Global distribution of near‐surface hydrogen on Mars

Feldman, W. C.; Prettyman, T. H.; Maurice, S.; Plaut, J. J.; Bish, David L.; Vaniman, D. T.; Mellon, M. T.; Metzger, A. E.; Squyres, S. W.; Karunatillake, S.; Boynton, W. V.; Elphic, R. C.; Funsten, H. O.; Lawrence, D. J.; Tokar, R. L.

doi:10.1029/2003je002160

Cited by 457 publications

(364 citation statements)

References 46 publications

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“…Larger polygons, however, are also formed in material with lower ice content (Lachenbruch, 1966) as was discussed for the terrestrial polygons (Table 1). No clear relationship between polygon dimension and ground-ice content, which increases with latitude (e.g., Feldman et al, 2004), could be observed on Mars (Mangold et al, 2004;Mangold, 2005;Levy et al, 2009a). The size of the upland polygons (UP1) is consistent with the findings of the Gamma Ray Spectrometer (GRS) that only~4 tõ 10 wt.% water-ice equivalent exists currently in the upper surface layer (b1 m depth) in the regions between 45°S and 45°N Mitrofanov et al, 2002;Feldman et al, 2004).…”

Section: Genesis Of Mars Polygons and Environmental Implicationssupporting

confidence: 72%

“…No clear relationship between polygon dimension and ground-ice content, which increases with latitude (e.g., Feldman et al, 2004), could be observed on Mars (Mangold et al, 2004;Mangold, 2005;Levy et al, 2009a). The size of the upland polygons (UP1) is consistent with the findings of the Gamma Ray Spectrometer (GRS) that only~4 tõ 10 wt.% water-ice equivalent exists currently in the upper surface layer (b1 m depth) in the regions between 45°S and 45°N Mitrofanov et al, 2002;Feldman et al, 2004). If higher ground-ice contents than in the upper layer occur deeper than 1 m, which was inferred from the dimension of the scalloped depressions (Morgenstern et al, 2007;Ulrich et al, 2010), seasonal thermal waves should not reach this depth at the present time (Mellon, 1997;Mangold et al, 2004).…”

Section: Genesis Of Mars Polygons and Environmental Implicationsmentioning

confidence: 99%

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Polygon pattern geomorphometry on Svalbard (Norway) and western Utopia Planitia (Mars) using high-resolution stereo remote-sensing data

et al. 2011

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Polygonal systems formed by thermal contraction cracking are complex landscape features widespread in terrestrial periglacial regions. The manner in which cracking occurs is controlled by various environmental factors and determines dimension, shape, and orientation of polygons. Analogous small-scale features are ubiquitous in Martian mid-and high-latitudes, and they are also inferred to originate from thermal contraction cracking. We studied the geomorphometry of polygonally-patterned ground on Svalbard to draw a terrestrial analogy to small-scale polygonal structures in scalloped terrain in Martian mid-latitudes. We performed a comparative quantitative terrain analysis based on high-resolution stereo remote-sensing data (HRSC-AX and HiRISE) in combination with terrestrial field data and multivariate statistics to determine the relationship of polygon geomorphometry to local environmental conditions. Results show that polygonal structures on Svalbard and in Utopia Planitia on Mars are similar with respect to their size and shape. A comparable thermal contraction cracking genesis is likely. Polygon evolution, however, is strongly related to regional and local landscape dynamics. Individual polygon dimensions and orthogonality vary according to age, thermal contraction cracking activity, and local subsurface conditions. Based on these findings, the effects of specific past and current environmental conditions on polygon formation on Mars must be considered. On both Earth and Mars, the smallest polygons represent young, recently-active low-centered polygons that formed in fine-grained ice-rich material. Small, low-centered Martian polygons show the closest analogy to terrestrial low-centered ice-wedge polygons. The formation of composite wedges could have occurred as a result of local geomorphological conditions during past Martian orbital configurations. Larger polygons reflect past climate conditions on both Earth and Mars. The present degradation of these polygons depends on relief and topographical situation. On Svalbard the thawing of ice wedges degrades high-centered polygons; in contrast, the present appearance of polygons in Utopia Planitia is primarily the result of contemporary dry degradation processes.

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Section: Genesis Of Mars Polygons and Environmental Implicationssupporting

confidence: 72%

Section: Genesis Of Mars Polygons and Environmental Implicationsmentioning

confidence: 99%

Polygon pattern geomorphometry on Svalbard (Norway) and western Utopia Planitia (Mars) using high-resolution stereo remote-sensing data

et al. 2011

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“…Gamma Ray Spectrometer and Neutron Spectrometer (GRS/NS) observations of regolith at latitudes N50-60°show substantial amounts of water ice within a few tens of centimeters of the surface (Boynton et al, 2002;Feldman et al, 2004). The soils may therefore have had a degree of cohesion from ice cement holding the grains together, resulting in little mobile sediment available for transport by the wind.…”

Section: Sediment Source and Spatial Distributionmentioning

confidence: 99%

Transverse Aeolian Ridges (TARs) on Mars

et al. 2008

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Aeolian processes are probably the dominant ongoing surface process on Mars; Large Dark Dunes (LDDs), particularly common aeolian landforms, were first recognized in the early 1970s. Recent, higher resolution images have revealed another, morphologically distinct, large population of smaller, ripple-like aeolian bedforms that have been termed "Transverse Aeolian Ridges" (TARs) as it is unknown whether they formed as large ripples or small dunes. We have begun a new study of TARs that examines their distribution, orientation, and morphology using N 10,000 high-resolution Mars Orbiter Camera (1.5 to 8 m/pixel resolution) images in a 45°longitude wide, pole-to-pole survey. The aim of this study is to assess whether TARs are active, to identify possible sediment sources and pathways, and to determine the volumes of sediment that they comprise. We present results from the first half of this study, in which we examine the northern hemisphere, and describe a new three-part classification scheme used to aid the survey. Our results show that TARs are abundant but not ubiquitous: preferentially forming proximal to friable, layered terrains such as those found in Terra Meridiani -the location of the ongoing Mars Exploration Rover "Opportunity" mission. TAR distribution in the northern hemisphere shows a strong latitudinal dependence with very few TARs being found north of ∼ 30°N. We also find that in most cases TARs are less mobile than LDDs, a conclusion possibly explained by Mars Exploration Rover Opportunity observations that show TARlike ripples to have a core of fine material armored by a monolayer of granule-sized particles. This could disallow significant bedform movement under the current wind regime. That TARs are essentially inactive is confirmed by superposition relations with slope streaks and LDDs and by observations of superposed impact craters. We suggest that observations made by the Opportunity Rover in Terra Meridiani indicate that the small aeolian bedforms common here are ripples and not small dunes. Farther south, these bedforms transition into larger features indistinguishable from TARs, suggesting that TARs (in the Meridiani area at least) are ripples and not dunes.

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“…3,4 These discoveries have reignited the concept of making methane on Mars for propulsion with oxygen. Previously, the biggest drawback to the methane option was the need to bring hydrogen from Earth, which is difficult to store and transport due to its low density and liquefaction temperature.…”

Section: Introductionmentioning

confidence: 99%

Mars Surface Mobility Leading to Sustainable Exploration

Linne

Barsi

et al. 2012

50th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition

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A Mars rocket-propelled hopper concept was evaluated for feasibility through analysis and experiments. The approach set forth in this paper is to combine the use of in-situ resources in a new Mars mobility concept that will greatly enhance the science return while providing the first opportunity towards reducing the risk of incorporating ISRU into the critical path for the highly coveted, but currently unaffordable, sample return mission. Experimental tests were performed on a high-pressure, self-throttling gaseous oxygen/methane propulsion system to simulate a two-burn-with-coast hop profile. Analysis of the trajectory, production plant requirements, and vehicle mass indicates that a small hopper vehicle could hop 2 km every 30 days with an initial mass of less than 60 kg. A larger vehicle can hop 15 km every 30 to 60 days with an initial mass of 300 to 430 kg.= conversion factor u = upstream h = heat transfer coefficient M = Mach number Greek m = mass π = flow coefficient mdot = mass flow rate γ = ratio of specific heats P = pressure µ = dynamic viscosity Pr = Prandtl number σ = heat transfer coefficient correction factor q" = heat flux R = gas constant r = radius of curvature T = temperature

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Global distribution of near‐surface hydrogen on Mars

Cited by 457 publications

References 46 publications

Polygon pattern geomorphometry on Svalbard (Norway) and western Utopia Planitia (Mars) using high-resolution stereo remote-sensing data

Polygon pattern geomorphometry on Svalbard (Norway) and western Utopia Planitia (Mars) using high-resolution stereo remote-sensing data

Transverse Aeolian Ridges (TARs) on Mars

Mars Surface Mobility Leading to Sustainable Exploration

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