Overview of the Spirit Mars Exploration Rover Mission to Gusev Crater: Landing site to Backstay Rock in the Columbia Hills

R. E. Arvidson; S. W. Squyres; Robert C. Anderson; J. F. Bell; D. L. Blaney; J. Brückner; Nathalie A. Cabrol; W. M. Calvin; M. H. Carr; P. R. Christensen; B. C. Clark; L. S. Crumpler; David J. Des Marais; Paulo de Souza; C. d’Uston; T. Economou; Jack D. Farmer; W. H. Farrand; W. M. Folkner; M. P. Golombek; S. Gorevan; J. A. Grant; R. Greeley; J. P. Grotzinger; E. A. Guinness; B. C. Hahn; L. A. Haskin; K. E. Herkenhoff; J. A. Hurowitz; S. F. Hviid; J. R. Johnson; G. Klingelhöfer; Andrew H. Knoll; Geoffrey A. Landis; C. Leff; M. T. Lemmon; R. Li; M. B. Madsen; M. C. Malin; S. M. McLennan; H. Y. McSween; D. W. Ming; J. E. Moersch; R. V. Morris; T. J. Parker; J. W. Rice; L. Richter; R. Rieder; D. Rodionov; Christian Schröder; M. R. Sims; M. D. Smith; Peter H. Smith; L. A. Soderblom; R. Sullivan; S. D. Thompson; Nicholas J. Tosca; Alian Wang; H. Wänke; J. G. Ward; T. J. Wdowiak; M. J. Wolff; A. S. Yen

doi:10.1029/2005je002499

Overview of the Spirit Mars Exploration Rover Mission to Gusev Crater: Landing site to Backstay Rock in the Columbia Hills

R. E. Arvidson(Washington University in St. Louis), S. W. Squyres(Cornell University), Robert C. Anderson(Jet Propulsion Laboratory), J. F. Bell(Cornell University), D. L. Blaney(Jet Propulsion Laboratory), J. Brückner(Max Planck Institute for Chemistry), Nathalie A. Cabrol(Ames Research Center), W. M. Calvin(University of Nevada, Reno), M. H. Carr(United States Geological Survey), P. R. Christensen(Arizona State University), B. C. Clark(Lockheed Martin (United States)), L. S. Crumpler(New Mexico Museum of Natural History and Science), David J. Des Marais(Ames Research Center), Paulo de Souza(Universidade Vale do Rio Doce), C. d’Uston(Centre National d'Études Spatiales), T. Economou(Fermi National Accelerator Laboratory), Jack D. Farmer(Arizona State University), W. H. Farrand(Space Science Institute), W. M. Folkner(Jet Propulsion Laboratory), M. P. Golombek(Jet Propulsion Laboratory), S. Gorevan(Honeybee Robotics (United States)), J. A. Grant(Smithsonian Institution), R. Greeley(Arizona State University), J. P. Grotzinger(Planetary Science Institute), E. A. Guinness(Washington University in St. Louis), B. C. Hahn(State University of New York), L. A. Haskin(Washington University in St. Louis), K. E. Herkenhoff(United States Geological Survey), J. A. Hurowitz(State University of New York), S. F. Hviid(Max Planck Institute for Solar System Research), J. R. Johnson(United States Geological Survey), G. Klingelhöfer(Johannes Gutenberg University Mainz), Andrew H. Knoll(Harvard University), Geoffrey A. Landis(Glenn Research Center), C. Leff(Jet Propulsion Laboratory), M. T. Lemmon(Texas A&M University), R. Li(The Ohio State University), M. B. Madsen(University of Copenhagen), M. C. Malin(Malin Space Science Systems (United States)), S. M. McLennan(State University of New York), H. Y. McSween(University of Tennessee at Knoxville), D. W. Ming(Johnson Space Center), J. E. Moersch(University of Tennessee at Knoxville), R. V. Morris(Johnson Space Center), T. J. Parker(Jet Propulsion Laboratory), J. W. Rice(Arizona State University), L. Richter(Deutsches Zentrum für Luft- und Raumfahrt e. V. (DLR)), R. Rieder(Jet Propulsion Laboratory), D. Rodionov(Johannes Gutenberg University Mainz), Christian Schröder(Johannes Gutenberg University Mainz), M. R. Sims(Ames Research Center), M. D. Smith(Goddard Space Flight Center), Peter H. Smith(University of Arizona), L. A. Soderblom(United States Geological Survey), R. Sullivan(Cornell University), S. D. Thompson(Arizona State University), Nicholas J. Tosca(State University of New York), Alian Wang(Washington University in St. Louis), H. Wänke(Max Planck Institute for Chemistry), J. G. Ward(Washington University in St. Louis), T. J. Wdowiak(University of Alabama at Birmingham), M. J. Wolff(Space Science Institute), A. S. Yen(Jet Propulsion Laboratory)

Journal of Geophysical Research Atmospheres

January 6, 2006

10.1029/2005je002499

Cited by 708Open Access

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Abstract

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.

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