Your search keyword '"Steven W. Squyres"' showing total 2 results

1. Esperance: Multiple episodes of aqueous alteration involving fracture fills and coatings at Matijevic Hill, Mars

Author

Douglas W. Ming, David W. Mittlefehldt, Steven W. Squyres, Bradley L. Jolliff, Albert S. Yen, Raymond E. Arvidson, Richard V. Morris, Benton C. Clark, William H. Farrand, Ralf Gellert, and Kenneth E. Herkenhoff

Subjects

010504 meteorology & atmospheric sciences, Outcrop, Fracture (mineralogy), Mineralogy, Mars Exploration Program, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Impact crater, Coating, Geochemistry and Petrology, engineering, Clay minerals, Vein (geology), Chemical composition, Geology, 0105 earth and related environmental sciences

Abstract

In the search for evidence of past aqueous activity by the Mars Exploration Rover Opportunity, fracture-filling veins and rock coatings are prime candidates for exploration. At one location within a segment of remaining rim material surrounding Endeavour Crater, a set of “boxwork” fractures in an outcrop called Esperance are filled by a bright, hydrated, and highly siliceous (SiO2 ~ 66 wt%) material, which has overall a montmorillonite-like chemical composition. This material is partially covered by patches of a thin, dark coating that is sulfate-rich (SO3 ~ 21 wt%) but also contains significant levels of Si, Fe, Ca, and Mg. The simultaneous presence of abundant S, Si, and Fe indicates significant mineralogical complexity within the coating. This combination of vein and coating compositions is unlike previous analyses on Mars. Both materials are heterogeneously eroded, presumably by eolian abrasion. The evidence indicates at least two separate episodes of solute precipitation from aqueous fluids at this location, possibly widely separated in time. In addition to the implications for multiple episodes of alteration at the surface of the planet, aqueous chemical environments such as these would have been habitable at the time of their formation and are also favorable for preservation of organic material.

Published

2016

2. High concentrations of manganese and sulfur in deposits on Murray Ridge, Endeavour Crater, Mars

Author

Margaret A.G. Hinkle, James F. Bell, Edward A. Guinness, Steven W. Squyres, Kenneth E. Herkenhoff, William H. Farrand, Raymond E. Arvidson, Nathan Stein, Valerie Fox, Richard V. Morris, Scott VanBommel, Ralf Gellert, Paulo de Souza, Benton C. Clark, David W. Mittlefehldt, Jeffrey R. Johnson, Wendy M. Calvin, Andrew H. Knoll, John P. Grotzinger, Scott M. McLennan, B. L. Jolliff, Matthew P. Golombek, and Jeffrey G. Catalano

Subjects

Basalt, 010504 meteorology & atmospheric sciences, Fracture (mineralogy), Geochemistry, Noachian, Mineralogy, Fracture zone, Mars Exploration Program, 010502 geochemistry & geophysics, 01 natural sciences, Geophysics, Impact crater, Geochemistry and Petrology, Breccia, Sulfate minerals, Geology, 0105 earth and related environmental sciences

Abstract

Mars Reconnaissance Orbiter HiRISE images and Opportunity rover observations of the ~22 km wide Noachian age Endeavour Crater on Mars show that the rim and surrounding terrains were densely fractured during the impact crater-forming event. Fractures have also propagated upward into the overlying Burns formation sandstones. Opportunity’s observations show that the western crater rim segment, called Murray Ridge, is composed of impact breccias with basaltic compositions, as well as occasional fracture-filling calcium sulfate veins. Cook Haven, a gentle depression on Murray Ridge, and the site where Opportunity spent its sixth winter, exposes highly fractured, recessive outcrops that have relatively high concentrations of S and Cl, consistent with modest aqueous alteration. Opportunity’s rover wheels serendipitously excavated and overturned several small rocks from a Cook Haven fracture zone. Extensive measurement campaigns were conducted on two of them: Pinnacle Island and Stuart Island. These rocks have the highest concentrations of Mn and S measured to date by Opportunity and occur as a relatively bright sulfate-rich coating on basaltic rock, capped by a thin deposit of one or more dark Mn oxide phases intermixed with sulfate minerals. We infer from these unique Pinnacle Island and Stuart Island rock measurements that subsurface precipitation of sulfate-dominated coatings was followed by an interval of partial dissolution and reaction with one or more strong oxidants (e.g., O_2) to produce the Mn oxide mineral(s) intermixed with sulfate-rich salt coatings. In contrast to arid regions on Earth, where Mn oxides are widely incorporated into coatings on surface rocks, our results demonstrate that on Mars the most likely place to deposit and preserve Mn oxides was in fracture zones where migrating fluids intersected surface oxidants, forming precipitates shielded from subsequent physical erosion.

Published

2016