habitable environments and life in our own solar system, understanding the emergence of life, determining how early life on Earth interacted and evolved with its changing environment, understanding the evolutionary mechanisms and environmental limits of life, determining the principles that will shape life in the future, and recognizing signatures of life on other worlds and on early Earth. For each of these goals, Science Objectives outline more specific high-priority efforts for the next 3-5 years. These 18 objectives are being integrated with NASA strategic planning.

Published
2003
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31. Jet-Suspended, Calcite-Ballasted Cyanobacterial Waterwarts in a Desert Spring

Author

Pichel-Garcia, Ferran, Wade, Bman D, and Farmer, Jack D

Subjects
Life Sciences (General)
Abstract

We describe a population of colonial cyanobacteria (waterwarts) that develops as the dominant primary producer in a bottom-fed, warm spring in the Cuatro Cienegas karstic region of the Mexican Chihuahuan Desert. The centimeter-sized waterwarts were suspended within a central, conically shaped, 6-m deep well by upwelling waters. Waterwarts were built by an unicellular cyanobacterium and supported a community of epiphytic filamentous cyanobacteria and diatoms but were free of heterotrophic bacteria inside. Sequence analysis of genes revealed that this cyanobacterium is only distantly related to several strains of other unicellular teria Cyanothece, Waterwarts contained orderly arrangements of mineral made up of microcrystalline low-magnesium calcite with high levels of strontium and sulfur. Waterwarts were 95.9% (v/v) glycan, 2.8% cells, and 1.3% mineral grains and had a buoyant density of 1.034 kg/L. An analysis of the hydrological properties of the spring well and the waterwarts demonstrated that both large colony size and the presence of controlled amounts of mineral ballast are required to prevent the population from being washed out of the well. The unique hydrological characteristics of the spring have likely selected for both traits. The mechanisms by which controlled nucleation of extracellular calcite is achieved remain to be explored.

Published
2002
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34. Deciphering Biosignatures in Planetary Contexts

Author

Chan, Marjorie A., primary, Hinman, Nancy W., additional, Potter-McIntyre, Sally L., additional, Schubert, Keith E., additional, Gillams, Richard J., additional, Awramik, Stanley M., additional, Boston, Penelope J., additional, Bower, Dina M., additional, Des Marais, David J., additional, Farmer, Jack D., additional, Jia, Tony Z., additional, King, Penelope L., additional, Hazen, Robert M., additional, Léveillé, Richard J., additional, Papineau, Dominic, additional, Rempfert, Kaitlin R., additional, Sánchez-Román, Mónica, additional, Spear, John R., additional, Southam, Gordon, additional, Stern, Jennifer C., additional, and Cleaves, Henderson James, additional

Published
2019
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35. Hopanoid Biomarker Preservation In Coniform (Phormidium) Stromatolites in Siliceous Thermal Springs, Yellowstone National Park

Author

Jahnke, Linda L, Summons, Roger E, Farmer, Jack D, Klein, Harold P, and DeVincenzi, Donald L

Subjects
Life Sciences (General)
Abstract

The microbial communities that characterize modem hydrothermal ecosystems serve as modern analogs to those thought to have dominated early environments on Earth and possibly Mars. The importance of such hydrothermal systems as targets in exploring for an early biosphere on Mars is well established. Such work provides an important basis for the analysis of Martian samples associated with such environments. The surviving molecular structure and isotopic signature of diagnostic lipid biomarkers found as chemical fossils can provide a link between modern bacterially dominated ecosystems and their ancient counterparts. We are interested in the processes involved in the deposition and/or degradation of organic material in moderately thermal, silicifying microbial mats, particularly as this relates to the potential for preservation of some biomarker components known to be more highly resistant to microbial degradation. Several excellent biomarker molecules are associated with the cyanobacteria that dominate these mats, particularly the 2-methylbacteriohopanepolyols (2-MeBHP). These compounds are ubiquitous on Earth and are not easily degraded in nature, a fact documented by their detection in ancient Earth rocks dating back as far as 2,700 Ma.

Published
2000

36. Modern Mat-Building Microbial Communities: a Key to the Interpretation of Proterozoic Stromatolitic Communities

Author

Pierson, Beverly K., primary, Bauld, John, additional, Castenholz, Richard W., additional, D'Amelio, Elisa, additional, Marais, David J. Des, additional, Farmer, Jack D., additional, Grotzinger, John P., additional, Jørgensen, Bo Barker, additional, Nelson, Douglas C., additional, Palmisano, Anna C., additional, Schopf, J. William, additional, Summons, Roger E., additional, Walter, Malcolm R., additional, and Ward, David M., additional

Published
1992
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39. Life: a cosmic imperative?

Author

Pendleton, Yvonne J. and Farmer, Jack D.

Subjects
Life on other planets -- Analysis, Planets, Theory of -- Analysis, Space biology -- Analysis, Astronomy, Analysis
Abstract

Earth has it. Mars might have it. What are the chances for life elsewhere in the solar system? Confined to a layer barely one-thousandth of the Earth's diameter, our planet's [...]

Published
1997

40. Exploring for Martian Life

Author

Farmer, Jack D and Chang, Sherwood

Subjects
Exobiology
Abstract

During the next decade, robotic field science will play an essential role in advancing our understanding of Martian history. Specifically, capable rovers are needed to survey a broad range of Martian rock types for in situ chemistry and mineralogy as a basis for interpreting globally-distributed data obtained from orbit. The relationship between orbital and landed science will be fundamental in selecting a landing site for future missions aimed at probing the ancient rock record for evidence of: (1) past life or prebiotic chemistry; (2) the climate and volatile history of Mars; and (3) candidate materials for in situ resource utilization.

Published
1997

41. Optimization of 2005 Sample Return for Mars Exopaleontology

Author

Farmer, Jack D

Subjects
Lunar And Planetary Exploration
Abstract

If we wish to retain the search for past/present life as an objective in the program, exobiological milestones need to be addressed at each opportunity. At this stage of Mars exploration, these milestones are complimentary to those of other disciplines. Achieving the goals of the exobiological community will require a long-term view of the problem and a phased plan of exploration. Decision trees are a realistic way to assess present needs and to benefit from future missions. Timely progress in achieving milestones identified will ensure we are moving ahead at each opportunity in meeting what the Agency (and public!) regards as an essential part of the program. It is clear that life-related issues must be handled carefully as they are presented to NASA and the public not to create an imbalance, or more importantly, misunderstanding about where we are in the exploration plan.

Published
1997

42. Exploring Mars for Evidence of Past or Present Life: Roles of Robotic and Human Missions

Author

Farmer, Jack D

Subjects
Lunar And Planetary Exploration
Abstract

During the coming decade, robotic field science will play a fundamental role in exploring Mars for evidence of past life and/or prebiotic chemistry. To create a context for such exploration, we especially need to understand the mineralogy and chemistry of the Martian surface. We have learned that the preservation of biological signatures in rocks on Earth is favored by rapid mineralization processes that are restricted to a comparatively small number of geological settings. Thus, a detailed knowledge of surface mineralogy will provide valuable clues about past Martian environments as a necessary context for future exobiological exploration.

Published
1996

43. Contributions of Planetary Science to Studies of Early Biosphere Evolution

Author

Farmer, Jack D and Chang, Sherwood

Subjects
Lunar And Planetary Science And Exploration
Abstract

The history of impact cratering on the Moon, and extrapolations of crater chronologies to the inner planets, suggests that the late accretionary history of the Earth overlapped with other crucial events in the its history, including the origin of terrestrial life. This evidence, acquired from studies of other planetary bodies in the inner solar system, has profoundly affected how we view the early history of the Earth and evolution of the biosphere. Pre-biotic chemical evolution and the origin of life would have been delayed by the probable existence of a global magma ocean until -4.2 Ga. The early crust was largely destroyed by recycling, thus accounting for the sparse Archean record on Earth. Once life had developed, large impacts may have extinguished it several times before it finally gained a foothold. Potentially sterilizing impacts could have occurred as late as 3.7 Ga. At the very least, large impacts would have forced the biosphere through major environmental "bottlenecks" thereby canalizing its subsequent evolution. One legacy of these early events may be the structure of the present RNA-tree which indicates that extreme thermophiles are primitive within the Archaea, and may be the last common ancestors of life. By 3.5 Ga, marine sedimentary sequences contain unequivocal microbial fossils that attest to the presence of a terrestrial biosphere. The diversity of microbial forms present in these earliest fossil assemblages implies a preceding interval of evolution during which major evolutionary advances (e.g. photosynthesis) could have taken place. Evidence cited above places the origin of life within the interval 3.5 and 4.2 Ga, a period of 700 Ma. Thus, it appears that terrestrial life not only evolved rapidly, but perhaps more than once. This expands the possibilities that life may have also developed elsewhere. Of the other planets in our solar system, Mars holds the greatest chance of having developed life. But, the present surface of Mars is hostile to life. Liquid water, regarded as essential for living systems, is unstable on the surface of Mars due to the low atmospheric pressure. The results of the Viking Lander biology experiments established that organic molecules are not present in the regolith of Mars, forcing the exobiological community to consider new ways of exploring for Martian life. Older, heavily cratered terranes on Mars show geomorphic evidence for abundant water between 3.0- 4.0 Ga. It is quite possible that life developed on Mars during this time, as it did on the Earth. The present focus for Mars Exobiology lies in the search for a fossil record. Archean-aged crust, while mostly missing on Earth, appears to be widespread in ancient cratered highlands of Mars, and aqueous mineral deposits within such sequences may hold crucial fossil evidence for an early Martian biosphere.

Published
1995

44. Fossilization Processes in Thermal Springs

Author

Farmer, Jack D, Cady, Sherry, Desmarais, David J, and Chang, Sherwood

Subjects
Geosciences (General)
Abstract

To create a comparative framework for the study of ancient examples, we have been carrying out parallel studies of the microbial biosedimentology, taphonomy and geochemistry of modem and sub-Recent thermal spring deposits. One goal of the research is the development of integrated litho- and taphofacies models for siliceous and travertline sinters. Thermal springs are regarded as important environments for the origin and early evolution of life on Earth, and we seek to utilize information from the fossil record to reconstruct the evolution of high temperature ecosystems. Microbial contributions to the fabric of thermal spring sinters occur when population growth rates keep pace with, or exceed rates of inorganic precipitation, allowing for the development of continuous biofilms or mats. In siliceous thermal springs, microorganisms are typically entombed while viable. Modes of preservation reflect the balance between rates of organic matter degradation, silica precipitation and secondary infilling. Subaerial sinters are initially quite porous and permeable and at temperatures higher than about 20 C, organic materials are usually degraded prior to secondary infilling of sinter frameworks. Thus, organically-preserved microfossils are rare and fossil information consists of characteristic biofabrics formed by the encrustation and underplating of microbial mat surfaces. This probably accounts for the typically low total organic carbon values observed in thermal spring deposits. In mid-temperature, (approx. 35 - 59 C) ponds and outflows, the surface morphology of tufted Phormidium mats is preserved through mat underplating by thin siliceous: crusts. Microbial taxes lead to clumping of ceils and/or preferred filament orientations that together define higher order composite fabrics in thermal spring stromatolites (e.g. network, coniform, and palisade). At lower temperatures (less than 35 C), Calothrix mats cover shallow terracette pools forming flat carpets or pustular surfaces that produce palisade and "shrub" fabrics, respectively. At finer scales, composite fabrics are seen to consist distinctive associations of microstructures formed by the encrustation of individual cells and filaments. Composite fabrics survive the diagenetic transitions from primary opaline silica to quartz and are known from subaerial thermal spring deposits as old as Lower Carboniferous. However, fossil microorganisms tend to be rare in older deposits, and are usually preserved only where cells or sheaths have been stained by iron oxides. In subaqueous mineralizing springs at lower temperatures, early infilling leads to a more rapid and complete reduction in porosity and permeability. This process, along with the slower rates of microbial degradation at lower temperatures, creates a more favorable situation for organic matter preservation. Application of this taphonomic model to the Rhynie Chert, previously interpreted as subaerial, suggest it was probably deposited in a subaqueous spring setting at lower temperatures.

Published
1995

45. Exopaleontology at The Pathfinder Landing Site

Author

Farmer, Jack D, DesMarais, David J, Greeley, Ronald, and DeVincenzi, Donald L

Subjects
Lunar And Planetary Science And Exploration
Abstract

The Mars Pathfinder Mission is a Discovery Class mission that will place a small lander and rover on the surface of Mars in July of 1997. It is primarily a technology demonstration to test the feasibility of a direct entry-delivery system, but carries a nominal scientific payload that includes rover-lander and instrumentation for limited mineralogical analysis. The nominal landing site was selected by the Pathfinder Team under the leadership of Dr. Matthew Golombek (JPL) based input from 60 participants at a Landing Site Workshop held last Spring at the Lunar Planetary Institute in Houston. The mission constraints for the landing site were 0-30 deg. N latitude, and below the 0.0 elevation datum. Over 20 landing sites were proposed and a nominal site was selected on southern Chryse Planitia near the terminae of the Ares and Tui outflow channels. In part, the decision to land at this location was based on the opportunity to sample a potentially large number lithologies in a small area (the rover will have a range of a few tens of meters from the lander). The purpose here is to review the general geological context of the landing site and the rationale for Exobiology's recommendation of the Ares site given at the workshop last spring. Because Ares and Tui Valles are sourced within terranes that may have originated by thermokarst processes, hydrothermal processes could have operated there for some time. Hydrothermal systems are presently regarded as important sites for a fossil record on Mars. Models for the formation of the outflow channels suggest that thermal spring sinters and associated aqueous mineral deposits, high priority targets for Mars Exopaleontology, could have formed in association with thermokarst processes and subsequently been delivered to the landing site in large quantities during the periodic cataclysmic outflows that created the channels.

Published
1995

46. A Strategy for Mars Exopaleontology

Author

Farmer, Jack D, DesMarais, David J, and Chang, Sherwood

Subjects
Lunar And Planetary Science And Exploration
Abstract

There is compelling geological evidence that the climate of early Mars was much more Earth-like, with a denser atmosphere and abundant surface water. Given that life developed on the Earth very quickly (between 4.2 and 3.5 Ga), it is quite plausible that life may have also developed on Mars during this early clement period. If Martian life developed, it is likely to have left behind a fossil record. Thus, an important focus for upcoming Mars missions is to explore for an ancient biosphere. This presents a set of goals and problems that are quite distinct from Exobiology. I call this new activity "Exopaleontology", whose core principles derive from studies of the Precambrian fossil record on Earth, biosedimentology and microbial fossilization. Such studies reveal that the most important factor favoring the long-term preservation of microbial fossils is rapid entombment of microorganisms by fine-grained, stable mineral phases such as silica, phosphate, carbonate and metal sulfides. Terrestrial environments where such aqueous mineral phases frequently entomb and preserve microorganisms include subaerial and subaqueous springs and shallow hydrothermal systems, evaporitic alkaline lakes, "hardpan" soils (e.g. calcretes, silcretes, ferracretes), and frozen soils or ground ice. With the exception of ice, which has a short crustal residence time, such deposits am known to retain a record of terrestrial life for billions of years. Current activities seek to refine and apply this strategy to the Mars Global Surveyor missions and beyond. Ongoing studies of microbial fossilization in each of the target environments identified above are aimed at improving our understanding of how biological information is incorporated into aqueous mineral deposits and preserved. Viking data is being used to target sites for high resolution orbital imaging and spectroscopy during upcoming Mars missions. Such data will provide a basis for selecting sites for future landed missions and eventually, sample return.

Published
1995

47. The Search for Carbonates on Mars

Author

Farmer, Jack D, DesMarais, David J, and Morrison, David

Subjects
Lunar And Planetary Science And Exploration
Abstract

Liquid water is presently unstable at the Martian surface, where the mean atmospheric pressure is 6 mbar (due to CO2) and the winter diurnal temperature ranges from 150 K at the pole to 220 K at the equator. Liquid water is widely regarded as a basic requirement for living systems, suggesting that life as we know it is not possible in present surface environments on Mars. However, life may survive within "oases" where liquid water is present. Potential oases on Mars include subsurface hydrothermal systems or deeply buried aquifers where chemoautolithotrophic microorganisms may exist. Potential metabolic strategies for primary production in such environments on Mars (and for the microbial mediation of geologic processes!) encompass the full range presently known for subsurface environments on the Earth (e.g. sulphate reduction, methanogenesis, acetogenesis, etc).

Published
1994

48. Exopaleontology and the search for a fossil record on Mars

Author

Farmer, Jack D and Desmarais, D. J

Subjects
Lunar And Planetary Exploration
Abstract

Although present Martian surface conditions appear unfavorable for life as we know it, there is compelling geological evidence that the climate of early Mars was much more Earth-like, with a denser atmosphere and abundant surface water. The fact that life developed on the Earth within the first billion years of its history makes it quite plausible that life may have also developed on Mars. If life did develop on Mars, it is likely to have left behind a fossil record. This has led to the development of a new subdiscipline of paleontology, herein termed 'exopaleontology', which deals with the exploration for fossils on other planets. The most important factor enhancing microbial fossilization is the rapid entombment of microorganisms by fine-grained, stable mineral phases, such as silica, phosphate, or carbonate. The oldest body fossils on Earth are preserved in this way, occurring as permineralized cells in fine-grained siliceous sediments (cherts) associated with ancient volcanic terranes in Australia and South Africa. Modern terrestrial environments where minerals may precipitate in the presence of microorganisms include subaerial thermal springs and shallow hydrothermal systems, sub-lacustrine springs and evaporitic alkaline lakes, zones of mineralization within soils where 'hardpans' (e.g. calcretes, silcretes) form, and high latitude frozen soils or ground ice.

Published
1994

49. Microbial Fossilization in Mineralizing Environments: Relevance for Mars 'EXOPALEONTOLOGY'

Author

Farmer, Jack D, DesMarais, David J, and Morrison, David

Subjects
Life Sciences (General)
Abstract

The goals of post-Viking exobiology include the search for a Martian fossil record. How can we optimize future exploration efforts to search for fossils on Mars? The Precambrian fossil record indicates that key factors for the long-term preservation of microbial fossils include: 1) the rapid entombment and/or replacement of organisms and organic matter by fine-grained, stable mineral phases (e.g. silica, phosphate, and to a lesser extent, carbonate), 2) low-permeability host sediments (maintaining a closed chemical system during early diagenesis), and 3) shallow burial (maintaining post-depositional temperatures and pressures within the stability range for complex organic molecules). Modem terrestrial environments where early mineralization commonly occurs in association with microbial organisms include: subaerial thermal springs and shallow hydrothermal systems, sub-lacustrine springs and evaporites of alkaline lakes, and subsoil environments where hardpans (e.g. calcretes, silcretes) and duricrusts form. Studies of microbial fossilization in such environments provide important insights preservation patterns in Precambrian rocks, while also playing a role in the development of strategies for Mars exopaleontology. The refinement of site priorities for Mars exopaleontology is expected to benefit greatly from high resolution imaging and altimetry acquired during upcoming orbital missions, and especially infrared and gamma ray spectral data needed for determining surface composition. In anticipation of future orbital missions, constraints for identifying high priority mineral deposits on Mars are being developed through analog remote sensing studies of key mineralizing environments on Earth.

Published
1994

50. Exobiology site priorities for Mars Pathfinder

Author

Farmer, Jack D and Desmarais, David J

Subjects
Lunar And Planetary Exploration
Abstract

The fact that life developed on the Earth within the first billion years of its history makes it quite plausible that life may have also developed on Mars. If life did develop on Mars, it undoubtedly left behind a fossil record. Such a fossil record is likely to be more accessible than either subsurface environments that may harbor life, or scattered 'oases' that may be present at the surface. Consequently, the post-Viking approach of Mars exobiology has shifted focus to search for evidence of an ancient martian biosphere. This has led to the emergence of a new subdiscipline of paleontology, herein termed 'exopaleontology', which deals with the exploration for fossils on other planets and whose core concepts derive from Earth-based Precambrian paleontology, microbial ecology, and sedimentology. Potential targets on Mars for subaqueous spring deposits, sedimentary cements, and evaporites are ancient terminal lake basins where hydrological systems could have endured for some time under arid conditions. Potential targets for the Mars Pathfinder mission include channeled impact craters and areas of deranged drainage associated with outflows in northwest Arabia and Xanthe Terra, where water may have ponded temporarily to form lakes. The major uncertainty of such targets is their comparatively younger age and the potentially short duration of hydrological activity compared to older paleolake basins found in the southern hemisphere. However, it has been suggested that cycles of catastrophic flooding associated with Tharsis volcanism may have sustained a large body of water, Oceanus Borealis, in the northern plains area until quite late in martian history. Although problematic, the shoreline areas of the proposed northern ocean provide potential targets for a Mars Pathfinder mission aimed at exploring for carbonates or other potentially fossiliferous marine deposits. Carbonates and evaporites possess characteristic spectra signatures in the near-infrared and should be detectable using rover-based spectroscopy and other methods for in situ mineralogical analysis.

Published
1994

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