Your search keyword '"Edgett, K. S"' showing total 118 results

1. The Mars 2020 Perseverance Rover Mast Camera Zoom (Mastcam-Z) Multispectral, Stereoscopic Imaging Investigation

Author

Bell, III, J. F., Maki, J. N., Mehall, G. L., Ravine, M. A., Caplinger, M. A., Bailey, Z. J., Brylow, S., Schaffner, J. A., Kinch, K. M., Madsen, M. B., Winhold, A., Hayes, A. G., Corlies, P., Tate, C., Barrington, M., Cisneros, E., Jensen, E., Paris, K., Crawford, K., Rojas, C., Mehall, L., Joseph, J., Proton, J. B., Cluff, N., Deen, R. G., Betts, B., Cloutis, E., Coates, A. J., Colaprete, A., Edgett, K. S., Ehlmann, B. L., Fagents, S., Grotzinger, J. P., Hardgrove, C., Herkenhoff, K. E., Horgan, B., Jaumann, R., Johnson, J. R., Lemmon, M., Paar, G., Caballo-Perucha, M., Gupta, S., Traxler, C., Preusker, F., Rice, M. S., Robinson, M. S., Schmitz, N., Sullivan, R., and Wolff, M. J.

Published

2021

2. The Stratigraphy of Central and Western Butte and the Greenheugh Pediment Contact

Author

Bryk, A. B, Dietrich, W. E, Fox, V. K, Bennett, K. A, Banham, S. G, Lamb, M. P, Grotzinger, J. P, Vasavada, A. R, Stack, K. M, Arvidson, R, Fedo, C. M, Gupta, S, Wiens, R. C, Williams, R. M. E, Kronyak, R.E, Turner, M. L, Lewis, K. W, Rubin, D. M, Rapin, W. N, Deit, L. Le, Mouélic, S. Le, Edgett, K. S, Fraeman, A. A, Hughes, M. N, Kah, L. C, and Bedford, C. C

Subjects

Space Sciences (General)

Abstract

The Greenheugh pediment at the base of Aeolis Mons (Mt. Sharp), which may truncate units in the Murray formation and is capped by a thin sandstone unit, appears to represent a major shift in climate history within Gale crater. The pediment appears to be an erosional remnant of potentially a much more extensive feature. Curiosity’s traverse through the southern extent of Glen Torridon (south of Vera Rubin ridge) has brought the rover in contact with several new stratigraphic units that lie beneath the pediment. These strata were visited at two outcrop-forming buttes (Central and Western butte- both remnants of the retreating pediment) south of an orbitally defined boundary marking the transition from the Fractured Clay-bearing Unit (fCU) and the fractured Intermediate Unit (fIU). Here we present preliminary interpretations of the stratigraphy within Central and Western buttes and propose the Western butte cap rocks do not match the pediment capping unit.

Published

2020

3. Prolonged Record of Hydroclimatic Changes at Antoniadi Crater, Mars

Author

Zaki, A. S., primary, Edgett, K. S., additional, Pajola, M., additional, Kite, E., additional, Davis, J. M., additional, Mangold, N., additional, Madof, A. S., additional, Lucchetti, A., additional, Grindrod, P., additional, Hughes, C. M., additional, Sangwan, K., additional, Thomas, N., additional, Schuster, M., additional, Gupta, S., additional, Cremonese, G., additional, and Castelltort, S., additional

Published

2023

4. The Sedimentary History of Mars as Observed by Rovers

Author

Rampe, E. B, Arvidson, R. E, Edgar, L. A, Edgett, K. S, Fedo, C. M, Fraeman, A. A, Grotzinger, J. P, McLennan, S. M, Ming, D. W, Morris, R. V, Siebach, K. L, and Sullivan, R. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

Mars has a sedimentary history that spans billions of years. Orbital images have allowed for the identification of vast regional sedimentary deposits that can be traced over 100s of kilometers and are 100s of meters thick including localized alluvial, deltaic, and lacustrine deposits. Detections of secondary minerals in these deposits from orbital spectroscopy suggest the aqueous history of early Mars varied as a function of space and time. Orbital observations, however, provide a simplified and incomplete picture of Mars’ sedimentary history because measurements for inferring sediment transport and deposition, such as lithology, grain size, and internal structures, and measurements for inferring sediment source and aqueous alteration, such as outcrop-scale mineralogic and geochemical composition and diagenetic features, cannot be identified from orbit. Rover observations have significantly enhanced our view of ancient and modern sedimentary environments on Mars, resulting in detailed reconstructions of paleo-environments and habitability.

Published

2019

5. Deposition, exhumation, and paleoclimate of an ancient lake deposit, Gale crater, Mars

Author

Grotzinger, J. P., Gupta, S., Malin, M. C., Rubin, D. M., Schieber, J., Siebach, K., Sumner, D. Y., Stack, K. M., Vasavada, A. R., Arvidson, R. E., Calef, F., Edgar, L., Fischer, W. F., Grant, J. A., Griffes, J., Kah, L. C., Lamb, M. P., Lewis, K. W., Mangold, N., Minitti, M. E., Palucis, M., Rice, M., Williams, R. M. E., Yingst, R. A., Blake, D., Blaney, D., Conrad, P., Crisp, J., Dietrich, W. E., Dromart, G., Edgett, K. S., Ewing, R. C., Gellert, R., Hurowitz, J. A., Kocurek, G., Mahaffy, P., McBride, M. J., McLennan, S. M., Mischna, M., Ming, D., Milliken, R., Newsom, H., Oehler, D., Parker, T. J., Vaniman, D., Wiens, R. C., and Wilson, S. A.

Published

2015

6. In Situ Radiometric and Exposure Age Dating of the Martian Surface

Author

MSL Science Team, Farley, K. A., Malespin, C., Mahaffy, P., Grotzinger, J. P., Vasconcelos, P. M., Milliken, R. E., Malin, M., Edgett, K. S., Pavlov, A. A., Hurowitz, J. A., Grant, J. A., Miller, H. B., Arvidson, R., Beegle, L., Calef, F., Conrad, P. G., Dietrich, W. E., Eigenbrode, J., Gellert, R., Gupta, S., Hamilton, V., Hassler, D. M., Lewis, K. W., McLennan, S. M., Ming, D., Navarro-González, R., Schwenzer, S. P., Steele, A., Stolper, E. M., Sumner, D. Y., Vaniman, D., Vasavada, A., Williford, K., and Wimmer-Schweingruber, R. F.

Published

2014

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

Author

MSL Science Team, Grotzinger, J. P., Sumner, D. Y., Kah, L. C., Stack, K., Gupta, S., Edgar, L., Rubin, D., Lewis, K., Schieber, J., Mangold, N., Milliken, R., Conrad, P. G., DesMarais, D., Farmer, J., Siebach, K., Calef, F., Hurowitz, J., McLennan, S. M., Ming, D., Vaniman, D., Crisp, J., Vasavada, A., Edgett, K. S., Malin, M., Blake, D., Gellert, R., Mahaffy, P., Wiens, R. C., Maurice, S., Grant, J. A., Wilson, S., Anderson, R. C., Beegle, L., Arvidson, R., Hallet, B., Sletten, R. S., Rice, M., Bell, J., Griffes, J., Ehlmann, B., Anderson, R. B., Bristow, T. F., Dietrich, W. E., Dromart, G., Eigenbrode, J., Fraeman, A., Hardgrove, C., Herkenhoff, K., Jandura, L., Kocurek, G., Lee, S., Leshin, L. A., Leveille, R., Limonadi, D., Maki, J., McCloskey, S., Meyer, M., Minitti, M., Newsom, H., Oehler, D., Okon, A., Palucis, M., Parker, T., Rowland, S., Schmidt, M., Squyres, S., Steele, A., Stolper, E., Summons, R., Treiman, A., Williams, R., and Yingst, A.

Published

2014

8. Mineralogy of a Mudstone at Yellowknife Bay, Gale Crater, Mars

Author

MSL Science Team, Vaniman, D. T., Bish, D. L., Ming, D. W., Bristow, T. F., Morris, R. V., Blake, D. F., Chipera, S. J., Morrison, S. M., Treiman, A. H., Rampe, E. B., Rice, M., Achilles, C. N., Grotzinger, J. P., McLennan, S. M., Williams, J., Bell, J. F., Newsom, H. E., Downs, R. T., Maurice, S., Sarrazin, P., Yen, A. S., Morookian, J. M., Farmer, J. D., Stack, K., Milliken, R. E., Ehlmann, B. L., Sumner, D. Y., Berger, G., Crisp, J. A., Hurowitz, J. A., Anderson, R., Des Marais, D. J., Stolper, E. M., Edgett, K. S., Gupta, S., and Spanovich, N.

Published

2014

9. Curiosity at Gale Crater, Mars: Characterization and Analysis of the Rocknest Sand Shadow

Author

Blake, D. F., Morris, R. V., Kocurek, G., Morrison, S. M., Downs, R. T., Bish, D., Ming, D. W., Edgett, K. S., Rubin, D., Goetz, W., Madsen, M. B., Sullivan, R., Gellert, R., Campbell, I., Treiman, A. H., McLennan, S. M., Yen, A. S., Grotzinger, J., Vaniman, D. T., Chipera, S. J., Achilles, C. N., Rampe, E. B., Sumner, D., Meslin, P.-Y., Maurice, S., Forni, O., Gasnault, O., Fisk, M., Schmidt, M., Mahaffy, P., Leshin, L. A., Glavin, D., Steele, A., Freissinet, C., Navarro-González, R., Yingst, R. A., Kah, L. C., Bridges, N., Lewis, K. W., Bristow, T. F., Farmer, J. D., Crisp, J. A., Stolper, E. M., Des Marais, D. J., and Sarrazin, P.

Published

2013

10. Martian Fluvial Conglomerates at Gale Crater

Author

Williams, R. M. E., Grotzinger, J. P., Dietrich, W. E., Gupta, S., Sumner, D. Y., Wiens, R. C., Mangold, N., Malin, M. C., Edgett, K. S., Maurice, S., Forni, O., Gasnault, O., Ollila, A., Newsom, H. E., Dromart, G., Palucis, M. C., Yingst, R. A., Anderson, R. B., Herkenhoff, K. E., Le Mouélic, S., Goetz, W., Madsen, M. B., Koefoed, A., Jensen, J. K., Bridges, J. C., Schwenzer, S. P., Lewis, K. W., Stack, K. M., Rubin, D., Kah, L. C., Bell, J. F., Farmer, J. D., Sullivan, R., Van Beek, T., Blaney, D. L., Pariser, O., and Deen, R. G.

Published

2013

11. 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

12. Mineralogy of Eolian Sands at Gale Crater

Author

Achilles, C. N, Vaniman, D. T, Blake, D. F, Bristow, T. F, Rampe, E. B, Ming, D. W, Chipera, S. J, Morris, R. V, Morrison, S. M, Downs, R. T, Fendrich, K. V, Ehlmann, B. L, Yen, A. S, Sarrazin, P. C, Treiman, A. H, Craig, P. I, Lapotre, M. G. A, Edgett, K. S, Gellert, R, Crisp, J. A, Morookian, J. M, Grotzinger, J. P, Des Marais, D. J, and Farmer, J. D

Subjects

Geophysics

Abstract

The Mars Science Laboratory rover Curiosity has been exploring outcrop and regolith in Gale crater since August 6, 2012. During this exploration, the mission has collected 10 samples for mineralogical analysis by X-ray diffraction (XRD), using the CheMin instrument. The CheMin (Chemistry and Mineralogy) instrument on the Mars Science Laboratory rover Curiosity uses a CCD detector and a Co-anode tube source to acquire both mineralogy (from the pat-tern of Co diffraction) and chemical information (from energies of fluoresced X-rays). A detailed description of CheMin is provided in [1]. As part of the rover checkout after landing, the first sample selected for analysis was an eolian sand deposit (the Rocknest "sand shadow"). This sample was selected in part to characterize unconsolidated eolian regolith, but primarily to prove performance of the scoop collection system on the rover. The focus of the mission after Rocknest was on the consolidated sediments of Gale crater, so all of the nine subsequent samples were collected by drilling into bedrock com-posed of lithified sedimentary materials, including mudstone and sandstone. No scoop samples have been collected since Rocknest, but at the time this abstract was written the mission stands poised to use the scoop again, to collect active dune sands from the Bagnold dune field. Several abstracts at this conference outline the Bagnold dune campaign and summarize preliminary results from analyses on approach to the Namib dune sampling site. In this abstract we review the mineralogy of Rocknest, contrast that with the mineralogy of local sediments, and anticipate what will be learned by XRD analysis of Bagnold dune sands.

Published

2016

13. Science Goals and Mission Architecture of the Europa Lander Mission Concept

Author

Hand, K. P., primary, Phillips, C. B., additional, Murray, A., additional, Garvin, J. B., additional, Maize, E. H., additional, Gibbs, R. G., additional, Reeves, G., additional, Martin, A. M. San, additional, Tan-Wang, G. H., additional, Krajewski, J., additional, Hurst, K., additional, Crum, R., additional, Kennedy, B. A., additional, McElrath, T. P., additional, Gallon, J. C., additional, Sabahi, D., additional, Thurman, S. W., additional, Goldstein, B., additional, Estabrook, P., additional, Lee, S. W., additional, Dooley, J. A., additional, Brinckerhoff, W. B., additional, Edgett, K. S., additional, German, C. R., additional, Hoehler, T. M., additional, Hörst, S. M., additional, Lunine, J. I., additional, Paranicas, C., additional, Nealson, K., additional, Smith, D. E., additional, Templeton, A. S., additional, Russell, M. J., additional, Schmidt, B., additional, Christner, B., additional, Ehlmann, B., additional, Hayes, A., additional, Rhoden, A., additional, Willis, P., additional, Yingst, R. A., additional, Craft, K., additional, Cameron, M. E., additional, Nordheim, T., additional, Pitesky, J., additional, Scully, J., additional, Hofgartner, J., additional, Sell, S. W., additional, Barltrop, K. J., additional, Izraelevitz, J., additional, Brandon, E. J., additional, Seong, J., additional, Jones, J.-P., additional, Pasalic, J., additional, Billings, K. J., additional, Ruiz, J. P., additional, Bugga, R. V., additional, Graham, D., additional, Arenas, L. A., additional, Takeyama, D., additional, Drummond, M., additional, Aghazarian, H., additional, Andersen, A. J., additional, Andersen, K. B., additional, Anderson, E. W., additional, Babuscia, A., additional, Backes, P. G., additional, Bailey, E. S., additional, Balentine, D., additional, Ballard, C. G., additional, Berisford, D. F., additional, Bhandari, P., additional, Blackwood, K., additional, Bolotin, G. S., additional, Bovre, E. A., additional, Bowkett, J., additional, Boykins, K. T., additional, Bramble, M. S., additional, Brice, T. M., additional, Briggs, P., additional, Brinkman, A. P., additional, Brooks, S. M., additional, Buffington, B. B., additional, Burns, B., additional, Cable, M. L., additional, Campagnola, S., additional, Cangahuala, L. A., additional, Carr, G. A, additional, Casani, J. R., additional, Chahat, N. E., additional, Chamberlain-Simon, B. K., additional, Cheng, Y., additional, Chien, S. A., additional, Cook, B. T., additional, Cooper, M., additional, DiNicola, M., additional, Clement, B., additional, Dean, Z., additional, Cullimore, E. A., additional, Curtis, A. G., additional, Croix, J-P. de la, additional, Pasquale, P. Di, additional, Dodd, E. M., additional, Dubord, L. A., additional, Edlund, J. A., additional, Ellyin, R., additional, Emanuel, B., additional, Foster, J. T., additional, Ganino, A. J., additional, Garner, G. J., additional, Gibson, M. T., additional, Gildner, M., additional, Glazebrook, K. J., additional, Greco, M. E., additional, Green, W. M., additional, Hatch, S. J., additional, Hetzel, M. M., additional, Hoey, W. A., additional, Hofmann, A. E., additional, Ionasescu, R., additional, Jain, A., additional, Jasper, J. D., additional, Johannesen, J. R., additional, Johnson, G. K., additional, Jun, I., additional, Katake, A. B., additional, Kim-Castet, S. Y., additional, Kim, D. I., additional, Kim, W., additional, Klonicki, E. F., additional, Kobeissi, B., additional, Kobie, B. D., additional, Kochocki, J., additional, Kokorowski, M., additional, Kosberg, J. A., additional, Kriechbaum, K., additional, Kulkarni, T. P., additional, Lam, R. L., additional, Landau, D. F., additional, Lattimore, M. A., additional, Laubach, S. L., additional, Lawler, C. R., additional, Lim, G., additional, Lin, J. Y, additional, Litwin, T. E., additional, Lo, M. W., additional, Logan, C. A., additional, Maghasoudi, E., additional, Mandrake, L., additional, Marchetti, Y., additional, Marteau, E., additional, Maxwell, K. A., additional, Namee, J. B. Mc, additional, Mcintyre, O., additional, Meacham, M., additional, Melko, J. P., additional, Mueller, J., additional, Muliere, D. A., additional, Mysore, A., additional, Nash, J., additional, Ono, H., additional, Parker, J. M., additional, Perkins, R. C., additional, Petropoulos, A. E, additional, Gaut, A., additional, Gomez, M. Y. Piette, additional, Casillas, R. P., additional, Preudhomme, M., additional, Pyrzak, G., additional, Rapinchuk, J., additional, Ratliff, J. M., additional, Ray, T. L., additional, Roberts, E. T., additional, Roffo, K., additional, Roth, D. C., additional, Russino, J. A., additional, Schmidt, T. M., additional, Schoppers, M. J., additional, Senent, J. S., additional, Serricchio, F., additional, Sheldon, D. J., additional, Shiraishi, L. R., additional, Shirvanian, J., additional, Siegel, K. J., additional, Singh, G., additional, Sirota, A. R., additional, Skulsky, E. D., additional, Stehly, J. S., additional, Strange, N. J., additional, Stevens, S. U., additional, Sunada, E. T., additional, Tepsuporn, S. P., additional, Tosi, L. P. C., additional, Trawny, N., additional, Uchenik, I., additional, Verma, V., additional, Volpe, R. A., additional, Wagner, C. T., additional, Wang, D., additional, Willson, R. G., additional, Wolff, J. L., additional, Wong, A. T., additional, Zimmer, A. K., additional, Sukhatme, K. G., additional, Bago, K. A., additional, Chen, Y., additional, Deardorff, A. M., additional, Kuch, R. S., additional, Lim, C., additional, Syvertson, M. L., additional, Arakaki, G. A., additional, Avila, A., additional, DeBruin, K. J., additional, Frick, A., additional, Harris, J. R., additional, Heverly, M. C., additional, Kawata, J. M., additional, Kim, S.-K., additional, Kipp, D. M., additional, Murphy, J., additional, Smith, M. W., additional, Spaulding, M. D., additional, Thakker, R., additional, Warner, N. Z., additional, Yahnker, C. R., additional, Young, M. E., additional, Magner, T., additional, Adams, D., additional, Bedini, P., additional, Mehr, L., additional, Sheldon, C., additional, Vernon, S., additional, Bailey, V., additional, Briere, M., additional, Butler, M., additional, Davis, A., additional, Ensor, S., additional, Gannon, M., additional, Haapala-Chalk, A., additional, Hartka, T., additional, Holdridge, M., additional, Hong, A., additional, Hunt, J., additional, Iskow, J., additional, Kahler, F., additional, Murray, K., additional, Napolillo, D., additional, Norkus, M., additional, Pfisterer, R., additional, Porter, J., additional, Roth, D., additional, Schwartz, P., additional, Wolfarth, L., additional, Cardiff, E. H., additional, Grob, E. W., additional, Adam, J. R., additional, Betts, E., additional, Norwood, J., additional, Heller, M. M., additional, Voskuilen, T., additional, Sakievich, P., additional, Gray, L., additional, Hansen, D. J., additional, Irick, K. W., additional, Hewson, J. C., additional, Lamb, J., additional, Stacy, S. C., additional, Brotherton, C. M., additional, Tappan, A. S, additional, Benally, D., additional, Thigpen, H., additional, Ortiz, E., additional, Sandoval, D., additional, Ison, A. M., additional, Warren, M., additional, Stromberg, P. G., additional, Thelen, P. M., additional, Blasy, B., additional, Nandy, P., additional, Haddad, A. W., additional, Trujillo, L. B., additional, Wiseley, T. H., additional, Bell, S. A., additional, Teske, N. P., additional, Post, C., additional, Torres-Castro, L., additional, Grosso, C., additional, and Wasiolek, M., additional

Published

2022

14. Fluvial Depositional Systems of the African Humid Period: An Analog for an Early, Wet Mars in the Eastern Sahara

Author

Zaki, A. S., Davis, J. M., Edgett, K. S., Giegengack, R., Roige, M., Conway, S., Schuster, M., Gupta, S., Salese, F., Sangwan, K. S., Fairén, A. G., Hughes, C. M., Pain, C. F., and Castelltort, S.

Subjects

Geophysics, Space and Planetary Science, Geochemistry and Petrology, Earth and Planetary Sciences (miscellaneous), Planète et Univers [physics]/Interfaces continentales, environnement, Planète et Univers [physics]/Sciences de la Terre, Sciences de l'environnement/Milieux et Changements globaux

Abstract

A widely hypothesized but complex transition from widespread fluvial activity to predominantly aeolian processes is inferred on Mars based on remote sensing data observations of ancient landforms. However, the lack of analysis of in situ martian fluvial deposits hinders our understanding of the flow regime nature and sustainability of the martian fluvial activity and the hunt for ancient life. Studying analogs from arid zones on Earth is fundamental to quantitatively understanding geomorphic processes and climate drivers that might have dominated during early Mars. Here we investigate the formation and preservation of fluvial depositional systems in the eastern Sahara, where the largest arid region on Earth hosts important repositories of past climatic changes. The fluvial systems are composed of well-preserved single-thread sinuous to branching ridges and fan-shaped deposits interpreted as deltas. The systems' configuration and sedimentary content suggest that ephemeral rivers carved these landforms by sequential intermittent episodes of erosion and deposition active for 10-100s years over ∼10,000 years during the late Quaternary. Subsequently, these landforms were sculpted by a marginal role of rainfall and aeolian processes with minimum erosion rates of 1.1 ± 0.2 mm/yr, supplying ∼96 ± 24 × 10

Published

2021

15. MARTIAN GEOLOGY: Deposition, exhumation, and paleoclimate of an ancient lake deposit, Gale crater, Mars

Author

Grotzinger, J. P., Gupta, S., Malin, M. C., Rubin, D. M., Schieber, J., Siebach, K., Sumner, D. Y., Stack, K. M., Vasavada, A. R., Arvidson, R. E., III, Calef F., Edgar, L., Fischer, W. F., Grant, J. A., Griffes, J., Kah, L. C., Lamb, M. P., Lewis, K. W., Mangold, N., Minitti, M. E., Palucis, M., Rice, M., Williams, R. M. E., Yingst, R. A., Blake, D., Blaney, D., Conrad, P., Crisp, J., Dietrich, W. E., Dromart, G., Edgett, K. S., Ewing, R. C., Gellert, R., Hurowitz, J. A., Kocurek, G., Mahaffy, P., McBride, M. J., McLennan, S. M., Mischna, M., Ming, D., Milliken, R., Newsom, H., Oehler, D., Parker, T. J., Vaniman, D., Wiens, R. C., and Wilson, S. A.

Published

2015

16. Diagenetic Crystal Growth in the Murray Formation, Gale Crater, Mars

Author

Kah, L. C, Kronyak, R. E, Ming, D. W, Grotzinger, J. P, Schieber, J, Sumner, D. Y, and Edgett, K. S

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Pahrump region (Gale Crater, Mars) marks a critical transition between sedimentary environments dominated by alluvial-to-fluvial materials associated with the Gale crater rim, and depositional environments fundamentally linked to the crater's central mound, Mount Sharp. At Pahrump, the Murray formation consists of an approximately 14-meter thick succession dominated by massive to finely laminated mudstone with occasional interbeds of cross-bedded sandstone, and is best interpreted as a dominantly lacustrine environment containing tongues of prograding fluvial material. Murray formation mudstones contain abundant evidence for early diagenetic mineral precipitation and its subsequent removal by later diagenetic processes. Lenticular mineral growth is particularly common within lacustrine mudstone deposits at the Pahrump locality. High-resolution MAHLI images taken by the Curiosity rover permit detailed morphological and spatial analysis of these features. Millimeter-scale lenticular features occur in massive to well-laminated mudstone lithologies and are interpreted as pseudomorphs after calcium sulfate. The distribution and orientation of lenticular features suggests deposition at or near the sediment-water (or sediment-air) interface. Retention of chemical signals similar to host rock suggests that original precipitation was likely poikilotopic, incorporating substantial amounts of the primary matrix. Although poikilotopic crystal growth is common in burial environments, it also occurs during early diagenetic crystal growth within unlithified sediment where high rates of crystal growth are common. Loss of original calcium sulfate mineralogy suggests dissolution by mildly acidic, later-diagenetic fluids. As with lenticular voids observed at Meridiani by the Opportunity Rover, these features indicate that calcium sulfate deposition may have been widespread on early Mars; dissolution of depositional and early diagenetic minerals is a likely source for both calcium and sulfate ion-enrichment in burial fluids that precipitated in ubiquitous late-stage hydrofracture veins

Published

2015

17. Oxidation Of Manganese At Kimberley, Gale Crater: More Free Oxygen In Mars' Past?

Author

Lanza, N. L, Wiens, R. C, Arvidson, R. E, Clark, B. C, Fischer, W. W, Gellert, R, Grotzinger, J. P, Hurowitz, J. A, McLennan, S. M, Morris, R. V, Rice, M. S, Bell, J. F., III, Berger, J. A, Blaney, D. L, Bridges, N. T, Calef, F., III, Campbell, J. L, Clegg, S. M, Cousin, A, Edgett, K. S, Fabre, C, Fisk, M. R, Forni, O, Frydenvang, J, and Ming, D. W

Subjects

Chemistry And Materials (General), Lunar And Planetary Science And Exploration

Abstract

High Mn concentrations provide unique indicators of water-rich environments and their redox state. Very high-potential oxidants are required to oxidize Mn to insoluble, high-valence oxides that can precipitate and concentrate Mn in rocks and sediments; these redox potentials are much higher than those needed to oxidize Fe or S. Consequently, Mn-rich rocks on Earth closely track the rise of atmospheric oxygen. Given the association between Mn-rich rocks and the redox state of surface environments, observations of anomalous Mn enrichments on Mars raise similar questions about redox history, solubility and aqueous transport, and availability as a metabolic substrate. Our observations suggest that at least some of the high Mn present in Gale crater occurs in the form of Mn-oxides filling veins that crosscut sand-stones, requiring post-depositional precipitation as highly oxidizing fluids moved through the fractured strata after their deposition and lithification.

Published

2015

18. Ripples, Transverse Aeolian Ridges, and Dark‐Toned Sand Dunes on Mars: A Case Study in Terra Sabaea

Author

Lu, Y., primary, Edgett, K. S., additional, and Wu, Y. Z., additional

Published

2021

19. A Lacustrine Paleoenvironment Recorded at Vera RubinRidge, Gale Crater: Overview of the Sedimentology and Stratigraphy Observed by the Mars ScienceLaboratory Curiosity Rover

Author

Edgar, L. A., Fedo, C. M., Gupta, S., Banham, S. G., Fraeman, A. A., Grotzinger, J. P., Stack, K. M., Stein, N. T., Bennett, K. A., Rivera‐Hernández, F., Sun, V. Z., Edgett, K. S., Rubin, D. M., House, C. H., and Van Beek, J.

Abstract

For ~500 Martian solar days (sols), the Mars Science Laboratory team explored Vera Rubin ridge (VRR), a topographic feature on the northwest slope of Aeolis Mons. Here we review the sedimentary facies and stratigraphy observed during sols 1,800–2,300, covering more than 100 m of stratigraphic thickness. Curiosity's traverse includes two transects across the ridge, which enables investigation of lateral variability over a distance of ~300 m. Three informally named stratigraphic members of the Murray formation are described: Blunts Point, Pettegrove Point, and Jura, with the latter two exposed on VRR. The Blunts Point member, exposed just below the ridge, is characterized by a recessive, fine‐grained facies that exhibits extensive planar lamination and is crosscut by abundant curvi‐planar veins. The Pettegrove Point member is more resistant, fine‐grained, thinly planar laminated, and contains a higher abundance of diagenetic concretions. Conformable above the Pettegrove Point member is the Jura member, which is also fine‐grained and parallel stratified, but is marked by a distinct step in topography, which coincides with localized meter‐scale inclined strata, a thinly and thickly laminated facies, and occasional crystal molds. All members record low‐energy lacustrine deposition, consistent with prior observations of the Murray formation. Uncommon outcrops of low‐angle stratification suggest possible subaqueous currents, and steeply inclined beds may be the result of slumping. Collectively, the rocks exposed at VRR provide additional evidence for a long‐lived lacustrine environment (in excess of 106 years via comparison to terrestrial records of sedimentation), which extends our understanding of the duration of habitable conditions in Gale crater.

Published

2020

20. Microscopic Views of Martian Soils and Evidence for Incipient Diagenesis

Author

Goetz, W, Madsen, M. B, Bridges, N, Clark, B, Edgett, K. S, Fisk, M, Grotzinger, J. P, Hviid, S. F, Meslin, P.-Y, Ming, D. W, Newsom, H, Sullivan, R, Vaniman, D, and Wiens, R

Subjects

Lunar And Planetary Science And Exploration

Abstract

Mars landed missions returned im-ages at increasingly higher spatial resolution (Table 1). These images help to constrain the microstructure of Martian soils, i.e. the grain-by-grain association of chemistry and mineralogy with secondary properties, such as albedo, color, magnetic properties, and mor-phology (size, shape, texture). The secondary charac-teristics are controlled by mineralogical composition as well as the geo-setting (transport and weathering modes, e.g. water supply, pH, atmospheric properties, exposure to radiation, etc.). As of today this association is poorly constrained. However, it is important to un-derstand soil-forming processes on the surface of Mars. Here we analyze high-resolution images of soils re-turned by different landed missions. Eventually these images must be combined with other types of data (chemistry and mineralogy at small spatial scale) to nail down the microstructure of Martian soils.

Published

2014

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

Author

Grotzinger, J. P., Sumner, D. Y., Kah, L. C., Stack, K., Gupta, S., Edgar, L., Rubin, D., Lewis, K., Schieber, J., Mangold, N., Milliken, R., Conrad, P. G., DesMarais, D., Farmer, J., Siebach, K., Calef, F., III, Hurowitz, J., McLennan, S. M., Ming, D., Vaniman, D., Crisp, J., Vasavada, A., Edgett, K. S., Malin, M., Blake, D., Gellert, R., Mahaffy, P., Wiens, R. C., Maurice, S., Grant, J. A., Wilson, S., Anderson, R. C., Beegle, L., Arvidson, R., Hallet, B., Sletten, R. S., Rice, M., Bell, J., III, Griffes, J., Ehlmann, B., Anderson, R. B., Bristow, T. F., Dietrich, W. E., Dromart, G., Eigenbrode, J., Fraeman, A., Hardgrove, C., Herkenhoff, K., Jandura, L., Kocurek, G., Lee, S., Leshin, L. A., Leveille, R., Limonadi, D., Maki, J., McCloskey, S., Meyer, M., Minitti, M., Newsom, H., Oehler, D., Okon, A., Palucis, M., Parker, T., Rowland, S., Schmidt, M., Squyres, S., Steele, A., Stolper, E., Summons, R., Treiman, A., Williams, R., and Yingst, A.

Published

2014

22. In Situ Radiometric and Exposure Age Dating of the Martian Surface

Author

Farley, K. A., Malespin, C., Mahaffy, P., Grotzinger, J. P., Vasconcelos, P. M., Milliken, R. E., Malin, M., Edgett, K. S., Pavlov, A. A., Hurowitz, J. A., Grant, J. A., Miller, H. B., Arvidson, R., Beegle, L., Calef, F., Conrad, P. G., Dietrich, W. E., Eigenbrode, J., Gellert, R., Gupta, S., Hamilton, V., Hassler, D. M., Lewis, K. W., McLennan, S. M., Ming, D., Navarro-González, R., Schwenzer, S. P., Steele, A., Stolper, E. M., Sumner, D. Y., Vaniman, D., Vasavada, A., Williford, K., and Wimmer-Schweingruber, R. F.

Published

2014

23. Mineralogy of a Mudstone at Yellowknife Bay, Gale Crater, Mars

Author

Vaniman, D. T., Bish, D. L., Ming, D. W., Bristow, T. F., Morris, R. V., Blake, D. F., Chipera, S. J., Morrison, S. M., Treiman, A. H., Rampe, E. B., Rice, M., Achilles, C. N., Grotzinger, J. P., McLennan, S. M., Williams, J., Bell, J. F., III, Newsom, H. E., Downs, R. T., Maurice, S., Sarrazin, P., Yen, A. S., Morookian, J. M., Farmer, J. D., Stack, K., Milliken, R. E., Ehlmann, B. L., Sumner, D. Y., Berger, G., Crisp, J. A., Hurowitz, J. A., Anderson, R., Des Marais, D. J., Stolper, E. M., Edgett, K. S., Gupta, S., and Spanovich, N.

Published

2014

24. Fluvial Depositional Systems of the African Humid Period: An Analog for an Early, Wet Mars in the Eastern Sahara.

Author

Zaki, A. S., Davis, J. M., Edgett, K. S., Giegengack, R., Roige, M., Conway, S., Schuster, M., Gupta, S., Salese, F., Sangwan, K. S., Fairén, A. G., Hughes, C. M., Pain, C. F., and Castelltort, S.

Subjects

EOLIAN processes, MARS (Planet), ALLUVIUM, ARID regions, CLIMATE change, EPHEMERAL streams, MEANDERING rivers

Abstract

A widely hypothesized but complex transition from widespread fluvial activity to predominantly aeolian processes is inferred on Mars based on remote sensing data observations of ancient landforms. However, the lack of analysis of in situ martian fluvial deposits hinders our understanding of the flow regime nature and sustainability of the martian fluvial activity and the hunt for ancient life. Studying analogs from arid zones on Earth is fundamental to quantitatively understanding geomorphic processes and climate drivers that might have dominated during early Mars. Here we investigate the formation and preservation of fluvial depositional systems in the eastern Sahara, where the largest arid region on Earth hosts important repositories of past climatic changes. The fluvial systems are composed of well‐preserved single‐thread sinuous to branching ridges and fan‐shaped deposits interpreted as deltas. The systems' configuration and sedimentary content suggest that ephemeral rivers carved these landforms by sequential intermittent episodes of erosion and deposition active for 10–100s years over ∼10,000 years during the late Quaternary. Subsequently, these landforms were sculpted by a marginal role of rainfall and aeolian processes with minimum erosion rates of 1.1 ± 0.2 mm/yr, supplying ∼96 ± 24 × 1010 m3 of disaggregated sediment to adjacent aeolian dunes. Our results imply that similar martian fluvial systems preserving single‐thread, short distance source‐to‐sink courses may have formed due to transient drainage networks active over short durations. Altogether, this study adds to the growing recognition of the complexity of interpreting climate history from orbital images of landforms. Plain Language Summary: Mars is currently a dry and cold desert, but rivers preserved in inverted topography suggest that water once flowed during its early history. However, how sustained and how frequently these rivers flowed remains uncertain. Here we study ancient fluvial systems (rivers and deltas) from the eastern Sahara that formed during the late Quaternary, in much wetter conditions than those prevailing today in this desert and which bear striking analogies to martian systems. We find that rivers and deltas, now preserved as ridges, record short distance source‐to‐sink high‐energy systems formed due to heavy rainfall events. Our observations and measurements of the meandering systems within the deltaic features suggest that such wet conditions might have spanned tens to a few hundred years over a total duration of ∼10,000 years. Since the wet conditions ceased, arid conditions prevailed, and the aeolian processes resumed, sculpting ridges out of ancient channels. Our results imply that martian fluvial systems may have been associated with similar local and heavy runoff conditions that lasted 10–100s years over thousands of years, possibly sufficient to support habitability. A shift toward arid environments led to the sculpting of fluvial ridges and the widespread formation of dunes across the modern martian landscape. Key Points: Ancient depositional rivers in southern Egypt record ephemeral fluvial systems formed due to intense rainfall over ∼10 kaThese fluvial systems suggest tens to hundreds of years of river activitySimilar martian systems imply that early Mars's surface was punctuated by local and transient drainage systems fed over short durations [ABSTRACT FROM AUTHOR]

Published

2022

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

Author

Grotzinger, J. P, Sumner, D. Y, Kah, L. C, Stack, K, Gupta, S, Edgar, L, Rubin, D, Lewis, K, Schieber, J, Mangold, N, Milliken, R, Conrad, P. G, DesMarais, D, Farmer, J, Siebach, K, Calef, F., III, Hurowitz, J, McLennan, S. M, Ming, D, Vaniman, D, Crisp, J, Vasavada, A, Edgett, K. S, Malin, M, Blake, D, Gellert, R, Mahaffy, P, Wiens, R. C, Maurice, S, Grant, J. A, Wilson, S, Anderson, R. C, Beegle, L, Arvidson, R, Hallet, B, Bristow, T. F, Eigenbrode, J, and Meyer, M

Subjects

Lunar And Planetary Science And Exploration, Exobiology

Abstract

The Curiosity rover discovered fine-grained sedimentary rocks, which are inferred to represent an ancient lake and preserve evidence of an environment that would have been suited to support a martian biosphere founded on chemolithoautotrophy. This aqueous environment was characterized by neutral pH, low salinity, and variable redox states of both iron and sulfur species. Carbon, hydrogen, oxygen, sulfur, nitrogen, and phosphorus were measured directly as key biogenic elements; by inference, phosphorus is assumed to have been available. The environment probably had a minimum duration of hundreds to tens of thousands of years. These results highlight the biological viability of fluvial-lacustrine environments in the post-Noachian history of Mars.

Published

2013

26. Mars Hand Lens Imager (MAHLI) efforts and observations at the “Rocknest' Eolian sand shadow in Curiosity’s Gale Crater field site

Author

Harker, D. E, Herkenhoff, K. E, Herrera, P. N, Hurowitz, J. A, Jandura, L, Krezoski, G. M, Lewis, K. W, Madsen, M. B, Maki, J. N, Malin, M. C, Ming, D. W, Nixon, B. E, Olson, T. S, Pariser, O, Posiolova, L. V, Ravine, M. A, Robinson, M. L, Roumeliotis, C, Rowland, S. K, Rubin, D. M, Ruoff, N. A, Seybold, C. C, Schieber, J, Schmidt, M. E, Sengstacken, A. J, Simmonds, J. J, Sullivan, R. J, Tompkins, V. V, Van Beek, T. L, Edgett, K. S, Yingst, R. A, Minitti, M. E, Goetz, W, Kah, L. C, Kennedy, M. R, Lipkaman, L. J, Jensen, E. H, Anderson, R. C, Beegle, L. W, Carsten, J. L, Cooper, B, Deen, R. G, Dromart, G, Eigenbrode, J. L, Grotzinger, J. P, Grupta, S, Hamilton, V. E, and Hardgrove, C. J

Abstract

The Mars Science Laboratory (MSL) mission is focused on assessing the past or present habitability of Mars, through interrogation of environment and environmental records at the Curiosity rover field site in Gale crater. The MSL team has two methods available to collect, process and deliver samples to onboard analytical laboratories, the Chemistry and Mineralogy instrument (CheMin) and the Sample Analysis at Mars (SAM) instrument suite. One approach obtains samples by drilling into a rock, the other uses a scoop to collect loose regolith fines.

Published

2013

27. Mars Hand Lens Imager (MAHLI) efforts and observations at the “Rocknest' Eolian sand shadow in Curiosity’s Gale Crater field site

Author

Edgett, K. S, Yingst, R. A, Minitti, M. E, Goetz, W, Kah, L. C, Kennedy, M. R, Lipkaman, L. J, Jensen, E. H, Anderson, R. C, Beegle, L. W, Carsten, J. L, Cooper, B, Deen, R. G, Dromart, G, Eigenbrode, J. L, Grotzinger, J. P, Grupta, S, Hamilton, V. E, Hardgrove, C. J, Harker, D. E, Herkenhoff, K. E, Herrera, P. N, Hurowitz, J. A, Jandura, L, Krezoski, G. M, Lewis, K. W, Madsen, M. B, Maki, J. N, Malin, M. C, Ming, D. W, Nixon, B. E, Olson, T. S, Pariser, O, Posiolova, L. V, Ravine, M. A, Robinson, M. L, Roumeliotis, C, Rowland, S. K, Rubin, D. M, Ruoff, N. A, Seybold, C. C, Schieber, J, Schmidt, M. E, Sengstacken, A. J, Simmonds, J. J, Sullivan, R. J, Tompkins, V. V, and Van Beek, T. L

Published

2013

28. Integrated Results from Analysis of the Rocknest Aeolian Deposit by the Curiosity Rover

Author

Leshin, L. A, Grotzinger, J. P, Blake, D. F, Edgett, K. S, Gellert, R, Mahaffy, P. R, Malin, M. C, Wiens, R. C, Treiman, A. H, Ming, D. W, and Eigenbrode, J

Subjects

Geophysics

Abstract

The Mars Science Laboratory Curiosity rover spent 45 sols (from sol 56-101) at an area called Rocknest (Fig. 1), characterizing local geology and ingesting its aeolian fines into the analytical instruments CheMin and SAM for mineralogical and chemical analysis. Many abstracts at this meeting present the contextual information and detailed data on these first solid samples analyzed in detail by Curiosity at Rocknest. Here, we present an integrated view of the results from Rocknest - the general agreement from discussions among the entire MSL Science Team.

Published

2013

29. Curiosity's Mars Hand Lens Imager (MAHLI): Inital Observations and Activities

Author

Edgett, K. S, Yingst, R. A, Minitti, M. E, Robinson, M. L, Kennedy, M. R, Lipkaman, L. J, Jensen, E. H, Anderson, R. C, Bean, K. M, Beegle, L. W, Carsten, J. L, Collins, C. L, Cooper, B, Deen, R. G, and Gupta, S

Subjects

Lunar And Planetary Science And Exploration

Abstract

MAHLI (Mars Hand Lens Imager) is a 2-megapixel focusable macro lens color camera on the turret on Curiosity's robotic arm. The investigation centers on stratigraphy, grain-scale texture, structure, mineralogy, and morphology of geologic materials at Curiosity's Gale robotic field site. MAHLI acquires focused images at working distances of 2.1 cm to infinity; for reference, at 2.1 cm the scale is 14 microns/pixel; at 6.9 cm it is 31 microns/pixel, like the Spirit and Opportunity Microscopic Imager (MI) cameras.

Published

2013

30. A Lacustrine Paleoenvironment Recorded at Vera RubinRidge, Gale Crater: Overview of the Sedimentology and Stratigraphy Observed by the Mars ScienceLaboratory Curiosity Rover

Author

Edgar, L. A., primary, Fedo, C. M., additional, Gupta, S., additional, Banham, S. G., additional, Fraeman, A. A., additional, Grotzinger, J. P., additional, Stack, K. M., additional, Stein, N. T., additional, Bennett, K. A., additional, Rivera‐Hernández, F., additional, Sun, V.Z., additional, Edgett, K. S., additional, Rubin, D. M., additional, House, C., additional, and Van Beek, J., additional

Published

2020

31. North-south geological differences between the residual polar caps on Mars

Author

Thomas, P. C., Malin, M. C., Edgett, K. S., Carr, M. H., Hartmann, W. K., Ingersoll, A. P., James, P. B., Soderblom, L. A., Veverka, J., and Sullivan, R.

Subjects

Environmental issues, Science and technology, Zoology and wildlife conservation

Abstract

Author(s): P. C. Thomas (corresponding author) [1]; M. C. Malin [2]; K. S. Edgett [2]; M. H. Carr [3]; W. K. Hartmann [4]; A. P. Ingersoll; P. B. James [6]; [...]

Published

2000

32. Recent Aeolian Dune Change on Mars

Author

Bourke, M. C, Edgett, K. S, and Cantor, B. A

Subjects

Geophysics

Abstract

Previous comparisons of Martian aeolian dunes in satellite images have not detected any change in dune form or position. Here, we show dome dunes in the north polar region that shrank and then disappeared over a period of 3.04 Mars years (5.7 Earth years), while larger, neighboring dunes showed no erosion or movement. The removal of sand from these dunes indicates that not only is the threshold wind speed for saltation exceeded under present conditions on Mars, but that any sand that is available for transport is likely to be moved. Dunes that show no evidence of change could be crusted, indurated. or subject to infrequent episodes of movement.

Published

2007

33. The Mars Hand Lens Imager (MAHLI) for the 209 Mars Science Laboratory

Author

Edgett, K. S, Bell, J. F., III, Herkenhoff, K. E, Heydari, E, Kah, L. C, Minitti, M. E, Olson, T. S, Rowland, S. K, Schieber, J, and Sullivan, R. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

The MArs Hand Lens Imager (MAHLI) is a small, RGB-color camera designed to examine geologic material at 12.5-75 microns/pixel resolution at the Mars Science Laboratory (MSL) landing site. MAHLI is a PI-led investigation competitively selected by NASA in December 2004 as part of the science payload for the MSL rover launching in 2009. The instrument is being fabricated by, and will be operated by, Malin Space Science Systems of San Diego, California.

Published

2005

34. The Mast Cameras and Mars Descent Imager (MARDI) for the 2009 Mars Science Laboratory

Author

Malin, M. C, Bell, J. F, Cameron, J, Dietrich, W. E, Edgett, K. S, Hallet, B, Herkenhoff, K. E, Lemmon, M. T, Parker, T. J, and Sullivan, R. J

Subjects

Geophysics

Abstract

Based on operational experience gained during the Mars Exploration Rover (MER) mission, we proposed and were selected to conduct two related imaging experiments: (1) an investigation of the geology and short-term atmospheric vertical wind profile local to the Mars Science Laboratory (MSL) landing site using descent imaging, and (2) a broadly-based scientific investigation of the MSL locale employing visible and very near infra-red imaging techniques from a pair of mast-mounted, high resolution cameras. Both instruments share a common electronics design, a design also employed for the MSL Mars Hand Lens Imager (MAHLI) [1]. The primary differences between the cameras are in the nature and number of mechanisms and specific optics tailored to each camera s requirements.

Published

2005

35. Extensive Polygonal Fracture Network in Siccar Point group Strata: Fracture Mechanisms and Implications for Fluid Circulation in Gale Crater, Mars

Author

Kronyak, R. E., primary, Kah, L. C., additional, Miklusicak, N. B., additional, Edgett, K. S., additional, Sun, V. Z., additional, Bryk, A. B., additional, and Williams, R. M. E., additional

Published

2019

36. The Residual Polar Caps of Mars: Geological Differences and Possible Consequences

Author

Thomas, P. C, Sullivan, R, Ingersoll, A. P, Murray, B. C, Danielson, G. E, Herkenhoff, K. E, Soderblom, L, Malin, M. C, Edgett, K. S, and James, P. B

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Martian polar regions have been known to have thick layered sequences (presumed to consist of silicates and ice), CO2 seasonal frost, and residual frosts that remain through the summer: H2O in the north, largely CO2 in the south. The relationship of the residual frosts to the underlying layered deposits could not be determined from Viking images. The Mars Orbiter Camera on Mars Global Surveyor has provided a 50-fold increase in resolution that shows more differences between the two poles. The north residual cap surface has rough topography of pits, cracks, and knobs, suggestive of ablational forms. This topography is less than a few meters in height, and grades in to surfaces exposing the layers underneath. In contrast, the south residual cap has distinctive collapse and possibly ablational topography emplaced in four or more layers, each approx. two meters thick. The top surface has polygonal depressions suggestive of thermal contraction cracks. The collapse and erosional forms include circular and cycloidal depressions, long sinuous troughs, and nearly parallel sets of troughs. The distinctive topography occurs throughout the residual cap area, but not outside it. Unconformities exposed in polar layers, or other layered materials, do not approximate the topography seen on the south residual cap. The coincidence of a distinct geologic feature, several layers modified by collapse, ablation, and mass movement with the residual cap indicates a distinct composition and/or climate compared to both the remainder of the south polar layered units and those in the north.

Published

2000

37. Mineral‐Filled Fractures as Indicators of Multigenerational Fluid Flow in the Pahrump Hills Member of the Murray Formation, Gale Crater, Mars

Author

Kronyak, R. E., primary, Kah, L. C., additional, Edgett, K. S., additional, VanBommel, S. J., additional, Thompson, L. M., additional, Wiens, R. C., additional, Sun, V. Z., additional, and Nachon, M., additional

Published

2019

38. Characterization of Terrain in the Mars Surveyor 2001 Landing Site Latitude and Elevation Region Using Mapping Phase Mars Global Surveyor MOC Images

Author

Malin, M. C, Edgett, K. S, and Parker, T. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

One of the original objectives of the Mars Orbiter Camera (MOC), as proposed in 1985, was to acquire observations to be used in assessing future spacecraft landing sites. Images obtained by the Mars Global Surveyor MOC since March 1999 provide the highest resolution views (1.5-4.5 m/pixel) of the planet ever seen. We have been examining these new data to develop a general view of what Mars is like at meter-scale within the latitudes and elevations that are accessible to the Mars Surveyor 2001 lander. Our goal is to provide guidance to the 2001 landing site selection process, rather than to use MOC images to recommend a specific landing site.

Published

1999

39. Detection of Crystalline Hematite Mineralization on Mars by the Thermal Emission Spectrometer: Evidence for Near-surface Water

Author

Christensen, P. R, Bandfield, J. L, Clark, R. N, Edgett, K. S, Hamilton, V. E, Hoefen, T, Kieffer, H. H, Kuzmin, R. O, Lane, M. D, and Malin, M. C

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Thermal Emission Spectrometer (TES) instrument on the Mars Global Surveyor (MGS) mission has discovered a remarkable accumulation of crystalline hematite ((alpha-Fe2O3) that covers an area with very sharp boundaries approximately 350 by 350-750 km in size centered near 2 S latitude between 0 and 5 W longitude (Sinus Meridiani). Crystalline hematite is uniquely identified by the presence of fundamental vibrational absorption features centered near 300, 450, and >525/cm, and by the absence of silicate fundamentals in the 1000/cm region. Spectral features resulting from atmospheric CO2, dust, and water ice were removed using a radiative transfer model. The spectral properties unique to Sinus Meridiani were emphasized by removing the average spectrum of the surrounding region. The depth and shape of the hematite fundamental bands show that the hematite is crystalline and relatively coarse grained (>5-10 micron). Diameters up to and greater than 100s of micrometers are permitted within the instrumental noise and natural variability of hematite spectra. Hematite particles <5-10 micron in diameter (either as an unpacked or hard-packed powders) fail to match the TES spectra. The spectrally-derived areal abundance of hematite varies with particle size from approximately 10% for particles >30 micron in diameter to 40-60% for unpacked 10 micron powders. The hematite in Sinus Meridiani is thus distinct from the fine-grained (diameter <5-10 micron), red, crystalline hematite considered, on the basis of visible, near-IR data, to be a minor spectral component in Martian bright regions like Olympus-Amazonis. Sinus Meridiani hematite is closely associated with a smooth, layered, friable surface that is interpreted to be sedimentary in origin. This material may be the uppermost surface in the region, indicating that it could be a late-stage sedimentary unit, or it could be a layered portion of the heavily cratered plains units. We consider five possible mechanisms for the formation of coarse-grained, crystalline hematite. These processes fall into two classes depending on whether they require a significant amount of near-surface water: (1) chemical precipitation that includes origin by (a) precipitation from oxygenated, Fe-rich water (iron formations), (b) hydrothermal extraction and crystal growth.

Published

1999

40. Proposed Mars Surveyor Landing Sites in Northern Meridiani Sinus, Southern Elysium Planitia, and Argyre Planitia

Author

Parker, T. J and Edgett, K. S

Subjects

Lunar And Planetary Science And Exploration

Abstract

Our objective is to propose two landing sites that the Mars Surveyor 2001 Lander and Athena Rover could go to on Mars that should meet the safety requirements of the spacecraft landing system and optimize surface operations (chiefly driven by power and communications requirements). An additional site within Argyre Planitia, initially proposed by Parker to the Mars Surveyor Landing Site program, is also proposed for potential consideration for post-2001 missions to Mars, as it is well outside the current latitude limits for the Athena Rover. All three sites are designed to be situated as close to a diversity of geologic units within a few kilometers of the landing site so that diversity can be placed in a geologic context. This objective is very different from the Mars Pathfinder requirement to land at a site with a maximum chance for containing a diversity of rocks within a few tens of meters of the lander. That requirement was driven by the Sojourner mobility limit of a few tens of meters. It can be argued that the Athena project, with its much larger mobility capability, might actually want to avoid such a site, because placing collected samples in geologic context would be difficult. While it has been argued, both before and after the Mars Pathfinder landing, that the provenance for local blocks may be determined by orbiter spectra, primarily from the MGS TES instrument, our ability to do so has yet to be demonstrated. Indeed, several months after conclusion of the Pathfinder mission, we have yet to reach a consensus on the composition of local materials. Our primary data set for selecting a landing site within the latitude and elevation constraints of the 2001 mission is the Viking Orbiter image archive. The site must be selected to place the landing ellipse so as to avoid obvious hazards, such as steep slopes, large or numerous craters, or abundant large knobs. For this purpose, we chose a resolution limit of better than 50 m/pixel. This necessarily excludes from the present study images from current and future orbiter spacecraft, until such data does become readily available. Within each proposed region, it may be possible to identify additional sites once these data become available. Second, the fine-component thermal inertia data, should be greater than about 5 or 6 cgs Units (10(exp -3) cal/sq cm s(exp -0.5)/K). Low thermal inertias imply dusty environments, which could pose a mobility hazard. Similarly, the albedo of the site should not be particularly high, which would also suggest dusty surfaces. Low albedos are preferred, as they often coincide with low Viking red:violet ratios and indicate less dusty surfaces. Next, the Modeled Block Abundance should also not be too high or too low. Based on the Viking Lander and Mars Pathfinder experiences, percentages of blocks should be on the order of 5-25%. Too many blocks could pose a hazard to the landing and mobility. Too few blocks could also indicate a dusty surface. Primary Landing Site: Northern Meridiani Sinus (Proposed by T. J. Parker and K., S. Edgett) Vital Statistics: (1) Latitude, Longitude: 0-3 N, 350-2 W. *Elevation (Viking): about0.5-1.5 Ian. (2) Viking Orbiter Image coverage: Excellent coverage by 15 - 25 m/pixel images (orbits 709A and 410B). Possible stereo coverage in region where two orbits overlap (probably small parallax angle, as these orbits are not listed in NASA Contractor Report 3501) (3) Albedo: about .18 -.26 (4) Block Abundance: 5-26% (5)Fine-Component Thermal Inertia: 5-9 cgs units This region consists of bright deposits similar to those described by Edgett et al, that also lie within a prominent dark albedo region. These deposits are flat-lying, to such a degree that they ramp against topography rather than draping over it. This led Edgett and Parker to suggest that they may be subaqueous sediments, possibly lacustrine or marine evaporites, laid down sometime from the late Noachian to middle Hesperian (age determination pending crater counts). A contact between this material and elevated, dissected highlands to the south was identified , and is described by Edgett et al. Our desire in proposing this landing site is to sample the edge of this deposit where it has been exposed through etching, presumably eolian deflation (the deposit, though in the highlands, is itself only lightly to moderately cratered). This should enable access to in situ stratigraphy. The actual landing site will be selected where slopes are not expected to be steep, such that the rover itself should be able to traverse them and sample layered materials on the way, either up or down the slope. Perhaps due to uncertainties at this time as to the friability or meter-scale roughness of the deposit, it might make sense to place the landing ellipse on the exhumed highland surface adjacent to the deflated margin of the deposit and plan on driving to the deposit rather than landing on it and driving downslope. This should also enable imaging the margin for evidence of layering should it prove too difficult to climb. A target ellipse on the highland surface should also allow Athena access to ancient Noachian highland materials, particularly if placed near crater ejecta or an inlier of knobby material. Secondary Landing Site: Southern Elysium Planitia (Proposed by T. J. Parker) Vital Statistics: (1) Latitude, Longitude: 1.5-3.5 S, 195-198 W. (2) Elevation (Viking): -1.0 km. (3) Viking Orbiter Image coverage: Excellent coverage by 15 - 25 m/pixel images (orbit 725). Possible stereo coverage between images from beginning and end of orbit that overlap (probably small parallax angle) (4) Albedo: about .27-.28 (5) Block Abundance: 4-7% (6) Fine-Component Thermal Inertia: about 3 cgs units This region consists of eroded knobby material, probably of Noachian age, though much of the crater population has been destroyed, that is onlapped at a sharp contact by an extensive plains unit in southern Elysium Planitia that is Amazonian in age. The plains materials have been attributed to unusually low-viscosity flood lavas from fissures south of the Elysium volcanic rise, or to lacustrine materials associated with a large, Amazonian lake at the source of Marte Vallis. Parker and Schenk presented evidence in support of the latter interpretation, though they attributed the putative shore morphology to an embayment of a northern plains ocean into the southern Elysium region. Detailed examination of the margin of the deposit, showing erosion, not simply burial, of small crater rims and fluidized ejecta blankets, also points to lacustrine or marine sedimentation rather than volcanic plains burial. The plains surface exhibits a "crusty" appearance that many researchers have attributed to pressure ridges in lava flows. In a lacustrine context, they also resemble pressure ridges in desiccated evaporite deposits and salt-rimmed pools (now dry) similar in scale and morphology to spectacular, hundred meter-scale pool rims in alkaline Lake Natron, East African Rift. The eroded highland margin surface adjacent to these plains appears to be fairly smooth, even at 15 m/pixel. Isolated knob inliers are scattered from a few kilometers to several tens of "kilometers apart. Heights of the knobs have not been measured yet but, based on experience with similar features in the Pathfinder landing ellipse, are probably typically on the order of several tens of meters high and smaller, though some of the largest knobs in the region are probably up to a few hundred meters high. Two craters larger than a kilometer in diameter, with fluidized deposits, lie nearby the proposed landing site. Very high-resolution images from MOC should help to determine whether a landing site navigable by the Athena rover could be placed in this region. The space between knobs and craters is large enough to enable placement of a target landing ellipse between them but still provide access to one or more of them and to the margin of the Elysium plains material. Post-2001 Mars Surveyor Landing Site: Argyre Planitia (Proposed by T. J. Parker) Vital Statistics: (1) Latitude, Longitude: 55-56 S, 41-43 W. (2) Elevation (Viking): 1.0 km. (3) Viking Orbiter Image coverage: Excellent coverage by 40 m/pixel images (orbits 567B, 568B, and 569B). Excellent stereo coverage with large parallax angles over the entire landing site region, and much of central and southern Argyre. (4) Albedo: about .23-.24 (5) Block Abundance: No data (6) Fine-Component Thermal Inertia: No data The floors of both the Argyre and Hellas basins contain etched layered materials that are probably thick accumulations of channel or lacustrine sediments. The deposits in Hellas are much more eroded than those in Argyre, and Hellas lacks a channel outlet. Argyre is unique in that Uzboi Vallis flowed out of the basin, requiring overflow of a standing body of water within Argyre. This makes it the largest impact basin on Mars with channels both draining into it and flowing out from it. Hellas' channels may be catastrophic flood channels, whereas Argyre was fed by modest-scale valley networks, though the outlet at Uzboi Vallis was a catastrophic flood Highland craters and basins of this kind should be high-priority landing targets for missions intended to focus on the search for either prebiotic organic materials or even simple fossil microorganisms. Basins with internally-draining valley networks should be preferred over flood channels, as they could have provided the long-term influx of water favorable to the origin of life. (Catastrophic floods are not conducive to fossil preservation, due to their very short durations and high transportation energies). They also afford an opportunity to study the evolution of the planet's climate and volatiles during the period of time between the late Noachian and early Hesperian, when a drastic change from a proposed early warm, wet climate to one more closely resembling the modern environment is thought to have occurred. Large basin

Published

1998

41. Potential Mars Surveyor 2001 Landing Sites: Low-Elevation Cratered 'Highlands' in Central and Eastern Sinus Meridiani and Near Amenthes Fossae

Author

Edgett, K. S, Parker, T. J, and Huntwork, S. N

Subjects

Lunar And Planetary Science And Exploration

Abstract

The main scientific goal for the Mars Surveyor Program 2001 (MSP 01) landed mission is to collect and characterize 91 rock and 13 soil core samples using an integrated instrument suite onboard the Athena Rover. If possible, these samples will be retrieved and returned to Earth via a MSP 05 or MSP 07 mission. Preliminary engineering constraints for the MSP 01 landing site call for a location that lies between 15 S and 30 N, and below about 2 km elevation (based on Viking-era topography). Desirable landing sites for MSP 01 are to be located "in the ancient highlands where the environmental conditions may have been favorable to the preservation of evidence of possible prebiotic or biotic processes including the emergence (and, potentially, the persistence) of life". We interpret this to mean that the desirable sites include those that have evidence of aqueous sediments that might have been deposited during the Noachian and/or Hesperian Epochs of Mars' history. In addition to the search for subaqueous sedimentary deposits, we took into consideration the fact that the rover, Athena, will need to be able to access these materials. Thus, a site where aeolian deflation has occurred might be desirable because it might expose, in situ, layered sedimentary deposits. Deflated areas, of course, might include potential landing hazards in the form of meterscale buttes and mesas (e.g., Christmas Lake Valley, OR), thus careful study of such sites with high resolution images will be required before a decision is made to land. We have been examining three regions that have potential to be considered for MSP 01 landing sites. This work is based on Viking (VIS, IRTM) and Phobos 2 (Termoskan) observations and should be regarded as preliminary because we believe that the final site selection should also be based upon analysis of Mars Global Surveyor observations that help constrain mineralogy (TES) and local geomorphology (MOC, MOLA). (1) Eastern Sinus Meridiani Region (proposed by K. S. Edgett) Sinus Meridiani is a persistent low-albedo (< 0. 16) region on the martian equator that has been recognized for about 400 years. All of Sinus Meridiani is below the 2 km elevation constraint for MSP 01. The region includes cratered highlands, valley networks, aeolian dunes, and possible aqueous sedimentary deposits. The landing site study region is located in the eastern portion of Sinus Meridiani. It is bounded by latitudes 10 S to 2 N, longitudes 355 W to 345 W, and the elevations are mostly 1-2 km. The center of this area contains a medium-albedo (0.19-0.21), relatively smooth-surfaced deposit that was suggested by Rice to be a lacustrine deposit. Several potential landing areas can be suggested within this region. Based on Viking and Phobos 2 data, the favored sites so far are centered at 7.6 S, 346.9 W and 0.8 S, 349 W. Thermal inertias are 3.2-7.0 x 10(exp -3) cal /sq cm s(exp -0.5)/K; and rock abundances are around 2-6%. The site at 7.6 S, 346.9 W is at the southern end of the smooth, medium-albedo unit that might have a lacustrine origin. At this location, numerous channels appear to have drained toward the smooth unit. Viking images from orbit 747A show this area at about 15 m/pixel ground resolution. The images reveal that aeolian deflation has occurred along the deposit's margins. Bright (i.e., albedo >= 0.21) aeolian dunes are present on the channel floors and in some of the depressions on the smooth unit. The bright, apparently active dunes might consist of material (perhaps lakedeposited sands) that has been eroded from the smooth unit. The site at approximately 0.8 S, 349 W is selected because it offers an opportunity to solve a long-standing puzzle about Mars remote sensing. There are three main "color" units on Mars: "dark red, dark gray, and bright red". This landing site would allow the Athena rover an opportunity to investigate all three materials within close proximity (the best place on Mars to do so). There are no high resolution (better than 100 m/pixel) Viking or Mariner images of this site. (2) Central Sinus Meridiani Region (proposed by K. S. Edgett and T. J. Parker) Central Sinus Meridiani is characterized by two types of surfaces [4]. One is like typical martian cratered highlands elsewhere- there are old valley networks and old impact craters. The other is relatively smooth and flat. These two units are in contact around 3.1 S between 5 W and 4 E longitudes. Valley networks- including one at 6'S, 358 W that rivals the Grand Canyon of Arizona- once drained toward the smooth unit. Edgett and Parker [4] proposed that the smooth unit might consist of sediments laid down in a large Noachian-aged sea/ocean that would have covered much of the northern hemisphere. Schultz and Lutz [I I I suggested that it is a paleopolar layered deposit. Regardless, the smooth unit where it contacts the cratered terrain would make an excellent site for Athena rover to investigate. The site is best seen in Viking high resolution images from orbits 408B (about 30 m/pixel) and 746A (about 12 m/pixel). These images suggest that aeolian deflation has occurred along the margin of the smooth unit, and this deflation has exposed horizontal larrs of material. The elevation is about 0.5 km; thermal inertias are 6.5-8.0 x 10(exp -3) cal /sq cm s(exp -0.5) / K; rock abundances are 2-4%; and the surface is probably sandy with dark drifts and ripples but almost no actual dunes. We suggest a landing around 3.2 S, 3.0 W would test the aqueous sediment hypothesis and provide a potentially smooth surface on which to land. (3) Amenthes Fossae Region (proposed by S. N. Huntwork and K. S. Edgett) The Amenthes Fossae are a series of graben/fissures that are circumferential to the southeast side of Isidis Planitia. These fissures cross a variety of ancient, heavily cratered Noachian terrain and younger, Hesperian and Amazonian terrain. We focused our search on a region 0-15 N, 250 - 270 W. Elevations are -0.5 to 2 km. Depending upon whether Isidis Planitia was ever a water-rich environment, this region might have been influenced by aqueous sedimentation. Valley networks are common, and they drained toward the north and northwest. We focused our work on a set of Viking orbiter high-resolution images, 719A 1-48. These have resolutions 16-24 rri/pixel. We examined images 20-23, centered at 2 N, 258 W. This site, on the plains just southwest of a 42 km-diameter crater, includes a valley network channel, a relatively young crater ejecta deposit, a few buttes composed of presumably ancient, Noachian bedrock, and a "plains" unit. The plains might make an ideal landing surface, except for the presence of some fine-scale ridges (oriented approximately N-S). The ridges are probably yardangs, thus this site offers a place where aeolian deflation has probably exposed some of the layered rock units that comprise the "plains". Thermal inertias are 7.9-8.3 x 10(exp -3) cal/sq cm s(exp -0.5) /K and rock abundances are 10-15%. A rover traverse might include the opportunity to go down to the floor (and sample along the walls) of the valley network channel at 2 N 258.1 W.

Published

1998

42. Mars Pathfinder Landing Site Workshop 2: Characteristics of the Ares Vallis Region and Field Trips in the Channeled Scabland, Washington

Author

Golombek, M. P, Edgett, K. S, and Rice, J. W. , Jr

Subjects

Lunar And Planetary Exploration

Abstract

Mars Pathfinder will place a single lander on the surface of Mars on July 4, 1997, following a December 1996 launch. As a result of the very successful first Mars Pathfinder Landing Site Workshop, the project has selected the Ares Vallis outflow channel in Chryse Planitia as the landing site. This location is where a large catastrophic outflow channel debouches into the northern lowlands. A second workshop and series of field trips, entitled Mars Pathfinder Landing Site Workshop 2: Characteristics of the Ares Vallis Region and Field Trips in the Channeled Scabland, Washington, were held in Spokane and Moses Lake, Washington. The purpose of the workshop was to provide a focus for learning as much as possible about the Ares Vallis region on Mars before landing there. The rationale is that the more that can be learned about the general area prior to landing, the better scientists will be able interpret the observations made by the lander and rover and place them in the proper geologic context. The field trip included overflights and surface investigations of the Channeled Scabland (an Earth analog for the martian catastrophic outflow channels), focusing on areas particularly analogous to Ares Vallis and the landing site. The overflights were essential for placing the enormous erosional and depositional features of the Channeled Scabland into proper three-dimensional context. The field trips were a joint educational outreach activity involving K-12 science educators, Mars Pathfinder scientists and engineers, and interested scientists from the Mars scientific community. Part 1 of the technical report on this workshop includes a description of the Mars Pathfinder mission, abstracts accepted for presentation at the workshop, an introduction to the Channeled Scabland, and field trip guides for the overflight and two field trips. This part, Part 2, includes the program for the workshop, summaries of the workshop technical sessions, a summary of the field trips and ensuing discussions, late abstracts of workshop presentations, reports on the education and public outreach activities carried out by the educators, and a list of the workshop and field trip participants.

Published

1995

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

Abstract

The Sample Analysis at Mars instrument evolved gas analyzer (SAM-EGA) has detected evolved water, H_2, SO_2, H_2S, NO, CO_2, CO, O_2 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 CO_2 (160 ± 248 - 2373 ± 820 μgC_((CO2))/g), and CO (11 ± 3 - 320 ± 130 μgC(CO)/g) suggest organic-C is present in Gale Crater materials. Five samples evolved CO_2 at temperatures consistent with carbonate (0.32± 0.05 - 0.70± 0.1 wt.% CO_3). Evolved NO amounts to 0.002 ± 0.007 - 0.06 ± 0.03 wt.% NO_3. Evolution of O_2 suggests oxychlorine phases (chlorate/perchlorate) (0.05 ± 0.025 - 1.05 ± 0.44wt. % ClO_4) are present while SO_2 evolution indicates the presence of crystalline and/or poorly crystalline Fe- and Mg-sulfate and possibly sulfide. Evolved H_2O (0.9 ± 0.3 - 2.5 ± 1.6 wt.% H_2O) is consistent with the presence of adsorbed water, hydrated salts, interlayer/structural water from phyllosilicates, and possible inclusion water in mineral/amorphous phases. Evolved H_2 and H_2S suggest reduced phases occur despite the presence of oxidized phases (nitrate, oxychlorine, sulfate, carbonate). SAM results coupled with CheMin mineralogical and APXS 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

44. Diagenetic silica enrichment and late-stage groundwater activity in Gale crater, Mars: Silica Enriching Diagenesis, Gale, Mars

Author

Frydenvang, J., Gasda, P. J., Hurowitz, J. A., Grotzinger, J. P., Wiens, R. C., Newsom, H. E., Edgett, K. S., Watkins, J., Bridges, J. C., Maurice, S., Fisk, M. R., Johnson, J. R., Rapin, W., Stein, N. T., Clegg, S. M., Schwenzer, S. P., Bedford, C. C., Edwards, P., Mangold, N., Cousin, A., Anderson, R. B., Payré, V., Vaniman, D., Blake, D. F., Lanza, N. L., Gupta, S., Van Beek, J., Sautter, V., Meslin, P.-Y., Rice, M., Milliken, R., Gellert, R., Thompson, L., Clark, B. C., Sumner, D. Y., Fraeman, A. A., Kinch, K. M., Madsen, M. B., Mitrofanov, I. G., Jun, I., Calef, F., and Vasavada, A. R.

Abstract

Diagenetic silica enrichment in fracture‐associated halos that crosscut lacustrine and unconformably overlying aeolian sedimentary bedrock is observed on the lower north slope of Aeolis Mons in Gale crater, Mars. The diagenetic silica enrichment is colocated with detrital silica enrichment observed in the lacustrine bedrock yet extends into a considerably younger, unconformably draping aeolian sandstone, implying that diagenetic silica enrichment postdates the detrital silica enrichment. A causal connection between the detrital and diagenetic silica enrichment implies that water was present in the subsurface of Gale crater long after deposition of the lacustrine sediments and that it mobilized detrital amorphous silica and precipitated it along fractures in the overlying bedrock. Although absolute timing is uncertain, the observed diagenesis likely represents some of the most recent groundwater activity in Gale crater and suggests that the timescale of potential habitability extended considerably beyond the time that the lacustrine sediments of Aeolis Mons were deposited.

Published

2017

45. Diagenetic silica enrichment and late-stage groundwater activity in Gale crater, Mars

Author

Frydenvang, J., Gasada, P. J., Hurowitz, J. A., Grotzinger, J. P, Wiens, R. C., Newsom, H. E., Edgett, K. S., Watkins, J., Bridges, J. C., Maurice, S, Fisk, M. R., Johnson, J. R., Rapin, W., Stein, N. T., Clegg, S. M., Schwenzer, Susanne, Bedford, Candice, Edwards, P., Mangold, N., Cousin, A., Anderson, R. B., Payre, V., Vaniman, D., Blake, D. F., Lanza, N. L., Gupta, S., Van Beek, J., Sautter, V, Meslin, P.-Y., Rice, M., Milliken, R., Gellert, R., Thompson, L., Clark, B. C., Sumner, D. Y., Fraeman, A. A., Kinch, K. M., Madsen, M. B., Mitrofanov, I. G., Jun, I., Calef, F., Vasavada, A. R., Los Alamos National Laboratory (LANL), Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (UCPH), Stony Brook University [SUNY] (SBU), State University of New York (SUNY), Division of Geological and Planetary Sciences [Pasadena], California Institute of Technology (CALTECH), Department of Earth and Planetary Sciences [Albuquerque] (EPS), The University of New Mexico [Albuquerque], Malin Space Science Systems (MSSS), Department of Physics and Astronomy [Leicester], University of Leicester, 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), College of Earth, Ocean and Atmospheric Sciences [Corvallis] (CEOAS), Oregon State University (OSU), Johns Hopkins University Applied Physics Laboratory [Laurel, MD] (APL), The Open University Business School [Milton Keynes], The Open University [Milton Keynes] (OU), Laboratoire de Planétologie et Géodynamique [UMR 6112] (LPG), Université d'Angers (UA)-Université de Nantes - UFR des Sciences et des Techniques (UN UFR ST), Université de Nantes (UN)-Université de Nantes (UN)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS), United States Geological Survey (USGS), GeoRessources, Institut national des sciences de l'Univers (INSU - CNRS)-Centre de recherches sur la géologie des matières premières minérales et énergétiques (CREGU)-Université de Lorraine (UL)-Centre National de la Recherche Scientifique (CNRS), Planetary Science Institute [Tucson] (PSI), NASA Ames Research Center (ARC), Department of Earth Science and Engineering [Imperial College London], Imperial College London, Institut de minéralogie, de physique des matériaux et de cosmochimie (IMPMC), Muséum national d'Histoire naturelle (MNHN)-Université Pierre et Marie Curie - Paris 6 (UPMC)-Institut de recherche pour le développement [IRD] : UR206-Centre National de la Recherche Scientifique (CNRS), Western Washington University (WWU), Department of Geological Sciences [Providence], Brown University, Department of Physics [Guelph], University of Guelph, University of New Brunswick (UNB), Space Science Institute [Boulder] (SSI), Department of Earth and Planetary Sciences [Univ California Davis] (EPS - UC Davis), University of California [Davis] (UC Davis), University of California (UC)-University of California (UC), Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Space Research Institute of the Russian Academy of Sciences (IKI), Russian Academy of Sciences [Moscow] (RAS), NASA MSL, Villum Fonden, Det Frie Forskningsrad (DFF), UKSA, UK Research & Innovation (UKRI)Science & Technology Facilities Council (STFC), and UK Space Agency

Subjects

[SDU]Sciences of the Universe [physics], Mars, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, Silica, MSL, Gale crater, Groundwater, Diagenesis

Abstract

International audience; Diagenetic silica enrichment in fracture-associated halos that crosscut lacustrine and unconformably overlying aeolian sedimentary bedrock is observed on the lower north slope of Aeolis Mons in Gale crater, Mars. The diagenetic silica enrichment is colocated with detrital silica enrichment observed in the lacustrine bedrock yet extends into a considerably younger, unconformably draping aeolian sandstone, implying that diagenetic silica enrichment postdates the detrital silica enrichment. A causal connection between the detrital and diagenetic silica enrichment implies that water was present in the subsurface of Gale crater long after deposition of the lacustrine sediments and that it mobilized detrital amorphous silica and precipitated it along fractures in the overlying bedrock. Although absolute timing is uncertain, the observed diagenesis likely represents some of the most recent groundwater activity in Gale crater and suggests that the timescale of potential habitability extended considerably beyond the time that the lacustrine sediments of Aeolis Mons were deposited.

Published

2017

46. Deucalionis Regio, Mars: Evidence for a unique mineralogic endmember and a crusted surface

Author

Merenyi, E, Edgett, K. S, and Singer, R. B

Subjects

Lunar And Planetary Exploration

Abstract

A small equatorial region south of Sinus Meridiani, Deucalionis Regio, has been found spectrally distinct from other regions as seen in a high spectral resolution telescopic image of the meridian hemisphere of Mars. Analysis of Viking IRTM and other related data suggest that Deucalionis Regio has a crusted surface. The crust-bonding minerals may contribute to the spectral uniqueness of this region. Two independent analyses of spectral images, linear spectral mixing and supervised classification based on the spectral shapes, showed that in addition to the well-known spectral endmember regions in this image (western Arabia, south Acidalia, and Sinus Meridiani), Deucalionis Regio has spectral properties that are unique enough to make it a principle endmember unit. In those earlier works, Deucalionis Regio was referred to as 'Meridiani Border.' Analysis of thermal inertia, rock abundance, and albedo information derived from Viking images and Infrared Thermal Mapper (IRTM) data obtained 1977-80 also indicate that Deucalionis Regio has a surface of distinctly different physical properties when compared to Arabia, Sinus Meridiani, and Acidalia. Deucalionis Regio has a thermal inertia equivalent to the Martian average, a low rock abundance (less than 5 percent), and an intermediate albedo and color. Considerable effort by previous investigators has revealed a consistent model for the surface (upper few cm) properties of the endmember reigons Arabia, Sinus Meridiani, and Acidalia. Compared with these regions, we consider that Deucalionis Regio is not a region of either (1) unconsolidated, fine bright dust like Arabia, (2) considerable windblown unconsolidated sand like Sinus Meridiani, or (3) a rocky-and-sandy surface like Acidalia. Thus, we are forced to consider that either the surface of Deucalionis Regio is made of unconsolidated fine to medium sand (about 250 microns) of an unusual and previously unreported color and albedo, or that the surface is crusted, fine-grained weathered soil, and the thermal inertia is an indicator of the degree to which the surface sediments have become indurated. We favor the latter.

Published

1993

47. Regional sedimentological variations among dark crater floor features: Toward a model for modern eolian sand distribution on Mars

Author

Edgett, K. S and Christensen, P. R

Subjects

Lunar And Planetary Exploration

Abstract

It has been known since 1972 that many Martian craters have dark features on their floors, and that when seen at higher image resolution, some of the dark units are dune fields. Interpretations of thermal inertia derived from Viking Infrared Thermal Mapper (IRTM) data have been used to suggest that many dark intracrater features, including those where dunes are not observed in images, contain some amount of sand or particles in the range 0.1-10 mm. However, it has never been known if all these dark features consist of dunes. We assembled a set of 108 carefully constrained Viking IRTM observations for dark crater-floor units. The data and selection criteria are described in detail elsewhere. Studied in conjunction with Mariner 9 and Viking orbiter images of each crater, these data indicate that the dark crater-floor units in some regions have different thermal properties than those in other regions. Thermal inertias were computed using the Viking thermal model of H. H. Kieffer and corrected for atmospheric CO2 effects using the relationship for a dust-free atmosphere shown by Haberle and Jakosky.

Published

1993

48. The ejecta deposit of the ancient basin Herschel - An example of a generally unrecognized Martian sedimentological unit

Author

Edgett, K. S

Subjects

Lunar And Planetary Exploration

Abstract

This paper discusses geomorphic features of Martian impact basins and of the basin ejecta landforms, with special attention given to the Hershel Basin (14 deg S, 230 deg W; 300-km diam) and its interior and exterior landforms. A map of geomorphic features in and around Hershel Basin is presented together with data on the basin's areal densities. It is estimated that the impact that formed Herschel Basin occurred during the Late Noachian Epoch upon an already heavily cratered Middle Noachian surface.

Published

1991

49. Chemistry, mineralogy, and grain properties at Namib and High dunes, Bagnold dune field, Gale crater, Mars: A synthesis of Curiosity rover observations

Author

Ehlmann, B. L., primary, Edgett, K. S., additional, Sutter, B., additional, Achilles, C. N., additional, Litvak, M. L., additional, Lapotre, M. G. A., additional, Sullivan, R., additional, Fraeman, A. A., additional, Arvidson, R. E., additional, Blake, D. F., additional, Bridges, N. T., additional, Conrad, P. G., additional, Cousin, A., additional, Downs, R. T., additional, Gabriel, T. S. J., additional, Gellert, R., additional, Hamilton, V. E., additional, Hardgrove, C., additional, Johnson, J. R., additional, Kuhn, S., additional, Mahaffy, P. R., additional, Maurice, S., additional, McHenry, M., additional, Meslin, P.‐Y., additional, Ming, D. W., additional, Minitti, M. E., additional, Morookian, J. M., additional, Morris, R. V., additional, O'Connell‐Cooper, C. D., additional, Pinet, P. C., additional, Rowland, S. K., additional, Schröder, S., additional, Siebach, K. L., additional, Stein, N. T., additional, Thompson, L. M., additional, Vaniman, D. T., additional, Vasavada, A. R., additional, Wellington, D. F., additional, Wiens, R. C., additional, and Yen, A. S., additional

Published

2017

50. Diagenetic origin of nodules in the Sheepbed member, Yellowknife Bay formation, Gale crater, Mars

Author

Stack, K. M., Grotzinger, J. P., Kah, L. C., Schmidt, M. E., Mangold, N., Edgett, K. S., Sumner, D. Y., Siebach, K. L., Nachon, M., Lee, R., Blaney, D. L., Deflores, L. P., Edgar, L. A., Fairén, A. G., Leshin, L. A., Maurice, S., Oehler, D. Z., Rice, M. S., and Wiens, R. C.

Abstract

The Sheepbed member of the Yellowknife Bay formation in Gale crater contains millimeter‐scale nodules that represent an array of morphologies unlike those previously observed in sedimentary deposits on Mars. Three types of nodules have been identified in the Sheepbed member in order of decreasing abundance: solid nodules, hollow nodules, and filled nodules, a variant of hollow nodules whose voids have been filled with sulfate minerals. This study uses Mast Camera (Mastcam) and Mars Hand Lens Imager (MAHLI) images from the Mars Science Laboratory Curiosity rover to determine the size, shape, and spatial distribution of the Sheepbed nodules. The Alpha Particle X‐Ray Spectrometer (APXS) and ChemCam instruments provide geochemical data to help interpret nodule origins. Based on their physical characteristics, spatial distribution, and composition, the nodules are interpreted as concretions formed during early diagenesis. Several hypotheses are considered for hollow nodule formation including origins as primary or secondary voids. The occurrence of concretions interpreted in the Sheepbed mudstone and in several other sedimentary sequences on Mars suggests that active groundwater systems play an important role in the diagenesis of Martian sedimentary rocks. When concretions are formed during early diagenetic cementation, as interpreted for the Sheepbed nodules, they have the potential to create a taphonomic window favorable for the preservation of Martian organics.

Published

2014