Surface processes recorded by rocks and soils on Meridiani Planum, Mars: Microscopic Imager observations during Opportunity's first three extended missions

Ken Herkenhoff; J. P. Grotzinger; Andrew H. Knoll; S. M. McLennan; C. M. Weitz; Aileen Yingst; Robert C. Anderson; B. A. Archinal; R. E. Arvidson; Janet M. Barrett; K. J. Becker; J. F. Bell; C. J. Budney; M. G. Chapman; D. Cook; B. L. Ehlmann; Brenda Franklin; L. R. Gaddis; D. Galuszka; P. A. Garcia; P. E. Geissler; T. M. Hare; E. Howington‐Kraus; J. R. Johnson; L. Keszthelyi; R. L. Kirk; P. D. Lanagan; Ella Mae Lee; C. Leff; J. N. Maki; K. F. Mullins; T. J. Parker; B. Redding; M. R. Rosiek; Michael H. Sims; L. A. Soderblom; N. Spanovich; Richard Springer; S. W. Squyres; Daniel A. Stolper; R. Sucharski; T. Sucharski; Rob Sullivan; J. Torson

doi:10.1029/2008je003100

Surface processes recorded by rocks and soils on Meridiani Planum, Mars: Microscopic Imager observations during Opportunity's first three extended missions

Ken Herkenhoff(United States Geological Survey), J. P. Grotzinger(California Institute of Technology), Andrew H. Knoll(Harvard University), S. M. McLennan(State University of New York), C. M. Weitz(Planetary Science Institute), Aileen Yingst(University of Wisconsin–Green Bay), Robert C. Anderson(California Institute of Technology), B. A. Archinal(United States Geological Survey), R. E. Arvidson(Washington University in St. Louis), Janet M. Barrett(United States Geological Survey), K. J. Becker(United States Geological Survey), J. F. Bell(Cornell University), C. J. Budney(California Institute of Technology), M. G. Chapman(United States Geological Survey), D. Cook(United States Geological Survey), B. L. Ehlmann(Washington University in St. Louis), Brenda Franklin(California Institute of Technology), L. R. Gaddis(United States Geological Survey), D. Galuszka(United States Geological Survey), P. A. Garcia(United States Geological Survey), P. E. Geissler(United States Geological Survey), T. M. Hare(United States Geological Survey), E. Howington‐Kraus(United States Geological Survey), J. R. Johnson(United States Geological Survey), L. Keszthelyi(United States Geological Survey), R. L. Kirk(United States Geological Survey), P. D. Lanagan(Planetary Science Institute), Ella Mae Lee(United States Geological Survey), C. Leff(California Institute of Technology), J. N. Maki(California Institute of Technology), K. F. Mullins(United States Geological Survey), T. J. Parker(California Institute of Technology), B. Redding(United States Geological Survey), M. R. Rosiek(United States Geological Survey), Michael H. Sims(Ames Research Center), L. A. Soderblom(United States Geological Survey), N. Spanovich(California Institute of Technology), Richard Springer(California Institute of Technology), S. W. Squyres(Cornell University), Daniel A. Stolper(California Institute of Technology), R. Sucharski(United States Geological Survey), T. Sucharski(United States Geological Survey), Rob Sullivan(Cornell University), J. Torson(United States Geological Survey)

Journal of Geophysical Research Atmospheres

November 6, 2008

10.1029/2008je003100

Cited by 319Open Access

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Abstract

The Microscopic Imager (MI) on the Mars Exploration Rover Opportunity has returned images of Mars with higher resolution than any previous camera system, allowing detailed petrographic and sedimentological studies of the rocks and soils at the Meridiani Planum landing site. Designed to simulate a geologist's hand lens, the MI is mounted on Opportunity's instrument arm and can resolve objects 0.1 mm across or larger. This paper provides an overview of MI operations, data calibration, and analysis of MI data returned during the first 900 sols (Mars days) of the Opportunity landed mission. Analyses of Opportunity MI data have helped to resolve major questions about the origin of observed textures and features. These studies support eolian sediment transport, rather than impact surge processes, as the dominant depositional mechanism for Burns formation strata. MI stereo observations of a rock outcrop near the rim of Erebus Crater support the previous interpretation of similar sedimentary structures in Eagle Crater as being formed by surficial flow of liquid water. Well‐sorted spherules dominate ripple surfaces on the Meridiani plains, and the size of spherules between ripples decreases by about 1 mm from north to south along Opportunity's traverse between Endurance and Erebus craters.

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