Your search keyword '"Newsom, H"' showing total 30 results

1. Fluids During Diagenesis and Sulfate Vein Formation in Sediments at Gale Crater, Mars

Author

Schwenzer, S. P, Bridges, J. C, Weins, R. C, Conrad, P. G, Kelley, S. P, Leveille, R, Mangold, N, Martin-Torres, J, McAdam, A, Newsom, H, Zorzano, M. P, Rapin, W, Spray, J, Treiman, A. H, Westall, F, Fairen, A. G, and Meslin, P.-Y

Subjects

Lunar And Planetary Science And Exploration

Abstract

We model the fluids involved in the alteration processes recorded in the Sheep bed Member mudstones of Yellowknife Bay (YKB), Gale crater, Mars, as revealed by the Mars Science Laboratory Curiosity rover investigations. We compare the Gale crater waters with fluids modeled for shergottites, nakhlites, and the ancient meteorite ALH 84001, as well as rocks analyzed by the Mars Exploration rovers, and with terrestrial ground and surface waters. The aqueous solution present during sediment alteration associated with phyllosilicate formation at Gale was high in Na, K, and Si; had low Mg, Fe, and Al concentrations relative to terrestrial ground waters such as the Deccan Traps and other modeled Mars fluids; and had near neutral to alkaline pH. Ca and S species were present in the 10(exp -3) to 10(exp -2) concentration range. A fluid local to Gale crater strata produced the alteration products observed by Curiosity and subsequent evaporation of this ground water- type fluid formed impure sulfate- and silica-rich deposits veins or horizons. In a second, separate stage of alteration, partial dissolution of this sulfate-rich layer in Yellowknife Bay,or beyond, led to the pure sulfate veins observed in YKB. This scenario is analogous to similar processes identified at a terrestrial site in Triassic sediments with gypsum veins of the Mercia Mudstone Group in Watchet Bay, UK.

Published

2016

2. Calibration of the Fluorine, Chlorine and Hydrogen Content of Apatites With the ChemCam LIBS Instrument

Author

Meslin, P.-Y, Cicutto, L, Forni, O, Drouet, C, Rapin, W, Nachon, M, Cousin, A, Blank, J. G, McCubbin, F. M, Gasnault, O, Newsom, H, Mangold, N, Schroeder, S, Sautter, V, Maurice, S, and Wiens, R. C

Subjects

Lunar And Planetary Science And Exploration

Abstract

Determining the composition of apatites is important to understand the behavior of volatiles during planetary differentiation. Apatite is an ubiquitous magmatic mineral in the SNC meteorites. It is a significant reservoir of halogens in these meteorites and has been used to estimate the halogen budget of Mars. Apatites have been identified in sandstones and pebbles at Gale crater by ChemCam, a Laser-Induced Breakdown Spectroscometer (LIBS) instrument onboard the Curiosity rover. Their presence was inferred from correlations between calcium, fluorine (using the CaF molecular band centered near 603 nm, whose detection limit is much lower that atomic or ionic lines and, in some cases, phosphorus (whose detection limit is much larger). An initial quantification of fluorine, based on fluorite (CaF2)/basalt mixtures and obtained at the LANL laboratory, indicated that the excess of F/Ca (compared to the stoichiometry of pure fluorapatites) found on Mars in some cases could be explained by the presence of fluorite. Chlorine was not detected in these targets, at least above a detection limit of 0.6 wt% estimated from. Fluorapatite was later also detected by X-ray diffraction (with CheMin) at a level of approx.1wt% in the Windjana drill sample (Kimberley area), and several points analyzed by ChemCam in this area also revealed a correlation between Ca and F. The in situ detection of F-rich, Cl-poor apatites contrasts with the Cl-rich, F-poor compositions of apatites found in basaltic shergottites and in gabbroic clasts from the martian meteorite NWA 7034, which were also found to be more Cl-rich than apatites from basalts on Earth, the Moon, or Vesta. The in situ observations could call into question one of the few possible explanations brought forward to explain the SNC results, namely that Mars may be highly depleted in fluorine. The purpose of the present study is to refine the calibration of the F, Cl, OH and P signals measured by the ChemCam LIBS instrument, initiated for F, for Cl in soils, for P, and estimate their limit of detection. For this purpose, different types of apatites and mixtures of basalt powder and apatites were analyzed using ChemCam Engineering Qualification Model (EQM) at IRAP, Toulouse. The present abstract presents the initial results from the laboratory analyses. Differences between the response function of the EQM and the Flight Model of ChemCam are still to be refined to apply these new results to the Martian dataset.

Published

2016

3. Fluorine and Lithium at the Kimberley Outcrop, Gale Crater

Author

Forni, O, Vaniman, D. T, Le Deit, L, Clegg, S. M, Lanza, N. L, Lasue, J, Bish, D. L, Mangold, N, Wiens, R. C, Meslin, P.-Y, Gasnault, O, Maurice, S, Cousin, A, Toplis, M. J, Newsom, H, and Rampe, E. B

Subjects

Lunar And Planetary Science And Exploration

Abstract

ChemCam is an active remote sensing instrument which has operated successfully on MSL since landing in August, 2012. Its laser pulses remove dust and to profile through weathering coatings of rocks up to 7 m away. Laser-induced breakdown spectroscopy (LIBS) produces emission spectra of materials ablated from the samples in electronically excited states. As the plasma cools, elements can recombine and molecular emission lines are observed. Recent experiments have shown that some of these molecular emissions can be much brighter than the associated atomic lines, especially when halo-gens and rare earth elements are present. We observed these molecular emissions in some of the ChemCam spectra and report the first detection of chlorine and fluorine with ChemCam. It is also the first time ever that fluorine has been detected on the surface of Mars. Among all the F-bearing observations, one third are observed in the Kimberley outcrop. We will dis-cuss the potential mineralogies related to these observations as well as the related elemental correlations and propose interpretations.

Published

2015

4. 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

5. Terrain Physical Properties Derived from Orbital Data and the First 360 Sols of Mars Science Laboratory Curiosity Rover Observations in Gale Crater

Author

Arvidson, R. E, Bellutta, P, Calef, F, Fraeman, A. A, Garvin, James B, Gasnault, O, Grant, J. A, Grotzinger, J. P, Hamilton, V. E, Heverly, M, Iagnemma, K. A, Johnson, J. R, Lanza, N, Le Mouelic, S, Mangold, N, Ming, D. W, Mehta, M, Morris, R. V, Newsom, H. E, Renno, N, Rubin, D, Scheiber, J, Sletten, R, Stein, N. T, Thuillier, F, Vasavada, A. R, Vizcaino, J, and Wiens, R. C

Subjects

Lunar And Planetary Science And Exploration

Abstract

Physical properties of terrains encountered by the Curiosity rover during the rst 360 sols of operations have been inferred from analysis of the scour zones produced by Sky Crane Landing System engine plumes, wheel touch down dynamics, pits produced by Chemical Camera (ChemCam) laser shots, rover wheel traverses over rocks, the extent of sinkage into soils, and the magnitude and sign of rover-based slippage during drives. Results have been integrated with morphologic, mineralogic, and thermophysical properties derived from orbital data, and Curiosity-based measurements, to understand the nature and origin of physical properties of traversed terrains. The hummocky plains (HP) landing site and traverse locations consist ofmoderately to well-consolidated bedrock of alluvial origin variably covered by slightly cohesive, hard-packedbasaltic sand and dust, with both embedded and surface-strewn rock clasts. Rock clasts have been addedthrough local bedrock weathering and impact ejecta emplacement and form a pavement-like surface in whichonly small clasts (5 to 10 cm wide) have been pressed into the soil during wheel passages. The beddedfractured (BF) unit, site of Curiositys rst drilling activity, exposes several alluvial-lacustrine bedrock unitswith little to no soil cover and varying degrees of lithication. Small wheel sinkage values (1 cm) for both HPand BF surfaces demonstrate that compaction resistance countering driven-wheel thrust has been minimaland that rover slippage while traversing across horizontal surfaces or going uphill, and skid going downhill,have been dominated by terrain tilts and wheel-surface material shear modulus values.

Published

2014

6. Assessments of Potential Rock Coatings at Rocknest, Gale Crater with ChemCam

Author

Blaney, D. L, Anderson, R, Berger, G, Bridges, J, Bridges, N, Clark, B, Clegg, S, Ehlman, B, Goetz, W, King, P, Lanza, N, Mangold, N, Meslin, P.-Y, and Newsom, H

Subjects

Lunar And Planetary Science And Exploration

Abstract

Many locations on Mars have low color contrast between the rocks and soils due to the rocks being "dusty"--basically having a surface that is spectrally similar to Martian soil. In general this has been interpreted as soil and/or dust clinging to the rock though either mechanical or electrostic processes. However, given the apparent mobility of thin films of water forming cemented soils on Mars and at Gale Crater, the possibility exists that some of these "dusty" surfaces may actually be coatings formed by thin films of water locally mobilizing soil/air fall material at the rock interface. This type of coating was observed by Spirit during an investigation of the rock Mazatzal which showed enhanced salts above "normal soil" and an enhancement of nano phase iron oxide that was ~ 10 micronmeters thick. We decided to use ChemCam to investigate the possibility of similar rock coatings forming at the Rocknest site at Gale Crater.

Published

2013

7. Calibration of the MSL/ChemCam/LIBS Remote Sensing Composition Instrument

Author

Wiens, R. C, Maurice S, Bender, S, Barraclough, B. L, Cousin, A, Forni, O, Ollila, A, Newsom, H, Vaniman, D, Clegg, S, Lasue, J. A, Blaney, D, DeFlores, L, and Morris, R. V

Subjects

Lunar And Planetary Science And Exploration

Abstract

The ChemCam instrument suite on board the 2011 Mars Science Laboratory (MSL) Rover, Curiosity, will provide remote-sensing composition information for rock and soil samples within seven meters of the rover using a laser-induced breakdown spectroscopy (LIBS) system, and will provide context imaging with a resolution of 0.10 mradians using the remote micro-imager (RMI) camera. The high resolution is needed to image the small analysis footprint of the LIBS system, at 0.2-0.6 mm diameter. This fine scale analytical capability will enable remote probing of stratigraphic layers or other small features the size of "blueberries" or smaller. ChemCam is intended for rapid survey analyses within 7 m of the rover, with each measurement taking less than 6 minutes. Repeated laser pulses remove dust coatings and provide depth profiles through weathering layers, allowing detailed investigation of rock varnish features as well as analysis of the underlying pristine rock composition. The LIBS technique uses brief laser pulses greater than 10 MW/square mm to ablate and electrically excite material from the sample of interest. The plasma emits photons with wavelengths characteristic of the elements present in the material, permitting detection and quantification of nearly all elements, including the light elements H, Li, Be, B, C, N, O. ChemCam LIBS projects 14 mJ of 1067 nm photons on target and covers a spectral range of 240-850 nm with resolutions between 0.15 and 0.60 nm FWHM. The Nd:KGW laser is passively cooled and is tuned to provide maximum power output from -10 to 0 C, though it can operate at 20% degraded energy output at room temperature. Preliminary calibrations were carried out on the flight model (FM) in 2008. However, the detectors were replaced in 2009, and final calibrations occurred in April-June, 2010. This presentation describes the LIBS calibration and characterization procedures and results, and details plans for final analyses during rover system thermal testing, planned for early March.

Published

2011

8. Exploring Martian Impact Craters: Why They are Important for the Search for Life

Author

Schwenzer, S. P, Abramov, O, Allen, C. C, Clifford, S, Filiberto, J, Kring, D. A, Lasue, J, McGovern, P. J, Newsom, H. E, Treiman, A. H, Vaniman, D. T, Wiens, R. C, and Wittmann, A

Subjects

Lunar And Planetary Science And Exploration

Abstract

Fluvial features and evidence for aqueous alteration indicate that Mars was wet, at least partially and/or periodically, in the Noachian. Also, impact cratering appears to have been the dominant geological process [1] during that epoch. Thus, investigation of Noachian craters will further our understanding of this geologic process, its effects on the water-bearing Martian crust, and any life that may have been present at the time. Impact events disturbed and heated the water- and/or ice-bearing crust, likely initiated long-lived hydrothermal systems [2-4], and formed crater lakes [5], creating environments suitable for life [6]. Thus, Noachian impact craters are particularly important exploration targets because they provide a window into warm, water-rich environments of the past which were possibly conducive to life. In addition to the presence of lake deposits, assessment of the presence of hydrothermal deposits in the walls, floors and uplifts of craters is important in the search for life on Mars. Impact craters are also important for astrobiological exploration in other ways. For example, smaller craters can be used as natural excavation pits, and so can provide information and samples that would otherwise be inaccessible (e.g., [7]). In addition, larger (> ~75 km) craters can excavate material from a potentially habitable region, even on present-day Mars, located beneath a >5-km deep cryosphere.

Published

2010

9. Inverted Martian Craters in Lineated Glacial Valleys, Ismenius Lacus Region, Mars

Author

McConnell, B. S, Wilt, G. L, Gillespie, A, and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

We studied small, uniquely-shaped craters found on the surface of lineated terrain in the Ismenius Lacus region of Mars. By utilizing MOC and THEMIS satellite images, we located terrain including lineations (viscous flow features), smoothing of topography, and morphologic features such as polygons and gullies, which appear to be strong evidence of preexisting ice deposits.

Published

2005

10. The Martian Soil as a Geochemical Sink for Hydrothermally Altered Crustal Rocks and Mobile Elements: Implications of Early MER Results

Author

Newsom, H. E, Nelson, M. J, Shearer, C. K, and Draper, D. S

Subjects

Lunar And Planetary Science And Exploration

Abstract

Hydrothermal and aqueous alteration can explain some of the exciting results from the MER team s analyses of the martian soil, including the major elements, mobile elements, and the nickel enrichment. Published results from the five lander missions lead to the following conclusions: 1) The soil appears to be globally mixed and basaltic with only small local variations in chemistry. Relative to martian basaltic meteorites and Gusev rocks the soils are depleted in the fluid-mobile element calcium, but only slightly enriched to somewhat depleted in iron oxide. 2) The presence of olivine in the soils based on M ssbauer data argues that the soil is only partly weathered and is more akin to a lunar regolith than a terrestrial soil. 3) The presence of bromine along with sulfur and chlorine in the soils is consistent with addition of a mobile element component to the soil.

Published

2005

11. Hydrothermal Processes and Mobile Element Transport in Martian Impact Craters - Evidence from Terrestrial Analogue Craters

Author

Newsom, H. E, Nelson, M. J, Shearer, C. K, and Dressler, B. L

Subjects

Lunar And Planetary Science And Exploration

Abstract

Hydrothermal alteration and chemical transport involving impact craters probably occurred on Mars throughout its history. Our studies of alteration products and mobile element transport in ejecta blanket and drill core samples from impact craters show that these processes may have contributed to the surface composition of Mars. Recent work on the Chicxulub Yaxcopoil-1 drill core has provided important information on the relative mobility of many elements that may be relevant to Mars. The Chicxulub impact structure in the Yucatan Peninsula of Mexico and offshore in the Gulf of Mexico is one of the largest impact craters identified on the Earth, has a diameter of 180-200 km, and is associated with the mass extinctions at the K/T boundary. The Yax-1 hole was drilled in 2001 and 2002 on the Yaxcopoil hacienda near Merida on the Yucatan Peninsula. Yax-1 is located just outside of the transient cavity, which explains some of the unusual characteristics of the core stratigraphy. No typical impact melt sheet was encountered in the hole and most of the Yax-1 impactites are breccias. In particular, the impact melt and breccias are only 100 m thick which is surprising taking into account the considerably thicker breccia accumulations towards the center of the structure and farther outside the transient crater encountered by other drill holes.

Published

2005

12. Hydrothermal Alteration at Lonar Crater, India and Elemental Variations in Impact Crater Clays

Author

Newsom, H. E, Nelson, M. J, Shearer, C. K, Misra, S, and Narasimham, V

Subjects

Lunar And Planetary Science And Exploration

Abstract

The role of hydrothermal alteration and chemical transport involving impact craters could have occurred on Mars, the poles of Mercury and the Moon, and other small bodies. We are studying terrestrial craters of various sizes in different environments to better understand aqueous alteration and chemical transport processes. The Lonar crater in India (1.8 km diameter) is particularly interesting being the only impact crater in basalt. In January of 2004, during fieldwork in the ejecta blanket around the rim of the Lonar crater we discovered alteration zones not previously described at this crater. The alteration of the ejecta blanket could represent evidence of localized hydrothermal activity. Such activity is consistent with the presence of large amounts of impact melt in the ejecta blanket. Map of one area on the north rim of the crater containing highly altered zones at least 3 m deep is shown.

Published

2005

13. Major and Trace Element Variations in Impact Crater Clay from Chicxulub, Lonar, and Mistastin, Implications for the Martian Soil

Author

Newsom, H. E, Nelson, M. J, Shearer, C. K, Rietmeijer, F. J. M, Gakin, R, and Lee, K

Subjects

Lunar And Planetary Science And Exploration

Abstract

The catastrophic Chicxulub event should have generated a large hydrothermal system with volatile element mobilization, producing interesting alteration materials and clays. The Yaxcopoil-1 (YAX) drill hole is located in the annular trough, about 70 km southwest of the crater center, in an area where the impactite layers are relatively thin (approx. 100 m thick). We have analyzed samples from the YAX drill core and from other impact craters including Mistastin and Lonar to determine the nature of alteration and trace element mobilization.

Published

2004

14. Volatile Behavior in Lunar and Terrestrial Basalts During Shock: Implications for Martian Magmas

Author

Chaklader, Johny, Shearer, C. K, Hoerz, F, and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The amount of water in martian magmas has significant ramifications for the martian atmosphere-hydrosphere cycle. Large D-enrichments have been observed in kaersutitic amphiboles in Zagami, Chassigny and Shergotty meteorites (delta-D values up to 4400 per mil) suggesting that substantial amounts of H escaped Mars in its past. Furthermore, martian meteorites with inclusions of biotite and apatite imply possible origins in a hydrous mantle. However, whether martian magmas ever possessed considerable proportions of water remains controversial and unclear. The H-content of mica and amphibole melt inclusions has been found to be low, while bulk-rock H2O content is also low ranging from 0.013 to 0.035 wt. % in Shergotty. Hydrous martian magmas were considered responsible for light lithophile element (LLE) zoning patterns observed in Nakhlite and Shergottite pyroxenes. Since LLEs, such as Li and B, partition into aqueous fluids at temperatures greater than 350 C, workers interpreted Li-B depletions in pyroxene rims as evidence that supercritical fluid exsolution occurred during magma degassing. In that many martian basalts experienced substantial shock (15-45 GPa) it is possible that the magmatic volatile record preserved in martian basalts has been disturbed. Previous shock experiments suggest that shock processes may effect water content and H/D. To better understand the possible effects of shock on this volatile record, we are studying the redistribution of volatile elements in naturally and experimentally shocked basalts. Here, we report the initial results from shocked basalts associated with the Lonar Crater, India and an experimentally shocked lunar basalt.

Published

2004

15. Evidence for an 800 km Diameter Impact Structure in Meridiani Planum and Associated Channels and Basins: A Connection with the Origin of the Hematite Deposits?

Author

Newsom, H. E, Barber, C. A, Schelble, R. T, Hare, T. M, Feldman, W. C, Sutherland, V, Gordon, H, Thorsos, I. E, Livingston, A, and Lewis, K

Subjects

Lunar And Planetary Science And Exploration

Abstract

Topographic evidence for the existence of an early 800 km diameter multi-ringed impact structure, and evidence for fluvial and lacustrine environments in Meridiani Planum suggests a connection with the origin of the hematite deposits present in the region.

Published

2003

16. Can Low Water/Rock Hydrothermal Alteration of Impact Materials Explain the Rock Component of the Martian Soil?

Author

Nelson, M. J and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The martian regolith is a globally homogenized product of chemical and aeolian weathering processes. The soil is thought to consist of a rock component, with lesser amounts of mobile elements (Ca, Na, and K) than a presumed protolith, and a salt or mobile element component enriched in sulfur and chlorine. In this study we consider the contributions of hydrothermal processes to the origin of the rock component of the martian soil.

Published

2003

17. Examining Topography of Mars Impact Basins to Determine If Impact Basins Have Topographic Characteristics of a Crater

Author

Livingston, A, Lewis, K, Simmons, J, Chavez, D, Gchachu, K, Newsom, H. E, Sutherland, V, Gordon, H, and Hare, T. M

Subjects

Lunar And Planetary Science And Exploration

Abstract

Determining the topography of suspect craters on Mars will help scientists better understand the land deformation that occurs from an asteroid or comet impact. This will provide a better understanding of how Mars has changed over time and the topography data could be used for planning future missions to Mars. We have begun a program at the Southwestern Indian Polytechnic Institute (SIPI), a Bureau of Indian Affairs junior college, to analyze large impact basins on Mars (>300 km diameter) utilizing Geographic Information System (GIS) technology. Collaborators at the University of New Mexico and the U.S. Geological Survey are providing technical support for this effort.

Published

2003

18. Impact Hydrothermal Alteration of Terrestrial Basalts: Explaining the Rock Component of the Martian Soil

Author

Nelson, M. J and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The large energy in terrestrial impacts can create hydrothermal systems and consequently produce hydrothermal alteration materials. In this study we consider the chemistry of impact and volcanic hydrothermal alteration under relatively low water/rock ratios in basaltic or a somewhat more evolved protolith. Our work on the Lonar and Mistastin craters suggests that Fe-rich clays, including Fe-rich saponite can be produced. We postulate that similar alteration materials are produced on Mars and could be a component of the martian soil or regolith, contrary to some earlier studies. The martian regolith is a globally homogenized product of various weathering processes. The soil [1] is thought to consist of a rock component, with lesser amounts of mobile elements (Ca, Na, and K) than a presumed protolith, and a salt or mobile element component enriched in sulfur and chlorine [2, 3]. In this study we consider the contributions of impacts and consequent hydrothermal processes to the rock component of the martian soil.

Published

2003

19. Development of a Digital Meteorite Identification Program at University of New Mexico (UNM) (Institute of Meteoritics) and Southwestern Indian Polytechnic Institute (SIPI)

Author

Gakin, R, Lewis, K, Simmons, J, Gchachu, K, Karner, J. M, Newsom, H. E, and Jones, R. H

Subjects

Lunar And Planetary Science And Exploration

Abstract

Determining the origin and chemical composition of suspect extra terrestrial specimens has lead to meteorite identification research programs. Such programs, like the University of New Mexico-Southwestern Indian Polytechnic Institute partnership, are being inundated with many non-meteorites (meteor wrongs) sent in by interested individuals from all over the world. This meteorite identification program developed a spreadsheet that aids in identifying the types of minerals in a sample for physical properties, possible meteorite characteristics, minerals and rock properties, and possible man made characteristics. Samples that show meteorite distinctiveness are further analyzed via the Scanning Electron Microprobe (SEM).

Published

2003

20. Impact-induced Hydrothermal Systems and Mineral Deposition on Mars

Author

Thorsos, I. E, Newsom, H. E, and Davies, A. G

Subjects

Lunar And Planetary Science And Exploration

Abstract

Modeling of hydrothermal circulation at impact craters on Mars to determine system duration and potential mineral deposition in the context of Mars exploration. Additional information is contained in the original extended abstract.

Published

2002

21. Meteorite Identification: A Partnership Opportunity

Author

Karner, J. M, Newsom, H. E, Jones, R. H, Simmons, J, Garcia, T, Livingston, D, and Townend, B

Subjects

Lunar And Planetary Science And Exploration

Abstract

We have begun a partnership between the Institute of Meteoritics at the University of New Mexico and the Southwestern Indian Polytechnic Institute (SIPI) to involve SIPI students in the identification and characterization of samples provided by the general public as possible meteorites. Additional information is contained in the original extended abstract.

Published

2002

22. Crater Deposits in 2003 MER Landing Sites

Author

Newsom, H. E, Barber, C. A, and Thorsos, I. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

At the Mars Exploration Rover Hematite landing site, impact melt and lake deposits from a 140 km diameter crater have been excavated by an 18 km diameter crater and probably deposited at the surface of the landing site ellipse. Crater deposits may also be present in the Gusev and Isidis landing sites. Additional information is contained in the original extended abstract.

Published

2002

23. Mobile Element Reservoir Mass Balance on Mars: New SIMS and EMP Data from Lonar and Mistastin Craters

Author

Newsom, H. E, Hagerty, J. J, and Shearer, C. W

Subjects

Lunar And Planetary Science And Exploration

Abstract

New SIMS data for mobile elements in Lonar Crater clay minerals are remarkably similar to data for alteration material in the Lafayette Mars meteorite. This work strongly supports the use of terrestrial analogues for Mars, including a new mass balance model for mobile elements through time. Additional information is contained in the original extended abstract.

Published

2002

24. Availability of Heat to Drive Hydrothermal Systems in Large Martian Impact Craters

Author

Thorsos, I. E, Newsom, H. E, and Davies, A. G

Subjects

Lunar And Planetary Science And Exploration

Abstract

The central uplift in large craters on Mars can provide a substantial source of heat, equivalent to heat produced by the impact melt sheet. The heat generated in large impacts could play a significant role in hydrothermal systems on Mars. Additional information is contained in the original extended abstract.

Published

2001

25. New Evidence for Impact-induced Hydrothermal Alteration at the Lunar Crater, India: Implications for the Effect of Small Craters on the Mineralogical and Chemical Composition of the Martian Regolith

Author

Hagerty, J and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The Lunar crater has several unique characteristics that make it a valid analogue for similar craters on Mars. We have characterized the secondary alteration assemblage at Lunar in order to make implications for martian alteration materials. Additional information is contained in the original extended abstract.

Published

2001

26. Central Remnant Craters on Mars - Localization of Hydrothermal Alteration at the Edge of Crater Floors?

Author

Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

Localized erosion at the edge of crater floors may be caused by hydrothermal alteration due to focusing of fluid flow around an impact melt sheet following crater formation, coupled with hydrothermal self-sealing under the center of the crater. Additional information is contained in the original extended abstract.

Published

2001

27. The Search for Life on Mars in Surface Samples: Lessons from the 1999 Marsokhod Field Test

Author

Newsom, H. E, Bishop, J. L, Cockell, C, Roush, T, and Johnson, J. R

Subjects

Lunar And Planetary Science And Exploration

Abstract

A rock with possible cryptoendolithic organisms was identified on the basis of a green tinge and textural information, which was confirmed by the identification of chlorophyll visible/NIR spectra.

Published

2000

28. Addressing the Misconceptions of Middle School Students About Becoming a Scientist or Engineer

Author

Newsom, H. E, Sorge, C, and Hagerty, J. J

Subjects

Lunar And Planetary Science And Exploration

Abstract

Assessment of our educational outreach program shows that students and their parents are excited about space science, but stereotypes about science and scientists drastically effect student attitudes about science and pursuing a technical career.

Published

2000

29. Geological Characterization of Remote Field Sites Using Visible and Infrared Spectroscopy: Results from the 1999 Marsokhod Field Test

Author

Johnson, J. R, Ruff, S. W, Moersch, J, Roush, T, Horton, K, Bishop, J, Cabrol, N. A, Cockell, C, Gazis, P, and Newsom, H. E

Subjects

Lunar And Planetary Science And Exploration

Abstract

The 1999 Marsokhod Field Experiment (MFE) provided an opportunity to test the suitability of rover-borne visible/near-infrared and thermal infrared field spectrometers to contribute to the remote geological exploration of a Mars analog field site.

Published

2000

30. Introduction to special section: early Mars

Author

Clifford, S, Treiman, A, Newsom, H, and Farmer, J

Subjects

Lunar And Planetary Science And Exploration

Abstract

Ongoing studies of the evolution of the Martian cratered highlands, the nature of the planet's early climate, and the recent announcement of possible evidence of ancient life in the ALH 84001 meteorite have reinvigorated interest in the conditions that prevailed on Mars during its first billion years of geologic history. To address this interest and assess our current understanding of these issues, the Lunar and Planetary Institute hosted a 4-day Conference on Early Mars in Houston in April of 1997. The papers contained in this special section are a product of that meeting. The purpose of the conference was twofold: (1) to consider how impacts, volcanism, and the presence of abundant water affected the physical and chemical environment that existed on Mars 4 Gyr ago, particularly as it related to the nature of the global climate, the origin of the valley networks, the geologic and mineralogic evolution of the surface, the aqueous geochemistry of groundwater, and the existence of local environments that may have been conducive to the development of indigenous life and the preservation of its signature in the geologic record; and (2) to discuss what observations or experiments might he included in future spacecraft missions to test the ideas and expectations arising from purpose 1. While pertinent issues of early atmospheric and solar evolution were also addressed, the primary discussion at the conference focused on the evidence and constraints provided by the geologic records of Earth, the Moon, and Mars and analysis of the SNC meteorites. The papers contained in this special section span the full range of these topics, including the stability of the early atmosphere to erosion by the solar wind, the geologic environment from which the SNC meteorites originated, geomorphic evidence regarding the nature of the early Martian climate and hydrologic cycle, the potential impact of the past and present environment on the preserved signature of ancient life, and a discussion of the capabilities of a lander-based X ray diffraction and fluorescence instrument to assess the potential for past fossilization from the mineralogy of the current local surface environment. The issues raised at the conference, and by the papers included in this special section, will be the focus of ongoing attention as the intensity and scope of Mars exploration increases over the next decade.

Published

1998