The Complex Exhumation History of Jezero Crater Floor Unit and Its Implication for Mars Sample Return

Quantin‐Nataf, Cathy; Holm‐Alwmark, Sanna; Calef, F.; Lasue, J.; Kinch, K. M.; Stack, K. M.; Sun, V. Z.; Williams, Nathan; Dehouck, E.; Mandon, Lucia; Mangold, N.; Beyssac, Olivier; Clavé, Elise; Walter, S.; Simon, Justin I.; Annex, Andrew; Horgan, B.; Rice, J. W.; Shuster, David L.; Cohen, B. A.; Kah, L. C.; Sholes, S. F.; Weiss, B. P.

doi:10.1029/2022je007628

Cited by 13 publications

(26 citation statements)

References 61 publications

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“…Along the Artuby ridge, the Artuby and Rochette members range up to 2–2.5 and 2 m thick, respectively. While we can infer the thickness of both members from RIMFAX data (B. Horgan et al., 2023) without seeing the lower portion of Artuby due to regolith cover, these are likely underestimates of the true thickness of the members because the upper portion of Rochette may have been eroded (Quantin‐Nataf et al., 2021, 2023). Likewise, the Artuby member may have been eroded before emplacement of Rochette, and may include erosional surfaces.…”

Section: Discussionmentioning

confidence: 99%

Diverse Lava Flow Morphologies in the Stratigraphy of the Jezero Crater Floor

et al. 2023

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We present a combined geomorphologic, multispectral, and geochemical analysis of crater floor rocks in Jezero crater based on data obtained by the Mast Camera Zoom and SuperCam instruments onboard the NASA Mars 2020 Perseverance rover. The combined data from this analysis together with the results of a comparative study with geologic sites on Earth allows us to interpret the origins of rocks exposed along the Artuby ridge, a ∼900 m long scarp of lower Máaz formation rocks. The ridge exposes rocks belonging to two morphologically distinct members, Artuby and Rochette, both of which have basaltic composition and are spectrally indistinguishable in our analysis. Artuby rocks consist of morphologically distinct units that alternate over the ridge, bulbous, hummocky, layers with varying thicknesses that in places appear to have flowed over underlying strata, and sub‐planar thinner laterally continuous layers with variable friability. The Rochette member has a massive appearance with pronounced pitting and sub‐horizontal partings. Our findings are most consistent with a primary igneous emplacement as lava flows, through multiple eruptions, and we propose that the thin layers result either from preferential weathering, interbedded ash/tephra layers, ʻaʻā clinker layers, or aeolian deposition. Our analyses provide essential geologic context for the Máaz formation samples that will be returned to Earth and highlight the diversity and complexity of geologic processes on Mars not visible from orbit.

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Section: Discussionmentioning

confidence: 99%

Diverse Lava Flow Morphologies in the Stratigraphy of the Jezero Crater Floor

et al. 2023

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“…Because the highest crater densities on the Jezero Crater floor, that is, the mapped Cf‐Fr unit (cf. Stack et al., 2020), occur farthest from the delta (near Hartwell Crater; Quantin‐Nataf et al., 2021), it is likely that this surface experienced the least burial and subsequent exhumation since crystallization. Thus, assuming the rocks exposed near Hartwell Crater are equivalent to upper Máaz, use of the crater density and size distribution observed near Hartwell with the crystallization age of Máaz would provide quantitative constraints on two of the key assumptions in the Mars cratering chronology, specifically the ratios of the bolide fluxes and crater diameters, respectively, between Mars and the Moon.…”

Section: Returned Sample Science Potentialmentioning

confidence: 99%

“…However, such tests require knowledge of how long a particular surface was exposed to crater‐forming impact events; this will not generally be equal to the time since an igneous rock crystallized on a planetary surface that has experienced active geomorphic processes. Indeed, the spatial distribution of crater densities observed at the Jezero crater floor clearly indicates that the igneous rocks have also experienced a complex exhumation history, both spatially and temporally, with lowest densities observed near the delta, highest to the NE of the landing site (Quantin‐Nataf et al., 2021). Any tests or calibrations of the crater chronology function will require knowledge of when, and at what rate, this post‐crystallization exhumation occurred, and more generally, how a rock crystallization age can be related to the duration of crater accumulation at a particular surface.…”

Section: Returned Sample Science Potentialmentioning

confidence: 99%

Samples Collected From the Floor of Jezero Crater With the Mars 2020 Perseverance Rover

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“…The Naa'táanii member transitions (Figures 3d and 3f) into the higher-standing, gray-toned, massive, blocky meter-scale boulders of the Ch'ał member, which form hummocky landscapes and is the hardest and least altered member from the crater floor (Figure 20). Due to its comparatively more resistant nature, the Ch'ał member is thought to be related to the crater-retaining unit on which crater count ages have been derived (Farley et al, 2022;Goudge et al, 2015;Quantin-Nataf et al, 2021;Schon et al, 2012;Shahrzad et al, 2019). The distinction between the Naa'táanii and Ch'ał members is based largely on outcrop morphology not composition (Wiens et al, 2022).…”

Section: Máaz Formation Membersmentioning

confidence: 99%

“…A main objective of the crater floor campaign was to collect samples from the crater‐retaining part of the Máaz formation to enable calculations of absolute age for the Máaz formation that could then be related to crater‐count ages for the unit (Section 3.1). Though this objective was accomplished, it is likely that any crater‐count derived ages may reflect the exhumation age of Máaz, rather than the formation age of the unit (Quantin‐Nataf et al., 2021). Future absolute ages derived for the Ch'ał samples will still be useful to reconstruct the timeline of events in Jezero crater, but the potential barrier to calibrating the absolute ages with the Mars crater chronology models is an inherent challenge.…”

Section: Campaign Summary and Debriefmentioning

confidence: 99%

Overview and Results From the Mars 2020 Perseverance Rover's First Science Campaign on the Jezero Crater Floor

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The Mars 2020 Perseverance rover landed in Jezero crater on 18 February 2021. After a 100‐sol period of commissioning and the Ingenuity Helicopter technology demonstration, Perseverance began its first science campaign to explore the enigmatic Jezero crater floor, whose igneous or sedimentary origins have been much debated in the scientific community. This paper describes the campaign plan developed to explore the crater floor's Máaz and Séítah formations and summarizes the results of the campaign between sols 100–379. By the end of the campaign, Perseverance had traversed more than 5 km, created seven abrasion patches, and sealed nine samples and a witness tube. Analysis of remote and proximity science observations show that the Máaz and Séítah formations are igneous in origin and composed of five and two geologic members, respectively. The Séítah formation represents the olivine‐rich cumulate formed from differentiation of a slowly cooling melt or magma body, and the Máaz formation likely represents a separate series of lava flows emplaced after Séítah. The Máaz and Séítah rocks also preserve evidence of multiple episodes of aqueous alteration in secondary minerals like carbonate, Fe/Mg phyllosilicates, sulfates, and perchlorate, and surficial coatings. Post‐emplacement processes tilted the rocks near the Máaz‐Séítah contact and substantial erosion modified the crater floor rocks to their present‐day expressions. Results from this crater floor campaign, including those obtained upon return of the collected samples, will help to build the geologic history of events that occurred in Jezero crater and provide time constraints on the formation of the Jezero delta.

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The Complex Exhumation History of Jezero Crater Floor Unit and Its Implication for Mars Sample Return

Cited by 13 publications

References 61 publications

Diverse Lava Flow Morphologies in the Stratigraphy of the Jezero Crater Floor

Diverse Lava Flow Morphologies in the Stratigraphy of the Jezero Crater Floor

Samples Collected From the Floor of Jezero Crater With the Mars 2020 Perseverance Rover

Overview and Results From the Mars 2020 Perseverance Rover's First Science Campaign on the Jezero Crater Floor

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