The Chemostratigraphy of the Murray Formation and Role of Diagenesis at Vera Rubin Ridge in Gale Crater, Mars, as Observed by the ChemCam Instrument
- Creators
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Frydenvang, J.
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Mangold, N.
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Wiens, R. C.
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Fraeman, A. A.
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Edgar, L. A.
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Fedo, C. M.
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L'Haridon, J. L.
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Bedford, C. C.
- Gupta, S.
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Grotzinger, J. P.
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Bridges, J. C.
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Clark, B. C.
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Rampe, E. B.
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Gasnault, O.
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Maurice, S.
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Gasda, P. J.
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Lanza, N. L.
- Olilla, A. M.
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Meslin, P.‐Y.
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Payré, V.
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Calef, F.
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Salvatore, M.
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House, C. H.
Abstract
Geochemical results are presented from Curiosity's exploration of Vera Rubin ridge (VRR), in addition to the full chemostratigraphy of the predominantly lacustrine mudstone Murray formation up to and including VRR. VRR is a prominent ridge flanking Aeolis Mons (informally Mt. Sharp), the central mound in Gale crater, Mars, and was a key area of interest for the Mars Science Laboratory mission. ChemCam data show that VRR is overall geochemically similar to lower‐lying members of the Murray formation, even though the top of VRR shows a strong hematite spectral signature as observed from orbit. Although overall geochemically similar, VRR is characterized by a prominent decrease in Li abundance and Chemical Index of Alteration across the ridge. This decrease follows the morphology of the ridge rather than elevation and is inferred to reflect a nondepositionally controlled decrease in clay mineral abundance in VRR rocks. Additionally, a notable enrichment in Mn above baseline levels is observed on VRR. While not supporting a single model, the results suggest that VRR rocks were likely affected by multiple episodes of postdepositional groundwater interactions that made them more erosionally resistant than surrounding Murray rocks, thus resulting in the modern‐day ridge after subsequent erosion.
Additional Information
© 2020 American Geophysical Union. Issue Online: 12 September 2020; Version of Record online: 12 September 2020; Accepted manuscript online: 27 June 2020; Manuscript accepted: 22 June 2020; Manuscript revised: 19 June 2020; Manuscript received: 07 December 2019. This work was supported by the NASA MSL Mission—operated by the Jet Propulsion Laboratory, California Institute of Technology—and the NASA Mars Exploration Program. We acknowledge the support of the MSL engineering and operations staff. JF acknowledges the support of the Carlsberg Foundation. NM, JLH, OG, SM, and PYM acknowledge the support of CNES for their work on MSL ChemCam. CCB was funded through the STFC doctoral training grant to the OU. A portion of this research was carried out at the Jet Propulsion Laboratory, California Institute of Technology, under a contract with the National Aeronautics and Space Administration. Data Availability Statement: All geochemical data used in this paper are provided in Table S1 and are available, along with spectra of all points, via the NASA Planetary Data System (http://pds-geosciences.wustl.edu/missions/msl/). Table S1 can also be acquired at doi.org/10.17894/ucph.80bf74b2‐c569‐45f8‐813e‐0c70e44bf298. Any use of trade, firm, or product names is for descriptive purposes only and does not imply endorsement by the U.S. Government.Attached Files
Published - 2019JE006320.pdf
Supplemental Material - jgrc24140-sup-0001-2020jc016544-si.pdf
Supplemental Material - jgre21423-sup-0001-2019je006320-si.pdf
Supplemental Material - jgre21423-sup-0002-2019je006320-ds01.xlsx
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Additional details
- Eprint ID
- 105047
- Resolver ID
- CaltechAUTHORS:20200820-143818644
- NASA/JPL/Caltech
- Carlsberg Foundation
- Centre National d'Études Spatiales (CNES)
- Science and Technology Facilities Council (STFC)
- Created
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2020-08-20Created from EPrint's datestamp field
- Updated
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2023-06-01Created from EPrint's last_modified field
- Caltech groups
- Division of Geological and Planetary Sciences