An Examination of Soil Crusts on the Floor of Jezero Crater, Mars

Hausrath, Elisabeth M.; Adcock, Chris; Bechtold, Andreas; Beck, P.; Benison, Kathleen C.; Brown, A. J.; Cardarelli, E.; Carman, N.A.; Chide, Baptiste; Christian, John; Clark, B. C.; Cloutis, E. A.; Cousin, A.; Forni, O.; Gabriel, T. S. J.; Gasnault, O.; Golombek, M.; Gómez, Felipe; Hecht, Michael H.; Henley, T.; Huidobro, Jennifer; Johnson, J. R.; Jones, Michael W. M.; Kelemen, P. B.; Knight, Alfred B.; Lasue, J.; Mouélic, S. Le; Madariaga, Juan Manuel; Maki, Justin N.; Mandon, Lucia; Martínez, G.; Martínez‐Frías, Jesús; McConnochie, T. H.; Meslin, P. Y.; Zorzano, María Paz; Newsom, H. E.; Paar, Gerhard; Randazzo, Nicolas; Royer, Clément; Siljeström, Sandra; Schmidt, M. E.; Schröder, Susanne; Sephton, Mark A.; Sullivan, Robert; Turenne, Nathalie; Udry, Arya; VanBommel, S. J.; Vaughan, Alicia; Wiens, Roger C.; Williams, Nathan; team, the SuperCam; group, the Regolith working

doi:10.1029/2022je007433

Cited by 9 publications

(13 citation statements)

References 90 publications

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“…In addition, this is consistent with the recent identification of starkeyite at Gale crater (Chipera et al, 2023). MEDA measurements of local temperature, humidity and pressures in Jezero crater at the time of collection of these data also confirm that starkeyite would most likely have been stable (Hausrath et al, 2023).…”

Section: Hydration Stability and Implications For The Water Cycle On ...supporting

confidence: 86%

“…Sulfate minerals typically occur within Martian dust and soils (e.g., B. C. Clark & Van Hart, 1981; Kounaves et al., 2010; Wang, Haskin, et al., 2006); in light‐toned deposits present inside canyons, in chaos terrain, and within sedimentary rocks of Meridiani Planum (e.g., Ehlmann & Edwards, 2014; Gendrin et al., 2005; Wang et al., 2016); as evaporites or diagenetic precipitates in sedimentary rocks (e.g., McLennan et al., 2005; Rapin et al., 2019); and as mineralized veins that cross‐cut local stratigraphy (e.g., Kronyak et al., 2019; Nachon et al., 2014). In Jezero crater, sulfate phases have been detected in igneous units (Corpolongo et al., 2023; Mandon et al., 2023), regolith targets (Hausrath et al., 2023), and recently in the fan front (Hurowitz et al., 2023; Phua et al., 2023; Roppel et al., 2023). Sulfate minerals can hold water in two ways: (a) as part of the crystal structure in the case of hydrated sulfate phases, and (b) as fluid inclusions within sulfate crystals.…”

Section: Introductionmentioning

confidence: 99%

“…Sulfate, perchlorate, and chloride salts can extract water from (and release it to) the atmosphere under present‐day martian environmental conditions either by undergoing hydration, deliquescence, or by forming liquid brines (Gough et al., 2011; Martin‐Torres et al., 2015; Toner et al., 2016; Zorzano et al., 2009). Perseverance's instruments have detected the presence of hydrated Ca‐ and Mg‐sulfate minerals in Jezero crater rocks (Corpolongo et al., 2023; Mandon et al., 2023) and regolith targets (Hausrath et al., 2023). Observations by the Perseverance instrument Mars Environmental Dynamics Analyzer (MEDA) indicate the possibility of diurnal and seasonal changes in the hydration of Mg‐sulfate and Ca‐sulfate salts (Hausrath et al., 2023).…”

Section: Introductionmentioning

confidence: 99%

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Evidence of Sulfate‐Rich Fluid Alteration in Jezero Crater Floor, Mars

Siljeström,

Czaja,

Corpolongo

et al. 2024

JGR Planets

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Sulfur plays a major role in martian geochemistry and sulfate minerals are important repositories of water. However, their hydration states on Mars are poorly constrained. Therefore, understanding the hydration and distribution of sulfate minerals on Mars is important for understanding its geologic, hydrologic, and atmospheric evolution as well as its habitability potential. NASA's Perseverance rover is currently exploring the Noachian‐age Jezero crater, which hosts a fan‐delta system associated with a paleolake. The crater floor includes two igneous units (the Séítah and Máaz formations), both of which contain evidence of later alteration by fluids including sulfate minerals. Results from the rover instruments Scanning Habitable Environments with Raman and Luminescence for Organics and Chemistry and Planetary Instrument for X‐ray Lithochemistry reveal the presence of a mix of crystalline and amorphous hydrated Mg‐sulfate minerals (both MgSO4·[3–5]H2O and possible MgSO4·H2O), and anhydrous Ca‐sulfate minerals. The sulfate phases within each outcrop may have formed from single or multiple episodes of water activity, although several depositional events seem likely for the different units in the crater floor. Textural and chemical evidence suggest that the sulfate minerals most likely precipitated from a low temperature sulfate‐rich fluid of moderate pH. The identification of approximately four waters puts a lower constraint on the hydration state of sulfate minerals in the shallow subsurface, which has implications for the martian hydrological budget. These sulfate minerals are key samples for future Mars sample return.

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Section: Hydration Stability and Implications For The Water Cycle On ...supporting

confidence: 86%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evidence of Sulfate‐Rich Fluid Alteration in Jezero Crater Floor, Mars

Siljeström,

Czaja,

Corpolongo

et al. 2024

JGR Planets

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“…The combination of environmental forcing through aeolian erosion, mechanical forcing from wind and pressure fluctuations, or thermodynamical forcing via changes in temperature and atmospheric composition, including water vapor, can cause a range of surface patterns. Some models that include environmental forcings from erosion and deposition represent them through a stochastic function that contains the statistical properties of environmental variability (e.g., Bosak et al., 2013; Cuerno et al., 2011; Grotzinger & Rothman, 1996; Hausrath et al., 2022).…”

Section: Introductionmentioning

confidence: 99%

Diurnal Cycle of Rapid Air Temperature Fluctuations at Jezero Crater: Probability Distributions, Exponential Tails, Scaling, and Intermittency

et al. 2023

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“…Previous work on Mars has identified evidence of fractures in the soil surface that indicate the presence of crust in multiple locations site (e.g., Blake et al., 2013; Sullivan et al., 2008) indicating that this is a common phenomenon on Mars. The characteristics of the crust and extent of induration, as evidenced in the 3D observation of cracks and fractures, as well as tracks, sheds important light on the characteristics of the crust (Hausrath et al., 2023). The fractures indicate evidence of induration, which may also indicate the presence of hydration and salts.…”

Section: Mastcam‐z 3d Vision Data Products and Presentation Science U...mentioning

confidence: 99%

Three‐Dimensional Data Preparation and Immersive Mission‐Spanning Visualization and Analysis of Mars 2020 Mastcam‐Z Stereo Image Sequences

Paar

Ortner

Tate

et al. 2023

Earth and Space Science

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The Mars 2020 Mastcam-Z stereo camera investigation enables the generation of three dimension (3D) data products needed to visualize and analyze rocks, outcrops, and other geological and aeolian features. The Planetary Robotics Vision Processing framework "PRoViP" as well as the Instrument Data System on a tactical-sol-by-sol-timeframe generate 3D vision products, such as panoramas, distance maps, and textured meshes. Structure-from-motion used by the Advanced Science Targeting Toolkit for Robotic Operations (ASTTRO) "Landform" tool and long baseline stereo pipelines add to the 3D vision products' suite on various scales. Data fusion with textured meshes from satellite imagery and 3D data analysis and interpretation of the resulting large 3D data sets is realized by visualization assets like the Planetary Robotics Vision 3D Viewer PRo3D, the 3D Geographical Information System GIS CAMP (Campaign Analysis Mapping and Planning tool), the ASTTRO 3D data presentation and targeting tool, and the Mastcam-Z planning tool Viewpoint. The pipelines' workflows and the user-oriented features of the visualization assets, shared across the Mars 2020 mission, are reported. The individual role and interplay, complements and synergies of the individual frameworks are explained. Emphasis is laid on publicly available 3D vision data products and tools. A representative set of scientific use cases from planetary geology, aeolian activity, soil analysis and impact science illustrates the scientific workflow, and public data deployment modes are briefly outlined, demonstrating that 3D vision processing and visualization is an essential mission-wide asset to solve important planetary science questions such as prevailing wind direction, soil composition, or geologic origin.Plain Language Summary Image processing enables to describe the surface of Mars in three dimension (3D) using the Mastcam-Z stereo cameras' images. The 3D reconstruction of the rocks, geological outcrops, as well as aeolian and mineralogical features, are crucial for understanding the planet's past. Image processing tools to reconstruct the surface of Mars from the images are available to the Mars 2020 Team, generating 3D data products with various information about the surface on Mars like elevation maps or distance maps that record the 3D coordinates of each point. To interpret these products, tools needed for their visualization and analysis are presented here. In a combination with data from other sensors or sourcesincluding 3D models obtained from satellite, and at different scales the interpretation of the processed products is enhanced. The reader learns about the synergies and interplay between these tools, including publicly available tools. Demonstrative planetary science examples, processed by the Mastcam-Z science team with the above mentioned tools, are presented. Geological features, such as wind activity, soil analysis, and impact science, are analyzed, illustrating the scientific work carried out and in particular the benefit of 3D vision processing and...

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An Examination of Soil Crusts on the Floor of Jezero Crater, Mars

Cited by 9 publications

References 90 publications

Evidence of Sulfate‐Rich Fluid Alteration in Jezero Crater Floor, Mars

Evidence of Sulfate‐Rich Fluid Alteration in Jezero Crater Floor, Mars

Diurnal Cycle of Rapid Air Temperature Fluctuations at Jezero Crater: Probability Distributions, Exponential Tails, Scaling, and Intermittency

Three‐Dimensional Data Preparation and Immersive Mission‐Spanning Visualization and Analysis of Mars 2020 Mastcam‐Z Stereo Image Sequences

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