The formation environment of potassic‐chloro‐hastingsite in the nakhlites <scp>MIL</scp> 03346 and pairs and <scp>NWA</scp> 5790: Insights from terrestrial chloro‐amphibole

Giesting, Paul A.; Filiberto, J.

doi:10.1111/maps.12675

Cited by 33 publications

(32 citation statements)

References 123 publications

(210 reference statements)

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“…Fe°sponge (needed for combination with hematite to provide the desired ferrous/ferric ratio) and MgCl 2 (for the chlorine-bearing sources) were added in the last hour to mitigate any oxidation or dissolution of the components, respectively. The Fe 2+ / (Fe 2+ +Fe 3+ ) ratio of this mixture was determined by the MELTS (Ghiorso & Sack, 1995) analysis mentioned above. This analysis indicated that a log (fO 2 /1 bar) of -7 (~0.2 log units above NNO) at 1150°C would be achieved by setting the Fe 2+ /(Fe 2+ +Fe 3+ ) ratio of the synthetic source mixture to 0.8.…”

Section: Methodsmentioning

confidence: 99%

“…Instead, the ferrous/ferric ratio was set to be that of NNO at 1150°C in the starting source material. The value of this initial ratio was obtained by using the Irvine composition for a MELTS analysis (Ghiorso & Sack, 1995) of the effect of log (fO 2 /1 bar; that is, log fugacity of oxygen relative to a 1 bar standard state) on the melt Fe 3+ /Fe 2+ ratio.…”

Section: 1029/2018je005911mentioning

confidence: 99%

“…Commonly considered mechanisms for the formation of the sulfates and chlorides/perchlorates in Martian fine‐grained material involve secondary processes acting upon preexisting sulfide‐ and chloride‐bearing bedrock sources. Studies of igneous Martian meteorites indicate that these rocks contain primary igneous sulfides, predominantly pyrrhotite (see review of King & McLennan, ), and Cl‐bearing minerals, such as amphiboles (e.g., Giesting & Filiberto, ; Johnson et al, ), Cl‐scapolite (Filiberto et al, ), and apatite (e.g., McCubbin & Nekvasil, ; Righter et al, ). Oxidation of primary sulfide minerals to form sulfates is speculated to have occurred through water‐rock or ice‐rock interaction (Bibring et al, ; Burns & Fisher, ; Chevrier & Mathé, ; King et al, ; King & McSween, ; McCollom & Hynek, ; Niles & Michalski, ; Yant et al, ).…”

Section: Introductionmentioning

confidence: 99%

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Vapor‐Deposited Minerals Contributed to the Martian Surface During Magmatic Degassing

et al. 2019

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Martian magmas were likely enriched in S and Cl with respect to H2O. Exsolution of a vapor phase from these magmas and ascent of the gas bubbles through the magma plumbing system would have given rise to shallow magmas that were gas‐charged. Release and cooling of this gas from lava flows during eruption may have resulted in the addition of a significant amount of vapor‐deposited phases to the fines of the surface. Experiments were conducted to simulate degassing of gas‐charged lava flows and shallow intrusions in order to determine the nature of vapor‐deposited phases that may form through this process. The results indicate that magmatic gas may have contributed a large amount of Fe, S, and Cl to the Martian surface through the deposition of iron oxides (magnetite, maghemite, and hematite), chlorides (molysite, halite, and sylvite), sulfur, and sulfides (pyrrhotite and pyrite). Primary magmatic vapor‐deposited minerals may react during cooling to form a variety of secondary products, including iron oxychloride (FeOCl), akaganéite (Fe3+O (OH,Cl)), and jarosite (KFe3+3(OH)6(SO4)2). Vapor‐deposition does not transport significant amounts of Ca, Al, or Mg from the magma and hence, this process does not directly deposit Ca‐ or Mg‐sulfates.

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Section: Methodsmentioning

confidence: 99%

Section: 1029/2018je005911mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Vapor‐Deposited Minerals Contributed to the Martian Surface During Magmatic Degassing

et al. 2019

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“…The presence of igneous rocks varying from basaltic to ultramafic compositions is inferred from the widespread occurrence of pyroxenes, olivine, and plagioclase, as observed by visible/near-infrared (VNIR), thermal infrared, and gamma ray spectrometers such as Observatoire pour la Minéralogie, l'Eau, les Glaces, et l'Activité, Compact Reconnaissance Imaging Spectrometer for Mars (CRISM), Thermal Emission Spectrometer, and Gamma Ray Spectrometer (e.g., Bibring et al, 2006;Boynton et al, 2007;Christensen et al, 2001;Murchie et al, 2007), in situ rock analyses on Mars (e.g., Brückner et al, 2003;Gellert et al, 2006;Ming et al, 2008;Schmidt et al, 2014;Squyres et al, 2012;Zipfel et al, 2011), and Martian meteorites of the shergottite, nakhlite, and chassignite group (Bridges & Warren, 2006;Meyer, 2013;Treiman, 2005;Treiman & Filiberto, 2015) and related basaltic meteorites (Agee et al, 2013). In addition, numerous alteration minerals have been identified, including clays, chlorite, mica, prehnite, epidote, zeolites, serpentine, carbonates, sulfates, hydrated (opaline) silica, oxides, scapolite, and Cl-rich amphibole (e.g., Arvidson et al, 2014;Carter et al, 2013;Changela & Bridges, 2010;Ehlmann et al, 2009;Filiberto et al, 2014;Gendrin et al, 2005;Giesting & Filiberto, 2016;Hicks et al, 2014;Milliken et al, 2008;Murchie et al, 2009;Poulet et al, 2005;Squyres et al, 2008;Treiman, 2005;Vaniman et al, 2014). The presence of hydrous phases indicates multiple diverse aqueous environments and episodes of activity.…”

Section: Introductionmentioning

confidence: 99%

Phase Equilibria Modeling of Low‐Grade Metamorphic Martian Rocks

et al. 2019

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Hydrous phases have been identified to be a significant component of Martian mineralogy. Particularly, prehnite, zeolites, and serpentine are evidence for low‐grade metamorphic reactions at elevated temperatures in mafic and ultramafic protoliths. Their presence suggests that at least part of the Martian crust is sufficiently hydrated for low‐grade metamorphic reactions to occur. A detailed analysis of changes in mineralogy with variations in fluid content and composition along possible Martian geotherms can contribute to determine the conditions required for subsurface hydrous alteration, fluid availability, and rock properties in the Martian crust. In this study, we use phase equilibria models to explore low‐grade metamorphic reactions covering a pressure‐temperature range of 0–0.5 GPa and 150–450 °C for several Martian protolith compositions and varying fluid content. Our models replicate the detected low‐grade metamorphic/hydrothermal mineral phases like prehnite, chlorite, analcime, unspecified zeolites, and serpentine. Our results also suggest that actinolite should be a part of lower‐grade metamorphic assemblages, but actinolite may not be detected in reflectance spectra for several reasons. By gradually increasing the water content in the modeled whole‐rock composition, we can estimate the amount of water required to precipitate low‐grade metamorphic phases. Mineralogical constraints do not necessarily require an elevated geothermal gradient for the formation of prehnite. However, restricted crater excavation depths even for large impact craters are not likely sampling prehnite along colder gradients, suggesting either a geotherm of ~20 °C/km in the Noachian or an additional heat source such as hydrothermal or magmatic activity.

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“…Filiberto et al (2014) found evidence for high temperature fluids in the form of marialite (Na‐Cl scapolite) in a melt inclusion in Nakhla, which is consistent with formation from Cl‐rich, water‐poor fluid (either magma or brine) at a minimum temperature of 700 °C. Further evidence for Cl‐rich hydrothermal conditions has been found in other nakhlites in the form of Cl‐potassic‐hastingsite (e.g., Giesting and Filiberto 2016), which forms in medium‐grade metamorphic conditions (>400 °C). Finally, recent investigations of meteorite NW 7533 found eskolaite encased in chromite‐magnetite and suggested that it formed from an active hydrothermal environment in the Martian crust (Liu et al 2016).…”

Section: Introductionmentioning

confidence: 84%

High‐pressure metamorphic mineralogy of the Martian crust with implications for density and seismic profiles

Semprich

Filiberto

2020

Meteorit & Planetary Scien

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Here, we calculate the mineralogy of the Martian lower crust and upper mantle as a function of pressure and temperature with depth using four bulk compositions (average crust, Gusev basalt, olivine‐phyric shergottite, and primitive average mantle). We then use this mineralogy to extract rock properties such as density and seismic velocities, describe their changes with varying conditions and geotherms, and make predictions for the crust–mantle boundary. Mineralogically, all compositions produce garnet, orthopyroxene, clinopyroxene in varying proportions at high pressures, with differences in minor minerals (spinel, ilmenite, rutile, and/or K‐feldspar). According to our calculations, the average crust and Gusev basalt compositions have the potential to yield higher densities than the average mantle composition, particularly for thicker crusts and/or colder geotherms. Therefore, recycling of the Martian crust into the mantle could occur through the process of crustal delamination, if not kinetically inhibited. However, our results show that, depending on crustal thickness, the crust may not be easily distinguishable from the mantle in seismic properties.

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The formation environment of potassic‐chloro‐hastingsite in the nakhlites MIL 03346 and pairs and NWA 5790: Insights from terrestrial chloro‐amphibole

Cited by 33 publications

References 123 publications

Vapor‐Deposited Minerals Contributed to the Martian Surface During Magmatic Degassing

Vapor‐Deposited Minerals Contributed to the Martian Surface During Magmatic Degassing

Phase Equilibria Modeling of Low‐Grade Metamorphic Martian Rocks

High‐pressure metamorphic mineralogy of the Martian crust with implications for density and seismic profiles

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