S. W. Squyres
Cornell University
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Featured researches published by S. W. Squyres.
Science | 2014
John P. Grotzinger; Dawn Y. Sumner; L. C. Kah; K. Stack; S. Gupta; Lauren A. Edgar; David M. Rubin; Kevin W. Lewis; Juergen Schieber; N. Mangold; Ralph E. Milliken; P. G. Conrad; David J. DesMarais; Jack D. Farmer; K. L. Siebach; F. Calef; Joel A. Hurowitz; Scott M. McLennan; D. Ming; D. T. Vaniman; Joy A. Crisp; Ashwin R. Vasavada; Kenneth S. Edgett; M. C. Malin; D. Blake; R. Gellert; Paul R. Mahaffy; Roger C. Wiens; Sylvestre Maurice; J. A. Grant
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.
Science | 2004
R. Rieder; Ralf Gellert; Robert C. Anderson; J. Brückner; B. C. Clark; G. Dreibus; T. Economou; G. Klingelhöfer; Guenter W. Lugmair; D. W. Ming; S. W. Squyres; C. d'Uston; H. Wänke; Albert S. Yen; Jutta Zipfel
The Alpha Particle X-ray Spectrometer on the Opportunity rover determined major and minor elements of soils and rocks in Meridiani Planum. Chemical compositions differentiate between basaltic rocks, evaporite-rich rocks, basaltic soils, and hematite-rich soils. Although soils are compositionally similar to those at previous landing sites, differences in iron and some minor element concentrations signify the addition of local components. Rocky outcrops are rich in sulfur and variably enriched in bromine relative to chlorine. The interaction with water in the past is indicated by the chemical features in rocks and soils at this site.
Science | 2004
Philip R. Christensen; Michael Bruce Wyatt; Timothy D. Glotch; A. D. Rogers; Saadat Anwar; Raymond E. Arvidson; Joshua L. Bandfield; Diana L. Blaney; Charles John Budney; Wendy M. Calvin; A. Fallacaro; R. L. Fergason; Noel Gorelick; T. G. Graff; Victoria E. Hamilton; Alexander G. Hayes; James Richard Johnson; Amy T. Knudson; Harry Y. McSween; Greg L. Mehall; L. K. Mehall; Jeffrey Edward Moersch; Richard V. Morris; M. D. Smith; S. W. Squyres; Steven W. Ruff; M. J. Wolff
The Miniature Thermal Emission Spectrometer (Mini-TES) on Opportunity investigated the mineral abundances and compositions of outcrops, rocks, and soils at Meridiani Planum. Coarse crystalline hematite and olivine-rich basaltic sands were observed as predicted from orbital TES spectroscopy. Outcrops of aqueous origin are composed of 15 to 35% by volume magnesium and calcium sulfates [a high-silica component modeled as a combination of glass, feldspar, and sheet silicates (∼20 to 30%)], and hematite; only minor jarosite is identified in Mini-TES spectra. Mini-TES spectra show only a hematite signature in the millimeter-sized spherules. Basaltic materials have more plagioclase than pyroxene, contain olivine, and are similar in inferred mineral composition to basalt mapped from orbit. Bounce rock is dominated by clinopyroxene and is close in inferred mineral composition to the basaltic martian meteorites. Bright wind streak material matches global dust. Waterlain rocks covered by unaltered basaltic sands suggest a change from an aqueous environment to one dominated by physical weathering.
Science | 2013
L. A. Leshin; Paul R. Mahaffy; C. R. Webster; Michel Cabane; Patrice Coll; P. G. Conrad; P. D. Archer; Sushil K. Atreya; A. E. Brunner; Arnaud Buch; Jennifer L. Eigenbrode; G. J. Flesch; Heather B. Franz; Caroline Freissinet; D. P. Glavin; A. C. McAdam; Kristen E. Miller; D. W. Ming; Richard V. Morris; Rafael Navarro-González; Paul B. Niles; Tobias Owen; S. W. Squyres; Andrew Steele; Jennifer C. Stern; Roger E. Summons; Dawn Y. Sumner; Brad Sutter; Cyril Szopa; Samuel Teinturier
Samples from the Rocknest aeolian deposit were heated to ~835°C under helium flow and evolved gases analyzed by Curiosity’s Sample Analysis at Mars instrument suite. H2O, SO2, CO2, and O2 were the major gases released. Water abundance (1.5 to 3 weight percent) and release temperature suggest that H2O is bound within an amorphous component of the sample. Decomposition of fine-grained Fe or Mg carbonate is the likely source of much of the evolved CO2. Evolved O2 is coincident with the release of Cl, suggesting that oxygen is produced from thermal decomposition of an oxychloride compound. Elevated δD values are consistent with recent atmospheric exchange. Carbon isotopes indicate multiple carbon sources in the fines. Several simple organic compounds were detected, but they are not definitively martian in origin.
Journal of Geophysical Research | 2006
Richard V. Morris; G. Klingelhöfer; C. Schröder; D. Rodionov; Albert S. Yen; D. W. Ming; P. A. de Souza; Thomas J. Wdowiak; Iris Fleischer; R. Gellert; B. Bernhardt; U. Bonnes; Barbara A. Cohen; E. N. Evlanov; J. Foh; P. Gütlich; E. Kankeleit; Timothy J. McCoy; D. W. Mittlefehldt; Franz Renz; Mariek E. Schmidt; B. Zubkov; S. W. Squyres; Raymond E. Arvidson
Additonal co-authors: P Gutlich, E Kankeleit, T McCoy, DW Mittlefehldt, F Renz, ME Schmidt, B Zubkov, SW Squyres, RE Arvidson
Science | 2004
Mark T. Lemmon; M. J. Wolff; Michael D. Smith; R. T. Clancy; Donald J. Banfield; Geoffrey A. Landis; Amitabha Ghosh; Peter W. H. Smith; N. Spanovich; Barbara A. Whitney; P. L. Whelley; Ronald Greeley; Shane D. Thompson; James F. Bell; S. W. Squyres
A visible atmospheric optical depth of 0.9 was measured by the Spirit rover at Gusev crater and by the Opportunity rover at Meridiani Planum. Optical depth decreased by about 0.6 to 0.7% per sol through both 90-sol primary missions. The vertical distribution of atmospheric dust at Gusev crater was consistent with uniform mixing, with a measured scale height of 11.56 ± 0.62 kilometers. The dusts cross section weighted mean radius was 1.47 ± 0.21 micrometers (μm) at Gusev and 1.52 ± 0.18 μ at Meridiani. Comparison of visible optical depths with 9-μ optical depths shows a visible-to-infrared optical depth ratio of 2.0 ± 0.2 for comparison with previous monitoring of infrared optical depths.
Space Science Reviews | 2004
William V. Boynton; W. C. Feldman; I. G. Mitrofanov; Larry G. Evans; Robert C. Reedy; S. W. Squyres; Richard D. Starr; Jack I. Trombka; C. d'Uston; J.R. Arnold; P.A.J. Englert; Albert E. Metzger; H. Wänke; J. Brückner; Darrell M. Drake; C. Shinohara; C. Fellows; David K. Hamara; K. Harshman; K. E. Kerry; Carl Turner; M. Ward; H. Barthe; K.R. Fuller; S. A. Storms; G. W. Thornton; J. L. Longmire; M. L. Litvak; A.K. Ton'chev
The Mars Odyssey Gamma-Ray Spectrometer is a suite of three different instruments, a gamma subsystem (GS), a neutron spectrometer, and a high-energy neutron detector, working together to collect data that will permit the mapping of elemental concentrations on the surface of Mars. The instruments are complimentary in that the neutron instruments have greater sensitivity to low amounts of hydrogen, but their signals saturate as the hydrogen content gets high. The hydrogen signal in the GS, on the other hand, does not saturate at high hydrogen contents and is sensitive to small differences in hydrogen content even when hydrogen is very abundant. The hydrogen signal in the neutron instruments and the GS have a different dependence on depth, and thus by combining both data sets we can infer not only the amount of hydrogen, but constrain its distribution with depth. In addition to hydrogen, the GS determines the abundances of several other elements. The instruments, the basis of the technique, and the data processing requirements are described as are some expected applications of the data to scientific problems.
Journal of Geophysical Research | 2006
Raymond E. Arvidson; S. W. Squyres; Robert C. Anderson; James F. Bell; Diana L. Blaney; J. Brückner; Nathalie A. Cabrol; Wendy M. Calvin; Michael H. Carr; Philip R. Christensen; B. C. Clark; Larry S. Crumpler; D. J. Des Marais; P. A. de Souza; C. d'Uston; T. Economou; Jack D. Farmer; William H. Farrand; William M. Folkner; M. P. Golombek; S. Gorevan; J. A. Grant; Ronald Greeley; John P. Grotzinger; Edward A. Guinness; Brian C. Hahn; Larry A. Haskin; K. E. Herkenhoff; Joel A. Hurowitz; S. F. Hviid
Spirit landed on the floor of Gusev Crater and conducted initial operations on soil-covered, rock-strewn cratered plains underlain by olivine-bearing basalts. Plains surface rocks are covered by wind-blown dust and show evidence for surface enrichment of soluble species as vein and void-filling materials and coatings. The surface enrichment is the result of a minor amount of transport and deposition by aqueous processes. Layered granular deposits were discovered in the Columbia Hills, with outcrops that tend to dip conformably with the topography. The granular rocks are interpreted to be volcanic ash and/or impact ejecta deposits that have been modified by aqueous fluids during and/or after emplacement. Soils consist of basaltic deposits that are weakly cohesive, relatively poorly sorted, and covered by a veneer of wind-blown dust. The soils have been homogenized by wind transport over at least the several kilometer length scale traversed by the rover. Mobilization of soluble species has occurred within at least two soil deposits examined. The presence of monolayers of coarse sand on wind-blown bedforms, together with even spacing of granule-sized surface clasts, suggests that some of the soil surfaces encountered by Spirit have not been modified by wind for some time. On the other hand, dust deposits on the surface and rover deck have changed during the course of the mission. Detection of dust devils, monitoring of the dust opacity and lower boundary layer, and coordinated experiments with orbiters provided new insights into atmosphere-surface dynamics.
Nature | 2005
R. Sullivan; Donald J. Banfield; James F. Bell; Wendy M. Calvin; David A. Fike; M. P. Golombek; Ronald Greeley; John P. Grotzinger; K. E. Herkenhoff; Douglas J. Jerolmack; M. C. Malin; D. W. Ming; L. A. Soderblom; S. W. Squyres; Shane D. Thompson; Wesley Andres Watters; Catherine M. Weitz; Albert S. Yen
The martian surface is a natural laboratory for testing our understanding of the physics of aeolian (wind-related) processes in an environment different from that of Earth. Martian surface markings and atmospheric opacity are time-variable, indicating that fine particles at the surface are mobilized regularly by wind. Regolith (unconsolidated surface material) at the Mars Exploration Rover Opportunitys landing site has been affected greatly by wind, which has created and reoriented bedforms, sorted grains, and eroded bedrock. Aeolian features here preserve a unique record of changing wind direction and wind strength. Here we present an in situ examination of a martian bright wind streak, which provides evidence consistent with a previously proposed formational model for such features. We also show that a widely used criterion for distinguishing between aeolian saltation- and suspension-dominated grain behaviour is different on Mars, and that estimated wind friction speeds between 2 and 3 m s-1, most recently from the northwest, are associated with recent global dust storms, providing ground truth for climate model predictions.
Journal of Geophysical Research | 2006
Raymond E. Arvidson; F. Poulet; Richard V. Morris; Jean-Pierre Bibring; James F. Bell; S. W. Squyres; Philip R. Christensen; G. Bellucci; B. Gondet; B. L. Ehlmann; William H. Farrand; R. L. Fergason; M. Golombek; J. L. Griffes; John P. Grotzinger; Edward A. Guinness; K. E. Herkenhoff; James Richard Johnson; G. Klingelhöfer; Yves Langevin; D. W. Ming; Kimberly D. Seelos; R. Sullivan; J. Ward; Sandra Margot Wiseman; M. J. Wolff
The ~5 km of traverses and observations completed by the Opportunity rover from Endurance crater to the Fruitbasket outcrop show that the Meridiani plains consist of sulfate-rich sedimentary rocks that are largely covered by poorly-sorted basaltic aeolian sands and a lag of granule-sized hematitic concretions. Orbital reflectance spectra obtained by Mars Express OMEGA over this region are dominated by pyroxene, plagioclase feldspar, crystalline hematite (i.e., concretions), and nano-phase iron oxide dust signatures, consistent with Pancam and Mini-TES observations. Mossbauer Spectrometer observations indicate more olivine than observed with the other instruments, consistent with preferential optical obscuration of olivine features in mixtures with pyroxene and dust. Orbital data covering bright plains located several kilometers to the south of the landing site expose a smaller areal abundance of hematite, more dust, and a larger areal extent of outcrop compared to plains proximal to the landing site. Low-albedo, low-thermal-inertia, windswept plains located several hundred kilometers to the south of the landing site are predicted from OMEGA data to have more hematite and fine-grained olivine grains exposed as compared to the landing site. Low calcium pyroxene dominates spectral signatures from the cratered highlands to the south of Opportunity. A regional-scale model is presented for the formation of the plains explored by Opportunity, based on a rising ground water table late in the Noachian Era that trapped and altered local materials and aeolian basaltic sands. Cessation of this aqueous process led to dominance of aeolian processes and formation of the current configuration of the plains.