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Published October 2013 | public
Journal Article Metadata-only

A hematite-bearing layer in Gale Crater, Mars: Mapping and implications for past aqueous conditions

Fraeman, A. A. ORCID icon
Arvidson, R. E. ORCID icon
Catalano, J. G. ORCID icon
Grotzinger, J. P. ORCID icon
Morris, R. V. ORCID icon
Murchie, S. L. ORCID icon
Stack, K. M. ORCID icon
Humm, D. C.
McGovern, J. A.
Seelos, F. P. ORCID icon
Viviano, C. E.

Abstract

Oversampled Compact Reconnaissance Imaging Spectrometer for Mars (CRISM) visible and near-infrared hyperspectral data over Mount Sharp in Gale Crater, Mars, were used to generate spatially sharpened maps of the location of red crystalline hematite within the uppermost stratum of an ∼6.5-km-long ridge on the mound's northern flank. Finely layered strata underlie the ridge to the north and have dips consistent with the nearby Mount Sharp sedimentary sequence. Fe-Mg smectites are exposed in a valley to the south of the ridge. Emplacement of the hematite is hypothesized to result either from exposure of anoxic Fe^(2+)-rich groundwater to an oxidizing environment, leading to precipitation of hematite or its precursors, or from in-place weathering of precursor silicate materials under oxidizing conditions. These hypotheses and implications for habitability will be testable with in situ measurements by the Mars rover Curiosity when it reaches Mount Sharp.

Additional Information

© 2013 Geological Society of America. Manuscript received 1 April 2013. Revised manuscript received 19 June 2013. Manuscript accepted 27 June 2013. We thank the CRISM Science Operations Center for their assistance in developing the along-track oversampled observations scheme. This manuscript was substantially improved by insightful reviews from E. Rampe, N. Tosca, S. Ruff, and one anonymous reviewer; we also thank S. McLennan and J. Hurowitz for comments on an early version. This work was supported by CRISM APL/JPL contract 104149, and Fraeman was funded by National Science Foundation Graduate Student Research Fellowship grant DGE-1143954. Catalano acknowledges financial support from the NASA Mars Fundamental Research Program (grant NNX11AH09G), and Morris acknowledges the support of the Mars Exploration Program.

Additional details

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August 19, 2023
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October 25, 2023