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1. Iron isotopes and the redox evolution of Ediacaran sediments

Author

Moynier, Frederic, Fike, David A., Menard, Gabrielle, Fischer, Woodward W., Grotzinger, John P., and Agranier, Arnaud

Subjects
Geochemistry, Ediacara, Shuram excursion, Fe isotopes, Oxygenation, Redox change, Ocean, Geophysics. Cosmic physics, QC801-809, Chemistry, QD1-999, Geology, QE1-996.5
Abstract

The Ediacaran age (ca. 570 Ma) Shuram excursion, a ca. $12‰$ depletion in $\delta ^{13}\mathrm{C}_{\mathrm{carb}}$, may record a dramatic oxidation of marine sediments associated with a reorganization of Earth’s carbon cycle closely preceding the rise of large metazoans. However, several geochemical indicators suggest it may instead record secondary processes affecting the sediments such as post-depositional alteration. The stable isotopic composition of iron incorporated within carbonates $(\delta ^{56}\mathrm{Fe}_{\mathrm{carb}})$ reveals an anomalous $^{56}\mathrm{Fe}$-depletion (down to $-1.05‰$) in strata containing the Shuram excursion, while the underlying and overlying strata have crustal $\delta ^{56}\mathrm{Fe}_{\mathrm{carb}}$ values. These depleted $\delta ^{56}\mathrm{Fe}_{\mathrm{carb}}$ data during the Shuram excursion reflect incomplete reduction of iron oxides, limited by low ambient organic carbon contents. This elevated pulse of sedimentary iron oxides would consume the majority of the limited pool of organic carbon and therefore would give rise to very low net organic carbon burial during a time of enhanced detrital delivery of oxidized iron to the sediments. These results imply a syndepositional origin for the Shuram excursion, which represents a shift in the redox composition of Earth’s sedimentary shell toward more oxidizing conditions, perhaps removing a long-lived buffer on atmospheric oxygen.

Published
2021
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2. The PIXL Instrument on the Mars 2020 Perseverance Rover

Author

Allwood, Abigail C., Hurowitz, Joel A., Clark, Benton C., Cinquini, Luca, Davidoff, Scott, Denise, Robert W., Elam, W. Timothy, Foote, Marc C., Flannery, David T., Gerhard, James H., Grotzinger, John P., Heirwegh, Christopher M., Hernandez, Christina, Hodyss, Robert P., Jones, Michael W., Jorgensen, John Leif, Henneke, Jesper, Lawson, Peter R., Liu, Yang, MacDonald, Haley, McLennan, Scott M., Moore, Kelsey R., Nachon, Marion, Nemere, Peter, O'Neil, Lauren, Pedersen, David A. K., Sinclair, Kimberly P., Sondheim, Michael E., Song, Eugenie, Tallarida, Nicholas R., Tice, Michael M., Treiman, Alan, Uckert, Kyle, Wade, Lawrence A., Young, Jimmie D., and Zamani, Payam

Subjects
Physics - Instrumentation and Detectors, Physics - Applied Physics
Abstract

The Planetary Instrument for X-ray Lithochemistry (PIXL) is a micro-focus X-ray fluorescence spectrometer mounted on the robotic arm of NASA's Perseverance rover. PIXL will acquire high spatial resolution observations of rock and soil chemistry, rapidly analyzing the elemental chemistry of a target surface. In 10 seconds, PIXL can use its powerful 120 micrometer diameter X-ray beam to analyze a single, sand-sized grain with enough sensitivity to detect major and minor rock-forming elements, as well as many trace elements. Over a period of several hours, PIXL can autonomously scan an area of the rock surface and acquire a hyperspectral map comprised of several thousand individual measured points., Comment: 2 pages, from 52nd Lunar and Planetary Science Conference, https://www.hou.usra.edu/meetings/lpsc2021/pdf/1591.pdf

Published
2021

7. The power of paired proximity science observations: Co-located data from SHERLOC and PIXL on Mars

Author

Razzell Hollis, Joseph, Moore, Kelsey R., Sharma, Sunanda, Beegle, Luther, Grotzinger, John P., Allwood, Abigail, Abbey, William, Bhartia, Rohit, Brown, Adrian J., Clark, Benton, Cloutis, Edward, Corpolongo, Andrea, Henneke, Jesper, Hickman-Lewis, Keyron, Hurowitz, Joel A., Jones, Michael W.M., Liu, Yang, Martinez-Frías, Jesús, Murphy, Ashley, Pedersen, David A.K., Shkolyar, Svetlana, Siljeström, Sandra, Steele, Andrew, Tice, Mike, Treiman, Alan, Uckert, Kyle, VanBommel, Scott, and Yanchilina, Anastasia

Published
2022
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8. Demosponge steroid biomarker 26-methylstigmastane provides evidence for Neoproterozoic animals

Author

Zumberge, J Alex, Love, Gordon D, Cárdenas, Paco, Sperling, Erik A, Gunasekera, Sunithi, Rohrssen, Megan, Grosjean, Emmanuelle, Grotzinger, John P, and Summons, Roger E

Subjects
Life Below Water, Animals, Biological Evolution, Biomarkers, Fossils, Phylogeny, Porifera, Steroids
Abstract

Sterane biomarkers preserved in ancient sedimentary rocks hold promise for tracking the diversification and ecological expansion of eukaryotes. The earliest proposed animal biomarkers from demosponges (Demospongiae) are recorded in a sequence around 100 Myr long of Neoproterozoic-Cambrian marine sedimentary strata from the Huqf Supergroup, South Oman Salt Basin. This C30 sterane biomarker, informally known as 24-isopropylcholestane (24-ipc), possesses the same carbon skeleton as sterols found in some modern-day demosponges. However, this evidence is controversial because 24-ipc is not exclusive to demosponges since 24-ipc sterols are found in trace amounts in some pelagophyte algae. Here, we report a new fossil sterane biomarker that co-occurs with 24-ipc in a suite of late Neoproterozoic-Cambrian sedimentary rocks and oils, which possesses a rare hydrocarbon skeleton that is uniquely found within extant demosponge taxa. This sterane is informally designated as 26-methylstigmastane (26-mes), reflecting the very unusual methylation at the terminus of the steroid side chain. It is the first animal-specific sterane marker detected in the geological record that can be unambiguously linked to precursor sterols only reported from extant demosponges. These new findings strongly suggest that demosponges, and hence multicellular animals, were prominent in some late Neoproterozoic marine environments at least extending back to the Cryogenian period.

Published
2018

11. Mineralogy, provenance, and diagenesis of a potassic basaltic sandstone on Mars: CheMin X-ray diffraction of the Windjana sample (Kimberley area, Gale Crater).

Author

Treiman, Allan H, Bish, David L, Vaniman, David T, Chipera, Steve J, Blake, David F, Ming, Doug W, Morris, Richard V, Bristow, Thomas F, Morrison, Shaunna M, Baker, Michael B, Rampe, Elizabeth B, Downs, Robert T, Filiberto, Justin, Glazner, Allen F, Gellert, Ralf, Thompson, Lucy M, Schmidt, Mariek E, Le Deit, Laetitia, Wiens, Roger C, McAdam, Amy C, Achilles, Cherie N, Edgett, Kenneth S, Farmer, Jack D, Fendrich, Kim V, Grotzinger, John P, Gupta, Sanjeev, Morookian, John Michael, Newcombe, Megan E, Rice, Melissa S, Spray, John G, Stolper, Edward M, Sumner, Dawn Y, Vasavada, Ashwin R, and Yen, Albert S

Subjects
CheMin, MSL, Mars, Windjana, X‐ray diffraction, sandstone, X-ray diffraction, Astronomical and Space Sciences, Geochemistry, Geology
Abstract

The Windjana drill sample, a sandstone of the Dillinger member (Kimberley formation, Gale Crater, Mars), was analyzed by CheMin X-ray diffraction (XRD) in the MSL Curiosity rover. From Rietveld refinements of its XRD pattern, Windjana contains the following: sanidine (21% weight, ~Or95); augite (20%); magnetite (12%); pigeonite; olivine; plagioclase; amorphous and smectitic material (~25%); and percent levels of others including ilmenite, fluorapatite, and bassanite. From mass balance on the Alpha Proton X-ray Spectrometer (APXS) chemical analysis, the amorphous material is Fe rich with nearly no other cations-like ferrihydrite. The Windjana sample shows little alteration and was likely cemented by its magnetite and ferrihydrite. From ChemCam Laser-Induced Breakdown Spectrometer (LIBS) chemical analyses, Windjana is representative of the Dillinger and Mount Remarkable members of the Kimberley formation. LIBS data suggest that the Kimberley sediments include at least three chemical components. The most K-rich targets have 5.6% K2O, ~1.8 times that of Windjana, implying a sediment component with >40% sanidine, e.g., a trachyte. A second component is rich in mafic minerals, with little feldspar (like a shergottite). A third component is richer in plagioclase and in Na2O, and is likely to be basaltic. The K-rich sediment component is consistent with APXS and ChemCam observations of K-rich rocks elsewhere in Gale Crater. The source of this sediment component was likely volcanic. The presence of sediment from many igneous sources, in concert with Curiosity's identifications of other igneous materials (e.g., mugearite), implies that the northern rim of Gale Crater exposes a diverse igneous complex, at least as diverse as that found in similar-age terranes on Earth.

Published
2016

14. The origin and implications of clay minerals from Yellowknife Bay, Gale crater, Mars

Author

Bristow, Thomas F, Bish, David L, Vaniman, David T, Morris, Richard V, Blake, David F, Grotzinger, John P, Rampe, Elizabeth B, Crisp, Joy A, Achilles, Cherie N, Ming, Doug W, Ehlmann, Bethany L, King, Penelope L, Bridges, John C, Eigenbrode, Jennifer L, Sumner, Dawn Y, Chipera, Steve J, Moorokian, John Michael, Treiman, Allan H, Morrison, Shaunna M, Downs, Robert T, Farmer, Jack D, Marais, David Des, Sarrazin, Philippe, Floyd, Melissa M, Mischna, Michael A, and McAdam, Amy C

Subjects
Earth Sciences, Geochemistry, Geology, Mars, Yellowknife Bay, clay minerals, CheMin, XRD, habitability, Resources Engineering and Extractive Metallurgy, Geochemistry & Geophysics
Abstract

The Mars Science Laboratory (MSL) rover Curiosity has documented a section of fluvio-lacustrine strata at Yellowknife Bay (YKB), an embayment on the floor of Gale crater, approximately 500 m east of the Bradbury landing site. X-ray diffraction (XRD) data and evolved gas analysis (EGA) data from the CheMin and SAM instruments show that two powdered mudstone samples (named John Klein and Cumberland) drilled from the Sheepbed member of this succession contain up to ~20 wt% clay minerals. A trioctahedral smectite, likely a ferrian saponite, is the only clay mineral phase detected in these samples. Smectites of the two samples exhibit different 001 spacing under the low partial pressures of H2O inside the CheMin instrument (relative humidity

Published
2015

15. Organic matter preserved in 3-billion-year-old mudstones at Gale crater, Mars

Author

Eigenbrode, Jennifer L., Summons, Roger E., Steele, Andrew, Freissinet, Caroline, Millan, Maëva, Navarro-González, Rafael, Sutter, Brad, McAdam, Amy C., Franz, Heather B., Glavin, Daniel P., Archer, Paul D., Mahaffy, Paul R., Conrad, Pamela G., Hurowitz, Joel A., Grotzinger, John P., Gupta, Sanjeev, Ming, Doug W., Sumner, Dawn Y., Szopa, Cyril, Malespin, Charles, Buch, Arnaud, and Coll, Patrice

Published
2018

17. Correction to: PIXL: Planetary Instrument for X-Ray Lithochemistry

Author

Allwood, Abigail C., Wade, Lawrence A., Foote, Marc C., Elam, William Timothy, Hurowitz, Joel A., Battel, Steven, Dawson, Douglas E., Denise, Robert W., Ek, Eric M., Gilbert, Martin S., King, Matthew E., Liebe, Carl Christian, Parker, Todd, Pedersen, David A. K., Randall, David P., Sharrow, Robert F., Sondheim, Michael E., Allen, George, Arnett, Kenneth, Au, Mitchell H., Basset, Christophe, Benn, Mathias, Bousman, John C., Braun, David, Calvet, Robert J., Clark, Benton, Cinquini, Luca, Conaby, Sterling, Conley, Henry A., Davidoff, Scott, Delaney, Jenna, Denver, Troelz, Diaz, Ernesto, Doran, Gary B., Ervin, Joan, Evans, Michael, Flannery, David T., Gao, Ning, Gross, Johannes, Grotzinger, John, Hannah, Brett, Harris, Jackson T., Harris, Cathleen M., He, Yejun, Heirwegh, Christopher M., Hernandez, Christina, Hertzberg, Eric, Hodyss, Robert P., Holden, James R., Hummel, Christopher, Jadusingh, Matthew A., Jørgensen, John L., Kawamura, Jonathan H., Kitiyakara, Amarit, Kozaczek, Kris, Lambert, James L., Lawson, Peter R., Liu, Yang, Luchik, Thomas S., Macneal, Kristen M., Madsen, Soren N., McLennan, Scott M., McNally, Patrick, Meras, Patrick L., Muller, Richard E., Napoli, Jamie, Naylor, Bret J., Nemere, Peter, Ponomarev, Igor, Perez, Raul M., Pootrakul, Napat, Romero, Raul A., Rosas, Rogelio, Sachs, Jared, Schaefer, Rembrandt T., Schein, Michael E., Setterfield, Timothy P., Singh, Vritika, Song, Eugenie, Soria, Mary M., Stek, Paul C., Tallarida, Nicholas R., Thompson, David R., Tice, Michael M., Timmermann, Lars, Torossian, Violet, Treiman, Allan, Tsai, Shihchuan, Uckert, Kyle, Villalvazo, Juan, Wang, Mandy, Wilson, Daniel W., Worel, Shana C., Zamani, Payam, Zappe, Mike, Zhong, Fang, and Zimmerman, Richard

Published
2021
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18. The SuperCam Instrument Suite on the NASA Mars 2020 Rover: Body Unit and Combined System Tests

Author

Wiens, Roger C., Maurice, Sylvestre, Robinson, Scott H., Nelson, Anthony E., Cais, Philippe, Bernardi, Pernelle, Newell, Raymond T., Clegg, Sam, Sharma, Shiv K., Storms, Steven, Deming, Jonathan, Beckman, Darrel, Ollila, Ann M., Gasnault, Olivier, Anderson, Ryan B., André, Yves, Michael Angel, S., Arana, Gorka, Auden, Elizabeth, Beck, Pierre, Becker, Joseph, Benzerara, Karim, Bernard, Sylvain, Beyssac, Olivier, Borges, Louis, Bousquet, Bruno, Boyd, Kerry, Caffrey, Michael, Carlson, Jeffrey, Castro, Kepa, Celis, Jorden, Chide, Baptiste, Clark, Kevin, Cloutis, Edward, Cordoba, Elizabeth C., Cousin, Agnes, Dale, Magdalena, Deflores, Lauren, Delapp, Dorothea, Deleuze, Muriel, Dirmyer, Matthew, Donny, Christophe, Dromart, Gilles, George Duran, M., Egan, Miles, Ervin, Joan, Fabre, Cecile, Fau, Amaury, Fischer, Woodward, Forni, Olivier, Fouchet, Thierry, Fresquez, Reuben, Frydenvang, Jens, Gasway, Denine, Gontijo, Ivair, Grotzinger, John, Jacob, Xavier, Jacquinod, Sophie, Johnson, Jeffrey R., Klisiewicz, Roberta A., Lake, James, Lanza, Nina, Laserna, Javier, Lasue, Jeremie, Le Mouélic, Stéphane, Legett, IV, Carey, Leveille, Richard, Lewin, Eric, Lopez-Reyes, Guillermo, Lorenz, Ralph, Lorigny, Eric, Love, Steven P., Lucero, Briana, Madariaga, Juan Manuel, Madsen, Morten, Madsen, Soren, Mangold, Nicolas, Manrique, Jose Antonio, Martinez, J. P., Martinez-Frias, Jesus, McCabe, Kevin P., McConnochie, Timothy H., McGlown, Justin M., McLennan, Scott M., Melikechi, Noureddine, Meslin, Pierre-Yves, Michel, John M., Mimoun, David, Misra, Anupam, Montagnac, Gilles, Montmessin, Franck, Mousset, Valerie, Murdoch, Naomi, Newsom, Horton, Ott, Logan A., Ousnamer, Zachary R., Pares, Laurent, Parot, Yann, Pawluczyk, Rafal, Glen Peterson, C., Pilleri, Paolo, Pinet, Patrick, Pont, Gabriel, Poulet, Francois, Provost, Cheryl, Quertier, Benjamin, Quinn, Heather, Rapin, William, Reess, Jean-Michel, Regan, Amy H., Reyes-Newell, Adriana L., Romano, Philip J., Royer, Clement, Rull, Fernando, Sandoval, Benigno, Sarrao, Joseph H., Sautter, Violaine, Schoppers, Marcel J., Schröder, Susanne, Seitz, Daniel, Shepherd, Terra, Sobron, Pablo, Dubois, Bruno, Sridhar, Vishnu, Toplis, Michael J., Torre-Fdez, Imanol, Trettel, Ian A., Underwood, Mark, Valdez, Andres, Valdez, Jacob, Venhaus, Dawn, and Willis, Peter

Published
2021
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19. PIXL: Planetary Instrument for X-Ray Lithochemistry

Author

Allwood, Abigail C., Wade, Lawrence A., Foote, Marc C., Elam, William Timothy, Hurowitz, Joel A., Battel, Steven, Dawson, Douglas E., Denise, Robert W., Ek, Eric M., Gilbert, Martin S., King, Matthew E., Liebe, Carl Christian, Parker, Todd, Pedersen, David A. K., Randall, David P., Sharrow, Robert F., Sondheim, Michael E., Allen, George, Arnett, Kenneth, Au, Mitchell H., Basset, Christophe, Benn, Mathias, Bousman, John C., Braun, David, Calvet, Robert J., Clark, Benton, Cinquini, Luca, Conaby, Sterling, Conley, Henry A., Davidoff, Scott, Delaney, Jenna, Denver, Troelz, Diaz, Ernesto, Doran, Gary B., Ervin, Joan, Evans, Michael, Flannery, David O., Gao, Ning, Gross, Johannes, Grotzinger, John, Hannah, Brett, Harris, Jackson T., Harris, Cathleen M., He, Yejun, Heirwegh, Christopher M., Hernandez, Christina, Hertzberg, Eric, Hodyss, Robert P., Holden, James R., Hummel, Christopher, Jadusingh, Matthew A., Jørgensen, John L., Kawamura, Jonathan H., Kitiyakara, Amarit, Kozaczek, Kris, Lambert, James L., Lawson, Peter R., Liu, Yang, Luchik, Thomas S., Macneal, Kristen M., Madsen, Soren N., McLennan, Scott M., McNally, Patrick, Meras, Patrick L., Muller, Richard E., Napoli, Jamie, Naylor, Bret J., Nemere, Peter, Ponomarev, Igor, Perez, Raul M., Pootrakul, Napat, Romero, Raul A., Rosas, Rogelio, Sachs, Jared, Schaefer, Rembrandt T., Schein, Michael E., Setterfield, Timothy P., Singh, Vritika, Song, Eugenie, Soria, Mary M., Stek, Paul C., Tallarida, Nicholas R., Thompson, David R., Tice, Michael M., Timmermann, Lars, Torossian, Violet, Treiman, Allan, Tsai, Shihchuan, Uckert, Kyle, Villalvazo, Juan, Wang, Mandy, Wilson, Daniel W., Worel, Shana C., Zamani, Payam, Zappe, Mike, Zhong, Fang, and Zimmerman, Richard

Published
2020
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21. Manganese-Iron Phosphate Nodules at the Groken Site, Gale Crater, Mars

Author

Treiman, Allan H., primary, Lanza, Nina L., additional, VanBommel, Scott, additional, Berger, Jeff, additional, Wiens, Roger, additional, Bristow, Thomas, additional, Johnson, Jeffrey, additional, Rice, Melissa, additional, Hart, Reginald, additional, McAdam, Amy, additional, Gasda, Patrick, additional, Meslin, Pierre-Yves, additional, Yen, Albert, additional, Williams, Amy J., additional, Vasavada, Ashwin, additional, Vaniman, David, additional, Tu, Valerie, additional, Thorpe, Michael, additional, Swanner, Elizabeth D., additional, Seeger, Christina, additional, Schwenzer, Susanne P., additional, Schröder, Susanne, additional, Rampe, Elizabeth, additional, Rapin, William, additional, Ralston, Silas J., additional, Peretyazhko, Tanya, additional, Newsom, Horton, additional, Morris, Richard V., additional, Ming, Douglas, additional, Loche, Matteo, additional, Le Mouélic, Stéphane, additional, House, Christopher, additional, Hazen, Robert, additional, Grotzinger, John P., additional, Gellert, Ralf, additional, Gasnault, Olivier, additional, Fischer, Woodward W., additional, Essunfeld, Ari, additional, Downs, Robert T., additional, Downs, Gordon W., additional, Dehouck, Erwin, additional, Crossey, Laura J., additional, Cousin, Agnes, additional, Comellas, Jade M., additional, Clark, Joanna V., additional, Clark, Benton, additional, Chipera, Steve, additional, Caravaca, Gwenaël, additional, Bridges, John, additional, Blake, David F., additional, and Anderson, Ryan, additional

Published
2023
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23. Centimeter to decimeter hollow concretions and voids in Gale Crater sediments, Mars

Author

Wiens, Roger C., Rubin, David M., Goetz, Walter, Fairén, Alberto G., Schwenzer, Susanne P., Johnson, Jeffrey R., Milliken, Ralph, Clark, Ben, Mangold, Nicolas, Stack, Kathryn M., Oehler, Dorothy, Rowland, Scott, Chan, Marjorie, Vaniman, David, Maurice, Sylvestre, Gasnault, Olivier, Rapin, William, Schroeder, Susanne, Clegg, Sam, Forni, Olivier, Blaney, Diana, Cousin, Agnes, Payré, Valerie, Fabre, Cecile, Nachon, Marion, Le Mouelic, Stephane, Sautter, Violaine, Johnstone, Stephen, Calef, Fred, Vasavada, Ashwin R., and Grotzinger, John P.

Published
2017
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28. Geomorphic and environmental controls on microbial mat fabrics on Little Ambergris Cay, Turks and Caicos Islands

Author

Stein, Nathaniel T., primary, Grotzinger, John P., additional, Quinn, Daven P., additional, Lingappa, Usha F., additional, Present, Theodore M., additional, Trower, Elizabeth J., additional, Gomes, Maya L., additional, Orzechowski, Emily, additional, Cantine, Marjorie, additional, Metcalfe, Kyle S., additional, Fischer, Woodward W., additional, Ehlmann, Bethany L., additional, Strauss, Justin V., additional, and Knoll, Andrew H., additional

Published
2023
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29. Late Permian Extinctions

Author

Martin, Ronald E., Vermeij, Geerat J., Dorritie, Daniel, Caldeira, Ken, Rampino, Michael R., Knoll, Andrew H., Bambach, Richard K., Canfield, Donald, Grotzinger, John P., Wignall, Paul B., and Twitchett, Richard J.

Published
1996

30. Geomorphic and environmental controls on microbial mat fabrics on Little Ambergris Cay, Turks and Caicos Islands

Author

Stein, Nathaniel T., Grotzinger, John P., Quinn, Daven P., Lingappa, Usha F., Present, Theodore M., Trower, Elizabeth J., Gomes, Maya L., Orzechowski, Emily, Cantine, Marjorie, Metcalfe, Kyle S., Fischer, Woodward W., Ehlmann, Bethany L., Strauss, Justin V., Knoll, Andrew H., Stein, Nathaniel T., Grotzinger, John P., Quinn, Daven P., Lingappa, Usha F., Present, Theodore M., Trower, Elizabeth J., Gomes, Maya L., Orzechowski, Emily, Cantine, Marjorie, Metcalfe, Kyle S., Fischer, Woodward W., Ehlmann, Bethany L., Strauss, Justin V., and Knoll, Andrew H.

Abstract

To interpret microbially influenced paleoenvironments in the sedimentary record, it is crucial to understand what processes control the development of microbial mats in modern environments. This article reports results from a multiyear study of Little Ambergris Cay, Turks and Caicos Islands, an uninhabited island floored by broad tracts of well-developed microbial mats on the wind-dominated and wave-dominated Caicos Platform. Uncrewed aerial vehicle-based imaging, differential global positioning system topographic surveys, radiocarbon data, and in situ sedimentological and microbial ecological observations were integrated to identify and quantify the environmental factors that influence the distribution and morphologies of Little Ambergris Cay microbial mats, including their response to large storm events. Based on these data, this study proposes that Little Ambergris Cay initially developed from the accretion and rapid lithification of carbonate sediment delivered by converging wave fronts in the lee of adjacent Big Ambergris Cay. Broad tracts of microbial mats developed during late Holocene time as the interior became restricted due to beach ridge development. Minor elevation differences regulate subaerial exposure time and lead to three categories of microbial mats, differentiated by surface texture and morphology: smooth mats, polygonal mats and blister mats. The surface texture and morphology of the mats is controlled by subaerial exposure time. In addition to elevation, the spatial distribution of mats is largely controlled by hydrodynamics and sediment transport during large storm events. This detailed assessment of the controls on mat formation and preservation at Little Ambergris Cay provides a framework within which to identify and understand the interactions between microbial communities and sediment transport processes in ancient high-energy carbonate depositional systems.

Published
2023

31. Silicic volcanism on Mars evidenced by tridymite in high-SiO₂ sedimentary rock at Gale crater

Author

Morris, Richard V., Vaniman, David T., Blake, David F., Gellert, Ralf, Chipera, Steve J., Rampe, Elizabeth B., Ming, Douglas W., Morrison, Shaunna M., Downs, Robert T., Treiman, Allan H., Yen, Albert S., Grotzinger, John P., Achilles, Cherie N., Bristow, Thomas F., Crisp, Joy A., Des Marais, David J., Farmer, Jack D., Fendrich, Kim V., Frydenvang, Jens, Graff, Trevor G., Morookian, John-Michael, Stolper, Edward M., and Schwenzer, Susanne P.

Published
2016

33. Barform deposits of the Carolyn Shoemaker formation, Gale crater, Mars

Author

Cardenas, Benjamin T., primary, Grotzinger, John P., additional, Lamb, Michael P., additional, Lewis, Kevin W., additional, Fedo, Christopher M., additional, Bryk, Alexander B., additional, Dietrich, William E., additional, Stein, Nathan, additional, Turner, Madison, additional, and Caravaca, Gwénaël, additional

Published
2022
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34. Curiosity at Vera Rubin Ridge: Major Findings and Implications for Habitability

Author

Fraeman, Abigail A, Sun, Vivian Zheng, Edgar, Lauren A, Fedo, Christopher, Fox, Valerie Kristen, Grotzinger, John P, Hardgrove, Craig, Horgan, Briony H. N, House, Christopher H, Jacobs, Samantha, Johnson, Jeffery Roy, Johnson, Sarah Stewart, Rampe, Elizabeth B, Salvatore, Mark R, Stack, Kathryn, Thopmson, Lucy M, Wellington, Danika F, Wiens, Roger C, Williams, Amy J, and Vasavada, Ashwin R

Subjects
Lunar And Planetary Science And Exploration
Published
2018

35. Geologic map of the Glen Torridon region, Gale crater, Mars

Author

Fedo, Christopher M., Bryk, Alex B., Edgar, Lauren A., Bennett, Kristen A., Fox, Valerie K., Dietrich, William E., Banham, Steven G., Gupta, Sanjeev, Stack, Kathryn M., Williams, Rebecca M.E., Grotzinger, John P., Stein, Nathan T., Rubin, David M., Caravaca, Gwenael, Arvidson, Raymond E., Hughes, Madison N., Fraeman, Abigail A., Vasavada, Ashwin R., Schieber, Juergen, and Sutter, Brad

Subjects
geologic map, Glen TorridonNNH15ZDA001N, stratigraphy, Gale crater, mars
Abstract

This is a stratigraphic-based geologic map of the Glen Torridon region, Gale crater, Mars around the locations studied by the Curiosity rover. This map accompanies Fedo et al. (2022, Journal of Geophysical Research - Planets). Corner coordinates for map area as follows Northwest: 137.3767, -4.7206 Northeast: 137.3919, -4.7206 Southwest: 137.3767, -4.7383 Southeast: 137.3919, -4.7383

Published
2022
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36. Geological, multispectral, and meteorological imaging results from the Mars 2020 Perseverance rover in Jezero crater

Author

Bell, James F., primary, Maki, Justin N., additional, Alwmark, Sanna, additional, Ehlmann, Bethany L., additional, Fagents, Sarah A., additional, Grotzinger, John P., additional, Gupta, Sanjeev, additional, Hayes, Alexander, additional, Herkenhoff, Ken E., additional, Horgan, Briony H. N., additional, Johnson, Jeffrey R., additional, Kinch, Kjartan B., additional, Lemmon, Mark T., additional, Madsen, Morten B., additional, Núñez, Jorge I., additional, Paar, Gerhard, additional, Rice, Melissa, additional, Rice, James W., additional, Schmitz, Nicole, additional, Sullivan, Robert, additional, Vaughan, Alicia, additional, Wolff, Mike J., additional, Bechtold, Andreas, additional, Bosak, Tanja, additional, Duflot, Louise E., additional, Fairén, Alberto G., additional, Garczynski, Brad, additional, Jaumann, Ralf, additional, Merusi, Marco, additional, Million, Chase, additional, Ravanis, Eleni, additional, Shuster, David L., additional, Simon, Justin, additional, St. Clair, Michael, additional, Tate, Christian, additional, Walter, Sebastian, additional, Weiss, Benjamin, additional, Bailey, Alyssa M., additional, Bertrand, Tanguy, additional, Beyssac, Olivier, additional, Brown, Adrian J., additional, Caballo-Perucha, Piluca, additional, Caplinger, Michael A., additional, Caudill, Christy M., additional, Cary, Francesca, additional, Cisneros, Ernest, additional, Cloutis, Edward A., additional, Cluff, Nathan, additional, Corlies, Paul, additional, Crawford, Kelsie, additional, Curtis, Sabrina, additional, Deen, Robert, additional, Dixon, Darian, additional, Donaldson, Christopher, additional, Barrington, Megan, additional, Ficht, Michelle, additional, Fleron, Stephanie, additional, Hansen, Michael, additional, Harker, David, additional, Howson, Rachel, additional, Huggett, Joshua, additional, Jacob, Samantha, additional, Jensen, Elsa, additional, Jensen, Ole B., additional, Jodhpurkar, Mohini, additional, Joseph, Jonathan, additional, Juarez, Christian, additional, Kah, Linda C., additional, Kanine, Oak, additional, Kristensen, Jessica, additional, Kubacki, Tex, additional, Lapo, Kristiana, additional, Magee, Angela, additional, Maimone, Michael, additional, Mehall, Greg L., additional, Mehall, Laura, additional, Mollerup, Jess, additional, Viúdez-Moreiras, Daniel, additional, Paris, Kristen, additional, Powell, Kathryn E., additional, Preusker, Frank, additional, Proton, Jon, additional, Rojas, Corrine, additional, Sallurday, Danny, additional, Saxton, Kim, additional, Scheller, Eva, additional, Seeger, Christiana H., additional, Starr, Mason, additional, Stein, Nathan, additional, Turenne, Nathalie, additional, Van Beek, Jason, additional, Winhold, Andrew G., additional, and Yingling, Rachel, additional

Published
2022
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38. In Situ Identification of Paleoarchean Biosignatures Using Colocated Perseverance Rover Analyses: Perspectives for In Situ Mars Science and Sample Return

Author

Hickman-Lewis, Keyron, primary, Moore, Kelsey R., additional, Hollis, Joseph J. Razzell, additional, Tuite, Michael L., additional, Beegle, Luther W., additional, Bhartia, Rohit, additional, Grotzinger, John P., additional, Brown, Adrian J., additional, Shkolyar, Svetlana, additional, Cavalazzi, Barbara, additional, and Smith, Caroline L., additional

Published
2022
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40. Shaler: in situ analysis of a fluvial sedimentary deposit on Mars

Author

Edgar, Lauren A., Gupta, Sanjeev, Rubin, David M., Lewis, Kevin W., Kocurek, Gary A., Anderson, Ryan B., Bell, James F., III, Dromart, Gilles, Edgett, Kenneth S., Grotzinger, John P., Hardgrove, Craig, Kah, Linda C., Leveille, Richard, Malin, Michael C., Mangold, Nicolas, Milliken, Ralph E., Minitti, Michelle, Palucis, Marisa, Rice, Melissa, Rowland, Scott K., Schieber, Juergen, Stack, Kathryn M., Sumner, Dawn Y., Wiens, Roger C., Williams, Rebecca M. E., and Williams, Amy J.

Published
2018
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41. Mars' Surface Radiation Environment Measured with the Mars Science Laboratory's Curiosity Rover

Author

MSL Science Team, Hassler, Donald M., Zeitlin, Cary, Wimmer-Schweingruber, Robert F., Ehresmann, Bent, Rafkin, Scot, Eigenbrode, Jennifer L., Brinza, David E., Weigle, Gerald, Böttcher, Stephan, Böhm, Eckart, Burmeister, Soenke, Guo, Jingnan, Köhler, Jan, Martin, Cesar, Reitz, Guenther, Cucinotta, Francis A., Kim, Myung-Hee, Grinspoon, David, Bullock, Mark A., Posner, Arik, Gómez-Elvira, Javier, Vasavada, Ashwin, and Grotzinger, John P.

Published
2014

43. In situ Identification of Paleoarchean Biosignatures Using Colocated Perseverance Rover Analyses: Perspectives for in situ Mars Science and Sample Return

Author

Hickman-Lewis, Keyron, Moore, Kelsey R., Hollis, Joseph J. Razzell, Tuite, Michael L., Beegle, Luther W., Bhartia, Rohit, Grotzinger, John P., Brown, Adrian J., Shkolyar, Svetlana, Cavalazzi, Barbara, and Smith, Caroline L.

Abstract

The NASA Mars 2020 Perseverance rover is currently exploring Jezero crater, a Noachian–Hesperian locality that once hosted a delta–lake system with high habitability and biosignature preservation potential. Perseverance conducts detailed appraisals of rock targets using a synergistic payload capable of geological characterization from kilometer to micron scales. The highest-resolution textural and chemical information will be provided by correlated WATSON (imaging), SHERLOC (deep-UV Raman and fluorescence spectroscopy), and PIXL (X-ray lithochemistry) analyses, enabling the distributions of organic and mineral phases within rock targets to be comprehensively established. Herein, we analyze Paleoarchean microbial mats from the ∼3.42 Ga Buck Reef Chert (Barberton greenstone belt, South Africa)—considered astrobiological analogues for a putative ancient martian biosphere—following a WATSON–SHERLOC–PIXL protocol identical to that conducted by Perseverance on Mars during all sampling activities. Correlating deep-UV Raman and fluorescence spectroscopic mapping with X-ray elemental mapping, we show that the Perseverance payload has the capability to detect thermally and texturally mature organic materials of biogenic origin and can highlight organic–mineral interrelationships and elemental colocation at fine spatial scales. We also show that the Perseverance protocol obtains very similar results to high-performance laboratory imaging, Raman spectroscopy, and μXRF instruments. This is encouraging for the prospect of detecting microscale organic-bearing textural biosignatures on Mars using the correlative micro-analytical approach enabled by WATSON, SHERLOC, and PIXL; indeed, laminated, organic-bearing samples such as those studied herein are considered plausible analogues of biosignatures from a potential Noachian–Hesperian biosphere. Were similar materials discovered at Jezero crater, they would offer opportunities to reconstruct aspects of the early martian carbon cycle and search for potential fossilized traces of life in ancient paleoenvironments. Such samples should be prioritized for caching and eventual return to Earth.

Published
2022

45. Burial and Exhumation of Sedimentary Rocks Revealed by the Base Stimson Erosional Unconformity, Gale Crater, Mars

Author

Watkins, Jessica A., primary, Grotzinger, John P., additional, Stein, Nathan T., additional, Banham, Steven G., additional, Gupta, Sanjeev, additional, Rubin, David M., additional, Morgan, Kathryn Stack, additional, Edgett, Kenneth S., additional, Frydenvang, Jens, additional, Siebach, Kirsten L., additional, Lamb, Michael P., additional, Sumner, Dawn Y., additional, and Lewis, Kevin W., additional

Published
2022
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49. A DELTA-LAKE SYSTEM AT JEZERO CRATER (MARS) FROM LONG DISTANCE OBSERVATIONS

Author

Sanjeev Gupta, Nicolas Mangold, Bell, Jim F., Olivier Gasnault, Tarnas, J. D., Sholes, S., Briony Horgan, Cathy Quantin-Nataf, Brown, A., Stéphane Le Mouélic, Roberta Yingst, Olivier Beyssac, Bosak, T., Fred Calef, Gwénaël CARAVACA, Ehlmann, B., Kenneth Farley, Grotzinger, John P., Hickman-Lewis, K., Holm-Alwmark, S., Kah, Linda C., Kanine, M., Martinez-Frias, J., Mclennan, Scott M., Sylvestre Maurice, Nuñez, J., Ollila, A. M., Gerhard Paar, Paolo Pilleri, Rice, J., Rice, M., Simon, J., Shuster, D., Katie Stack‐morgan, Vivian Sun, Treiman, Allan H., Weiss, B., Wiens, Roger C., Williams, A., Williams, N., Williford, Kenneth H., Department of Earth Science and Engineering [Imperial College London], Imperial College London, Laboratoire de Planétologie et Géosciences [UMR_C 6112] (LPG), Université d'Angers (UA)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Nantes université - UFR des Sciences et des Techniques (Nantes univ - UFR ST), Nantes Université - pôle Sciences et technologie, Nantes Université (Nantes Univ)-Nantes Université (Nantes Univ)-Nantes Université - pôle Sciences et technologie, Nantes Université (Nantes Univ)-Nantes Université (Nantes Univ), Arizona State University [Tempe] (ASU), Institut de recherche en astrophysique et planétologie (IRAP), Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Observatoire Midi-Pyrénées (OMP), Institut de Recherche pour le Développement (IRD)-Université Toulouse III - Paul Sabatier (UT3), Université de Toulouse (UT)-Université de Toulouse (UT)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Institut de Recherche pour le Développement (IRD)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National d'Études Spatiales [Toulouse] (CNES)-Centre National de la Recherche Scientifique (CNRS)-Météo-France -Centre National de la Recherche Scientifique (CNRS), Jet Propulsion Laboratory (JPL), NASA-California Institute of Technology (CALTECH), Purdue University [West Lafayette], Laboratoire de Géologie de Lyon - Terre, Planètes, Environnement (LGL-TPE), École normale supérieure de Lyon (ENS de Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Institut national des sciences de l'Univers (INSU - CNRS)-Université Jean Monnet - Saint-Étienne (UJM)-Centre National de la Recherche Scientifique (CNRS), Plancius Research LLC, Planetary Science Institute [Tucson] (PSI), Institut de minéralogie, de physique des matériaux et de cosmochimie (IMPMC), Muséum national d'Histoire naturelle (MNHN)-Institut de recherche pour le développement [IRD] : UR206-Sorbonne Université (SU)-Centre National de la Recherche Scientifique (CNRS), Massachusetts Institute of Technology (MIT), California Institute of Technology (CALTECH), The Natural History Museum [London] (NHM), Alma Mater Studiorum Università di Bologna [Bologna] (UNIBO), Niels Bohr Institute [Copenhagen] (NBI), Faculty of Science [Copenhagen], University of Copenhagen = Københavns Universitet (UCPH)-University of Copenhagen = Københavns Universitet (UCPH), Lund University [Lund], Natural History Museum of Denmark, The University of Tennessee [Knoxville], Instituto de Geociencias [Madrid] (IGEO), Universidad Complutense de Madrid = Complutense University of Madrid [Madrid] (UCM)-Consejo Superior de Investigaciones Científicas [Madrid] (CSIC), Department of Geosciences [Stony Brook], Stony Brook University [SUNY] (SBU), State University of New York (SUNY)-State University of New York (SUNY), JHUAPL, Los Alamos National Laboratory (LANL), Joanneum Research, College of Engineering and Science [Louisiana], Louisiana Tech University, Astromaterials Research and Exploration Science (ARES), NASA Johnson Space Center (JSC), NASA-NASA, Department of Earth and Planetary Science [UC Berkeley] (EPS), University of California [Berkeley] (UC Berkeley), University of California (UC)-University of California (UC), Lunar and Planetary Institute [Houston] (LPI), Department of Geological Sciences [Gainesville] (UF|Geological), University of Florida [Gainesville] (UF), and Lunar and Planetary Institute

Subjects
Jezero crater, delta, [SDU.STU.PL]Sciences of the Universe [physics]/Earth Sciences/Planetology, [SDU]Sciences of the Universe [physics], [SDU.STU.ST]Sciences of the Universe [physics]/Earth Sciences/Stratigraphy, Mars 2020, Mars, sedimentolgoy, stratigraphy, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences
Abstract

International audience; Orbital and rover observations of relictgeomorphic features and stratigraphic architectures indicate Mars once had a warmer, wetter climate. Constraining the character, relative timing and persistence of ancient aqueous activity on Mars is possible through detailed interrogation of the stratal geometry of aqueously deposited sedimentary bodies. Such analyses inform interpretations of Martian climate evolution, potential habitability, and search strategies for rocks that might contain potential biosignatures. A prominent sedimentary fan deposit at the westernmargin of Jezero crater has been inferred to be a river delta that built into an ancient lake basin during the Late Noachian-Early Hesperian epochs on Mars (~3.6-3.8 Ga) [1, 2, 3]. The Perseverance rover landed on 18 February 2021 ~2.2 km from the western fan. During the early phase of mission investigations, highresolution images obtained from the Mastcam-Z camera and from the Remote Micro-Imager of the SuperCaminstrument provided the first ground-based observations of the western fan and an associated remnant outcrop, named Kodiak. Here, we report its sedimentology, which provide new constraints on the nature of the fan deposits, and their paleoenvironmental implications (4).

Published
2022

50. Geological, multispectral, and meteorological imaging results from the Mars 2020 Perseverance rover in Jezero crater

Author

Bell, James F., Maki, Justin N., Alwmark, Sanna, Ehlmann, Bethany L., Fagents, Sarah A., Grotzinger, John P., Gupta, Sanjeev, Hayes, Alexander, Herkenhoff, Ken E., Horgan, Briony H. N., Johnson, Jeffrey R., Kinch, Kjartan B., Lemmon, Mark T., Madsen, Morten B., Nunez, Jorge, Paar, Gerhard, Rice, Melissa, Rice, James W., Schmitz, Nicole, Sullivan, Robert, Vaughan, Alicia, Wolff, Mike J., Bechtold, Andreas, Bosak, Tanja, Duflot, Louise E., Fairen, Alberto G., Garczynski, Brad, Jaumann, Ralf, Merusi, Marco, Million, Chase, Ravanis, Eleni, Shuster, David L., Simon, Justin, St Clair, Michael, Tate, Christian, Walter, Sebastian, Weiss, Benjamin, Bailey, Alyssa M., Bertrand, Tanguy, Beyssac, Olivier, Brown, Adrian J., Caballo-Perucha, Piluca, Caplinger, Michael A., Caudill, Christy M., Cary, Francesca, Cisneros, Ernest, Cloutis, Edward A., Cluff, Nathan, Corlies, Paul, Crawford, Kelsie, Curtis, Sabrina, Deen, Robert, Dixon, Darian, Donaldson, Christopher, Barrington, Megan, Ficht, Michelle, Fleron, Stephanie, Hansen, Michael, Harker, David, Howson, Rachel, Huggett, Joshua, Jacob, Samantha, Jensen, Elsa, Jensen, Ole B., Jodhpurkar, Mohini, Joseph, Jonathan, Juarez, Christian, Kah, Linda C., Kanine, Oak, Kristensen, Jessica, Kubacki, Tex, Lapo, Kristiana, Magee, Angela, Maimone, Michael, Mehall, Greg L., Mehall, Laura, Mollerup, Jess, Viudez-Moreiras, Daniel, Paris, Kristen, Powell, Kathryn E., Preusker, Frank, Proton, Jon, Rojas, Corrine, Sallurday, Danny, Saxton, Kim, Scheller, Eva, Seeger, Christiana H., Starr, Mason, Stein, Nathan, Turenne, Nathalie, Van Beek, Jason, Winhold, Andrew G., Yingling, Rachel, Bell, James F., Maki, Justin N., Alwmark, Sanna, Ehlmann, Bethany L., Fagents, Sarah A., Grotzinger, John P., Gupta, Sanjeev, Hayes, Alexander, Herkenhoff, Ken E., Horgan, Briony H. N., Johnson, Jeffrey R., Kinch, Kjartan B., Lemmon, Mark T., Madsen, Morten B., Nunez, Jorge, Paar, Gerhard, Rice, Melissa, Rice, James W., Schmitz, Nicole, Sullivan, Robert, Vaughan, Alicia, Wolff, Mike J., Bechtold, Andreas, Bosak, Tanja, Duflot, Louise E., Fairen, Alberto G., Garczynski, Brad, Jaumann, Ralf, Merusi, Marco, Million, Chase, Ravanis, Eleni, Shuster, David L., Simon, Justin, St Clair, Michael, Tate, Christian, Walter, Sebastian, Weiss, Benjamin, Bailey, Alyssa M., Bertrand, Tanguy, Beyssac, Olivier, Brown, Adrian J., Caballo-Perucha, Piluca, Caplinger, Michael A., Caudill, Christy M., Cary, Francesca, Cisneros, Ernest, Cloutis, Edward A., Cluff, Nathan, Corlies, Paul, Crawford, Kelsie, Curtis, Sabrina, Deen, Robert, Dixon, Darian, Donaldson, Christopher, Barrington, Megan, Ficht, Michelle, Fleron, Stephanie, Hansen, Michael, Harker, David, Howson, Rachel, Huggett, Joshua, Jacob, Samantha, Jensen, Elsa, Jensen, Ole B., Jodhpurkar, Mohini, Joseph, Jonathan, Juarez, Christian, Kah, Linda C., Kanine, Oak, Kristensen, Jessica, Kubacki, Tex, Lapo, Kristiana, Magee, Angela, Maimone, Michael, Mehall, Greg L., Mehall, Laura, Mollerup, Jess, Viudez-Moreiras, Daniel, Paris, Kristen, Powell, Kathryn E., Preusker, Frank, Proton, Jon, Rojas, Corrine, Sallurday, Danny, Saxton, Kim, Scheller, Eva, Seeger, Christiana H., Starr, Mason, Stein, Nathan, Turenne, Nathalie, Van Beek, Jason, Winhold, Andrew G., and Yingling, Rachel

Abstract

Perseverance's Mastcam-Z instrument provides high-resolution stereo and multispectral images with a unique combination of spatial resolution, spatial coverage, and wavelength coverage along the rover's traverse in Jezero crater, Mars. Images reveal rocks consistent with an igneous (including volcanic and/or volcaniclastic) and/or impactite origin and limited aqueous alteration, including polygonally fractured rocks with weathered coatings; massive boulder-forming bedrock consisting of mafic silicates, ferric oxides, and/or iron-bearing alteration minerals; and coarsely layered outcrops dominated by olivine. Pyroxene dominates the iron-bearing mineralogy in the finegrained regolith, while olivine dominates the coarse-grained regolith. Solar and atmospheric imaging observations show significant intra- and intersol variations in dust optical depth and water ice clouds, as well as unique examples of boundary layer vortex action from both natural (dust devil) and Ingenuity helicopter-induced dust lifting. High-resolution stereo imaging also provides geologic context for rover operations, other instrument observations, and sample selection, characterization, and confirmation.

Published
2022

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