Mars Science Laboratory CheMin Data From the Glen Torridon Region and the Significance of Lake‐Groundwater Interactions in Interpreting Mineralogy and Sedimentary History

Thorpe, M. T.; Bristow, T. F.; Rampe, E. B.; Tosca, Nicholas J.; Grotzinger, J. P.; Bennett, K. A.; Achilles, C. N.; Blake, D. F.; Chipera, S. J.; Downs, G. W.; Vaniman, David T.; Morrison, S. M.; Bridges, John C.; Castle, N.; Siebach, K. L.; Marais, David J. Des; Hazen, Robert M.; Ming, D. W.; Morris, R. V.; Treiman, Allan H.; Vaniman, D. T.; Yen, Albert S.; Vasavada, A. R.; Dehouck, E.; Bridges, J. C.; Berger, J. A.; McAdam, A. C.; Peretyazhko, T. S.; Bryk, A. B.; Fox, V. K.; Fedo, C. M.

doi:10.1029/2021je007099

Cited by 39 publications

(214 citation statements)

References 148 publications

(314 reference statements)

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“…The Greenheugh pediment capping unit has more MgO relative to the other Stimson localities (Figures 6 and 11), in addition to a greater abundance of Clusters 2 and 5 (Figure 11), indicative of higher abundances of mafic minerals. This is supported by the mineralogical results from CheMin that show a relatively high concentration of olivine (Rampe, Yen et al., 2020; Thorpe et al., 2022), indicating that the Greenheugh capping unit may be enriched in mafic components as a result of mineral sorting during transportation, assuming that the sands were derived from the same sediment source. If this is the case, the Greenheugh capping unit would have been deposited farther from the source than the Stimson formation at the Emerson and Naukluft plateaus that respectively show an increase in the felsic Clusters 3 and 4 (Figure 10).…”

Section: Discussionmentioning

confidence: 65%

“…The geochemical trends of the majority of ChemCam data between mafic and felsic minerals, and the similarity in composition between concretionary and non‐concretionary bedrock, also suggests that alteration was likely minimal away from the unconformity for the Greenheugh pediment capping unit. Minimal alteration at Greenheugh is further supported by the presence of 8 wt% olivine in the Edinburgh drilled sample (Rampe, Yen et al., 2020; Thorpe et al, 2022), which is only slightly less than the olivine abundances for the active aeolian sands at the Bagnold Dunes (e.g., 9.6 wt% at Ogunquit Beach; Rampe et al., 2018). This, in addition to the low degree of chemical weathering during transportation for dry aeolian systems (Jiang and Yang, 2019; Zhu and Yang, 2009), suggests that the geochemistry of the Stimson formation at the Greenheugh pediment capping unit is likely to be representative of the mineralogy of the dune sands at the time of deposition.…”

Section: Discussionmentioning

confidence: 95%

“…This can be indicative of calcium sulfate cement which has been largely detected by the ChemCam instrument and correlated to light-toned cements in MAHLI images acquired in the traverse leading up to the Greenheugh pediment (Gasda et al, 2022;Nellessen et al, 2019). However, the mineralogy of the Hutton drilled sample acquired below the capping unit only contains 0.6 wt% anhydrite (Thorpe et al, 2022), which is some of the lowest abundances of crystalline calcium sulfate detected in the Mt Sharp group since the drilled samples of the Pahrump Hills (Rampe et al, 2017), and sulfur is not detected here with APXS (Thompson et al, 2022). F abundances also increase in the Carolyn Shoemaker formation below the unconformity at the Hutton drill site (Dehouck et al, 2022; Figure 8b), including for alteration features such as veins and raised ridges (Gasda et al, 2022).…”

Section: Diagenesis At the Unconformitymentioning

confidence: 99%

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An Insight Into Ancient Aeolian Processes and Post‐Noachian Aqueous Alteration in Gale Crater, Mars, Using ChemCam Geochemical Data From the Greenheugh Capping Unit

et al. 2022

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Aeolian processes have shaped and contributed to the geological record in Gale crater, Mars, long after the fluviolacustrine system existed ∼3 Ga ago. Understanding these aeolian deposits, particularly those which have been lithified and show evidence for aqueous alteration, can help to constrain the environment at their time of deposition and the role of liquid water later in Mars' history. The NASA Curiosity rover investigated a prominent outcrop of aeolian sandstone within the Stimson formation at the Greenheugh pediment as part of its investigation of the Glen Torridon area. In this study, we use geochemical data from ChemCam to constrain the effects of aeolian sedimentary processes, sediment provenance, and diagenesis of the sandstone at the Greenheugh pediment, comparing the Greenheugh data to the results from previous Stimson localities situated 2.5 km north and >200 m lower in elevation. Our results, supported by mineralogical data from CheMin, show that the Stimson formation at the Greenheugh pediment was predominately sourced from an olivine‐rich unit that may be present farther up the slopes of Gale crater's central mound. Our results also suggest that the Greenheugh pediment Stimson formation was cemented by surface water runoff such as that which may have formed Gediz Vallis. The lack of alteration features in the Stimson formation at the Greenheugh pediment relative to those of the Emerson and Naukluft plateaus suggests that groundwater was not as available at this locality compared to the others. However, all sites share diagenesis at the unconformity.

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Section: Discussionmentioning

confidence: 65%

Section: Discussionmentioning

confidence: 95%

Section: Diagenesis At the Unconformitymentioning

confidence: 99%

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An Insight Into Ancient Aeolian Processes and Post‐Noachian Aqueous Alteration in Gale Crater, Mars, Using ChemCam Geochemical Data From the Greenheugh Capping Unit

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“…If the 9.2 Å phase is an authigenic clay mineral such as mixed layer G‐M hypothesized by Thorpe et al. (2022) the siderite may have been deposited from the same fluids as formed the G‐M, since these minerals are known to occur together in terrestrial settings.…”

Section: Discussionmentioning

confidence: 98%

“…This process could have also contributed to the heterogeneity in siderite abundances now observed in Jm and KHm rocks. If the 9.2 Å phase is an authigenic clay mineral such as mixed layer G-M hypothesized by Thorpe et al (2022) the siderite may have been deposited from the same fluids as formed the G-M, since these minerals are known to occur together in terrestrial settings. 3.…”

Section: Plausible Series Of Eventsmentioning

confidence: 99%

Evolved Gas Analyses of Sedimentary Rocks From the Glen Torridon Clay‐Bearing Unit, Gale Crater, Mars: Results From the Mars Science Laboratory Sample Analysis at Mars Instrument Suite

et al. 2022

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Evolved gas analysis (EGA) data from the Sample Analysis at Mars (SAM) instrument suite indicated Fe-rich smectite, carbonate, oxidized organics, Fe/Mg sulfate, and chloride in sedimentary rocks from the Glen Torridon (GT) region of Gale crater that displayed phyllosilicate spectral signatures from orbit. SAM evolved H 2 O data indicated that the primary phyllosilicate in all GT samples was an Fe-rich dioctahedral smectite (e.g., nontronite) with lesser amounts of a phyllosilicate such as mixed layer talc-serpentine or greenalite-minnesotaite. CO 2 data supported the identification of siderite in several samples, and CO 2 and CO data was also consistent with trace oxidized organic compounds such as oxalate salts. SO 2 data indicated trace and/or amorphous Fe sulfates in all samples and one sample may contain Fe sulfides. SO 2 data points to significant Mg sulfates in two samples, and lesser amounts in several other samples. A lack of evolved O 2 indicated the absence of oxychlorine salts and Mn 3+ /Mn 4+ oxides. The lack of, or very minor, evolved NO revealed absent or very trace nitrate/nitrite salts. HCl data suggested chloride salts in GT samples. Constraints from EGA data on mineralogy and chemistry indicated that the environmental history of GT involved alteration with fluids of variable redox potential, chemistry and pH under a range of fluid-to-rock ratio conditions. Several of the fluid episodes could have provided habitable environmental conditions and carbon would have been available to any past microbes though the lack of significant N could have been a limiting factor for microbial habitability in the GT region. Plain Language SummaryThe Mars Science Laboratory Curiosity rover carried out a comprehensive investigation of the sedimentary rocks in the Glen Torridon (GT) region in Gale crater, Mars, to better understand Martian geologic history. The rover's Sample Analysis at Mars instrument suite was used to heat samples from GT and detect gases that were evolved to help identify the volatile-bearing mineralogy of the samples. Results indicated the presence of Fe-rich smectite, carbonate, oxidized organics, Fe and Mg sulfate, and chloride while oxychlorine salts, Mn 3+ /Mn 4+ oxides, and nitrate/nitrite salts were either not detected or occurred in trace amounts. This mineralogy data implied that geochemical conditions and fluid-to-rock ratios varied over time and that the conditions of GT depositional and diagenetic environments would have been amenable to microbial life with sufficient carbon but nitrogen abundances could have been limiting.

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Statistical analysis of APXS-derived chemistry of the clay-bearing Glen Torridon region and Mount Sharp group, Gale crater, Mars

O’Connell‐Cooper

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et al. 2022

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The Glen Torridon stratigraphic sequence marks the transition from the low energy lacustrine-dominated Murray formation (Mf) (Jura member: Jm) to the more diverse Carolyn Shoemaker formation (CSf) (Knockfarril Hill member: KHm; Glasgow member: Gm), indicating a change in overall depositional setting. Alpha Particle X-ray Spectrometer (APXS) results and statistical analysis reveals that the bulk primary geochemistry of Mf targets are broadly in family with CSf targets, but with subtle compositional and diagenetic trends with increasing elevation. APXS results reveal significant compositional differences between Jm GT and the stratigraphically equivalent Jura on Vera Rubin ridge (Jm VRR). APXS data defines two geochemical facies (high-K or high-Mg) with a strong bimodal grain distribution in Jm GT and KHm. The contact between KHm to Gm is marked by abrupt sedimentological changes but a similar composition for both. Away from the contact, the KHm and Gm plot discretely, suggesting a zone of common alteration at the transition and/or a gradual transition in provenance with increasing elevation in the Gm. APXS results point to a complex history of diagenesis within Glen Torridon, with increasing diagenesis close to the Basal Siccar Point unconformity on the Greenheugh pediment, and with proximity to the beginning of the clay sulfate transition. Elemental mobility is evident in localized enrichments or depletions of Ca, S, Mn, P, Zn, Ni. The highly altered Hutton interval, in contact with the unconformity on Tower butte, is also identified on Western Butte, indicating that the "interval" was once laterally extensive.1

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Mars Science Laboratory CheMin Data From the Glen Torridon Region and the Significance of Lake‐Groundwater Interactions in Interpreting Mineralogy and Sedimentary History

Cited by 39 publications

References 148 publications

An Insight Into Ancient Aeolian Processes and Post‐Noachian Aqueous Alteration in Gale Crater, Mars, Using ChemCam Geochemical Data From the Greenheugh Capping Unit

An Insight Into Ancient Aeolian Processes and Post‐Noachian Aqueous Alteration in Gale Crater, Mars, Using ChemCam Geochemical Data From the Greenheugh Capping Unit

Evolved Gas Analyses of Sedimentary Rocks From the Glen Torridon Clay‐Bearing Unit, Gale Crater, Mars: Results From the Mars Science Laboratory Sample Analysis at Mars Instrument Suite

Statistical analysis of APXS-derived chemistry of the clay-bearing Glen Torridon region and Mount Sharp group, Gale crater, Mars

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