Geochemical diversity in first rocks examined by the Curiosity Rover in Gale Crater: Evidence for and significance of an alkali and volatile‐rich igneous source

Schmidt, M. E.; Campbell, John L.; Gellert, R.; Perrett, G. M.; Treiman, Allan H.; Blaney, D. L.; Olilla, A. M.; Calef, F.; Edgar, L. A.; Elliott, Beverley; Grotzinger, J. P.; Hurowitz, J. A.; King, P. L.; Minitti, M. E.; Sautter, V.; Stack, K. M.; Berger, J. A.; Bridges, J. C.; Ehlmann, B. L.; Forni, O.; Leshin, L. A.; Lewis, K. W.; McLennan, Scott M.; Ming, D. W.; Newsom, H. E.; Pradler, Irina; Squyres, S. W.; Stolper, Edward M.; Thompson, L. M.; VanBommel, S. J.; Wiens, R. C.

doi:10.1002/2013je004481

Cited by 128 publications

(211 citation statements)

References 83 publications

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“…These samples were only analyzed with the ChemCam instrument (laser-induced breakdown spectroscopy), and precise bulk rock compositions are not available. However, chemical analyses highlighted an important compositional diversity ranging from basaltic to evolved and alkali-rich compositions similar to Jake_M (Sautter et al, 2014;Schmidt et al, 2014). Alkalibasalts and tholeiitic basalts might coexist in the same locality, as also observed in Gusev Crater.…”

Section: Gale Crater: Mugearite and Other Alkaline Rocksmentioning

confidence: 71%

“…The extreme alkali and Al 2 O 3 contents of Jake_M are easier to produce from a low degree melt (∼10 wt.%) produced at a pressure higher than 1.0 GPa. Metasomatism is often invoked to enrich the source of Jake_M in potassium (Schmidt et al, 2014;Stolper et al, 2013). Alternatively, we suggest that low-degree melts, produced from a mantle not anomalously enriched, can fractionate and eventually crystallize to form rocks similar to Jake_M.…”

Section: Gale Crater: Mugearite and Other Alkaline Rocksmentioning

confidence: 83%

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Melting of the primitive martian mantle at 0.5–2.2 GPa and the origin of basalts and alkaline rocks on Mars

Collinet

Médard

Charlier

et al. 2015

Earth and Planetary Science Letters

109

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We have performed piston-cylinder experiments on a primitive martian mantle composition between 0.5 and 2.2 GPa and 1160 to 1550 • C. The composition of melts and residual minerals constrain the possible melting processes on Mars at 50 to 200 km depth under nominally anhydrous conditions. Silicate melts produced by low degrees of melting (<10 wt.%) were analyzed in layers of vitreous carbon spheres or in micro-cracks inside the graphite capsule. The total range of melt fractions investigated extends from 5 to 50 wt.%, and the liquids produced display variable SiO 2 (43.7-59.0 wt.%), MgO (5.3-18.6 wt.%) and Na 2 O + K 2 O (1.0-6.5 wt.%) contents. We provide a new equation to estimate the solidus temperature of the martian mantle: T ( • C) = 1033 + 168.1P (GPa) − 14.22P 2 (GPa), which places the solidus 50 • C below that of fertile terrestrial peridotites. Low-and high-degree melts are compared to martian alkaline rocks and basalts, respectively. We suggest that the parental melt of Adirondack-class basalts was produced by ∼25 wt.% melting of the primitive martian mantle at 1.5 GPa (∼135 km) and ∼1400 • C. Despite its brecciated nature, NWA 7034/7533 might be composed of material that initially crystallized from a primary melt produced by ∼10-30 wt.% melting at the same pressure. Other igneous rocks from Mars require mantle reservoirs with different CaO/Al 2 O 3 and FeO/MgO ratios or the action of fractional crystallization. Alkaline rocks can be derived from mantle sources with alkali contents (∼0.5 wt.%) similar to the primitive mantle.

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Section: Gale Crater: Mugearite and Other Alkaline Rocksmentioning

confidence: 71%

Section: Gale Crater: Mugearite and Other Alkaline Rocksmentioning

confidence: 83%

Melting of the primitive martian mantle at 0.5–2.2 GPa and the origin of basalts and alkaline rocks on Mars

Collinet

Médard

Charlier

et al. 2015

Earth and Planetary Science Letters

109

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“…22) (Foley et al 2003;Christensen et al 2005;Bandfield 2006;Wray et al 2013). Felsic and alkali-rich igneous rocks (including mugearite, granodiorite, and trachyte) have been identified on float rocks and conglomerate clasts by the Curiosity rover at Gale crater (Stolper et al 2013;Schmidt et al 2014;Sautter et al 2014Sautter et al , 2015. The meteorite breccia NWA 7034 (paired with NWA 7533 and NWA 7475 of similar origin) is a unique piece of ancient crust with zircon crystals dated at 4.43 Gy and contains differentiated felsic rocks with abundant feldspars showing a more complex mineralogy than any other martian meteorites (Agee et al 2013;Humayun et al 2013;Wittmann et al 2015).…”

Section: Integrating Geophysical and Geochemical Approachesmentioning

confidence: 99%

Mars: a small terrestrial planet

Mangold

Baratoux

Witasse

et al. 2016

Astron Astrophys Rev

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Mars is characterized by geological landforms familiar to terrestrial geologists. It has a tenuous atmosphere that evolved differently from that of Earth and Venus and a differentiated inner structure. Our knowledge of the structure and evolution of Mars has strongly improved thanks to a huge amount of data of various types (visible and infrared imagery, altimetry, radar, chemistry, etc) acquired by a dozen of missions over the last two decades. In situ data have provided ground truth for remote-sensing data and have opened a new era in the study of Mars geology. While large sections of Mars science have made progress and new topics have emerged, a major question in Mars exploration-the possibility of past or present life-is still unsolved. Without entering into the debate around the presence of life traces, our review develops various topics of Mars science to help the search of life on Mars, building on the most recent discoveries, going from the exosphere to the interior structure, from the magmatic evolution to the currently active processes, including the fate of volatiles and especially liquid water.

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“…Aqueous environments interpreted from these rover datasets range from acid sulfate leaching at Meridiani Planum (Squyres and Knoll, 2005), hydrothermal alteration of volcaniclastic deposits at Home Plate, Gusev Crater (Hurowitz et al, 2006;Morris et al, 2008;Schmidt et al, 2009), and aqueous, potentially hydrothermal alteration of basaltic impact breccias (Arvidson et al, 2014;Squyres et al, 2012). NASA's Mars Science Laboratory rover Curiosity has identified a range of lithologies influenced by aqueous activity, ranging from transported volcaniclastics (Schmidt et al, 2014), fluvial conglomerates (Williams et al, 2013), and the fine-grained sedimentary deposits at Yellowknife Bay comprising primary basaltic minerals and alteration phases. The latter includes amorphous material, smectite clays, and sulfates (Vaniman et al, 2014), potentially indicative of sustained hydrous environments (Grotzinger et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

Remote detection of past habitability at Mars-analogue hydrothermal alteration terrains using an ExoMars Panoramic Camera emulator

Harris

Cousins

Gunn

et al. 2015

Icarus

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This paper is dedicated to the late Prof. Dave Barnes who sadly passed away before the publication of this work, to which he had significantly contributed over the years through his work on the ExoMars PanCamA major scientific goal of the European Space Agency?s ExoMars 2018 rover is to identify evidence of life within the martian rock record. Key to this objective is the remote detection of geological substrates that are indicative of past habitable environments, which will rely on visual (stereo wide-angle, and high resolution images) and multispectral (440?1000 nm) data produced by the Panoramic Camera (PanCam) instrument. We deployed a PanCam emulator at four hydrothermal sites in the N?mafjall volcanic region of Iceland, a Mars-analogue hydrothermal alteration terrain. At these sites, sustained acidic?neutral aqueous interaction with basaltic substrates (crystalline and sedimentary) has produced phyllosilicate, ferric oxide, and sulfate-rich alteration soils, and secondary mineral deposits including gypsum veins and zeolite amygdales. PanCam emulator datasets from these sites were complemented with (i) NERC Airborne Research and Survey Facility aerial hyperspectral images of the study area; (ii) in situ reflectance spectroscopy (400?1000 nm) of PanCam spectral targets; (iii) laboratory X-ray Diffraction, and (iv) laboratory VNIR (350?2500 nm) spectroscopy of target samples to identify their bulk mineralogy and spectral properties. The mineral assemblages and palaeoenvironments characterised here are analogous to neutral?acidic alteration terrains on Mars, such as at Mawrth Vallis and Gusev Crater. Combined multispectral and High Resolution Camera datasets were found to be effective at capturing features of astrobiological importance, such as secondary gypsum and zeolite mineral veins, and phyllosilicate-rich substrates. Our field observations with the PanCam emulator also uncovered stray light problems which are most significant in the NIR wavelengths and investigations are being undertaken to ensure that the flight model PanCam cameras are not similarly affectedpublishersversionPeer reviewe

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Geochemical diversity in first rocks examined by the Curiosity Rover in Gale Crater: Evidence for and significance of an alkali and volatile‐rich igneous source

Cited by 128 publications

References 83 publications

Melting of the primitive martian mantle at 0.5–2.2 GPa and the origin of basalts and alkaline rocks on Mars

Melting of the primitive martian mantle at 0.5–2.2 GPa and the origin of basalts and alkaline rocks on Mars

Mars: a small terrestrial planet

Remote detection of past habitability at Mars-analogue hydrothermal alteration terrains using an ExoMars Panoramic Camera emulator

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