Geochemical diversity in first rocks examined by the Curiosity Rover in Gale Crater: Evidence for and significance of an alkali and volatile‐rich igneous source

M. E. Schmidt; J. L. Campbell; R. Gellert; G. M. Perrett; A. H. Treiman; D. L. Blaney; A. M. Olilla; F. J. Calef; L. A. Edgar; Beverley Elliott; J. P. Grotzinger; J. A. Hurowitz; P. L. King; M. E. Minitti; V. Sautter; K. M. Stack; J. A. Berger; J. C. Bridges; B. L. Ehlmann; O. Forni; L. A. Leshin; K. W. Lewis; S. M. McLennan; D. W. Ming; H. E. Newsom; Irina Pradler; S. W. Squyres; Edward M. Stolper; L. M. Thompson; S. J. VanBommel; R. C. Wiens

doi:10.1002/2013je004481

Geochemical diversity in first rocks examined by the Curiosity Rover in Gale Crater: Evidence for and significance of an alkali and volatile‐rich igneous source

M. E. Schmidt(Brock University), J. L. Campbell(University of Guelph), R. Gellert(University of Guelph), G. M. Perrett(University of Guelph), A. H. Treiman(Planetary Science Institute), D. L. Blaney(Jet Propulsion Laboratory), A. M. Olilla(University of New Mexico), F. J. Calef(Jet Propulsion Laboratory), L. A. Edgar(Arizona State University), Beverley Elliott(University of New Brunswick), J. P. Grotzinger(California Institute of Technology), J. A. Hurowitz(Stony Brook School), P. L. King(Australian National University), M. E. Minitti(Johns Hopkins University Applied Physics Laboratory), V. Sautter(Muséum national d'Histoire naturelle), K. M. Stack(California Institute of Technology), J. A. Berger(Western University), J. C. Bridges(University of Leicester), B. L. Ehlmann(California Institute of Technology), O. Forni(Université Toulouse III - Paul Sabatier), L. A. Leshin(Rensselaer Polytechnic Institute), K. W. Lewis(Princeton University), S. M. McLennan(Princeton University), D. W. Ming(Johnson Space Center), H. E. Newsom(University of New Mexico), Irina Pradler(University of Guelph), S. W. Squyres(Cornell University), Edward M. Stolper(California Institute of Technology), L. M. Thompson(University of New Brunswick), S. J. VanBommel(University of Guelph), R. C. Wiens(Los Alamos National Laboratory)

Journal of Geophysical Research Planets

December 9, 2013

10.1002/2013je004481

Cited by 142Open Access

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Abstract

Abstract The first four rocks examined by the Mars Science Laboratory Alpha Particle X‐ray Spectrometer indicate that Curiosity landed in a lithologically diverse region of Mars. These rocks, collectively dubbed the Bradbury assemblage, were studied along an eastward traverse (sols 46–102). Compositions range from Na‐ and Al‐rich mugearite Jake_Matijevic to Fe‐, Mg‐, and Zn‐rich alkali‐rich basalt/hawaiite Bathurst_Inlet and span nearly the entire range in FeO* and MnO of the data sets from previous Martian missions and Martian meteorites. The Bradbury assemblage is also enriched in K and moderately volatile metals (Zn and Ge). These elements do not correlate with Cl or S, suggesting that they are associated with the rocks themselves and not with salt‐rich coatings. Three out of the four Bradbury rocks plot along a line in elemental variation diagrams, suggesting mixing between Al‐rich and Fe‐rich components. ChemCam analyses give insight to their degree of chemical heterogeneity and grain size. Variations in trace elements detected by ChemCam suggest chemical weathering (Li) and concentration in mineral phases (e.g., Rb and Sr in feldspars). We interpret the Bradbury assemblage to be broadly volcanic and/or volcaniclastic, derived either from near the Gale crater rim and transported by the Peace Vallis fan network, or from a local volcanic source within Gale Crater. High Fe and Fe/Mn in Et_Then likely reflect secondary precipitation of Fe 3+ oxides as a cement or rind. The K‐rich signature of the Bradbury assemblage, if igneous in origin, may have formed by small degrees of partial melting of metasomatized mantle.

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