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

Collinet, Max; Médard, Étienne; Charlier, Bernard; Auwera, Jacqueline Vander; Grove, T. L.

doi:10.1016/j.epsl.2015.06.056

Cited by 47 publications

(120 citation statements)

References 67 publications

(110 reference statements)

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“…Olivines in primitive depleted shergottites reach Mg# of 0.86 (Usui et al, 2008), which requires extensive (>50%) melting of the Martian primitive mantle if the BSM has Mg# = 0.75, which is unlikely to be achieved when shergottites formed (Musselwhite et al, 2006). On the other hand, with an Fe-poor Martian primitive mantle (Mg# ∼ 0.80), much lower degrees of mantle melting can produce the high-Mg olivine (Musselwhite et al, 2006;Collinet et al, 2015;McCoy et al, 2016). Collinet et al (2015) concluded that the Martian mantle has heterogeneous Mg# ranging between 0.75-0.82.…”

Section: Major Elements (Mg Si Fe)mentioning

confidence: 99%

The composition of Mars

Yoshizaki

McDonough

2020

Geochimica et Cosmochimica Acta

132

154

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Comparing compositional models of the terrestrial planets provides insights into physicochemical processes that produced planet-scale similarities and differences. The widely accepted compositional model for Mars assumes Mn and more refractory elements are in CI chondrite proportions in the planet, including Fe, Mg, and Si, which along with O make up >90% the mass of Mars. However, recent improvements in our understandings on the composition of the solar photosphere and meteorites challenge the use of CI chondrite as an analog of Mars. Here we present an alternative model composition for Mars that avoids such an assumption and is based on data from Martian meteorites and spacecraft observations. Our modeling method was previously applied to predict the Earth's composition. The model establishes the absolute abundances of refractory lithophile elements in the bulk silicate Mars (BSM) at 2.26 times higher than that in CI carbonaceous chondrites. Relative to this chondritic composition, Mars has a systematic depletion in moderately volatile lithophile elements as a function of their condensation temperature. Given this finding, we constrain the abundances of siderophile and chalcophile elements in the bulk Mars and its core. The Martian volatility trend is consistent with ≤7 wt% S in its core, which is significantly lower than that assumed in most core models (i.e., >10 wt% S). Occurrence of ringwoodite at the Martian core-mantle boundary might have contributed to the partitioning of O and H into the Martian core.

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Section: Major Elements (Mg Si Fe)mentioning

confidence: 99%

The composition of Mars

Yoshizaki

McDonough

2020

Geochimica et Cosmochimica Acta

132

154

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“…Experiments performed from the wholerock composition of NWA 1068 (Filiberto et al, 2010) have identified a multiple saturation point (MSP) where olivine and orthopyroxene appear on the liquidus of NWA 1068 at 1.7 GPa and 1520°C. Under those conditions, the primitive martian mantle is expected to contain only olivine and orthopyroxene (Collinet et al, 2015). The CaO/Al 2 O 3 of NWA 1068 is super-chondritic and rules out that the parental melt derives from the primitive martian mantle by equilibrium melting.…”

Section: Parental Melt Of Nwa 1068 and Implications For The Origin Ofmentioning

confidence: 99%

“…10). The olivine compositions in equilibrium with primary martian mantle melts vary from Fo 76 for melting of the primitive martian mantle (Collinet et al, 2015) to Fo 85 for the mantle source of the depleted shergottites (Musselwhite et al, 2006). The parental melt of NWA 1068 could have been in equilibrium with Fo 80±1 olivines and would represent a primary melt of a mantle source with an intermediate Mg#.…”

Section: Parental Melt Of Nwa 1068 and Implications For The Origin Ofmentioning

confidence: 99%

Crystallization history of enriched shergottites from Fe and Mg isotope fractionation in olivine megacrysts

Collinet

Charlier

Namur

et al. 2017

Geochimica et Cosmochimica Acta

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Martian meteorites are the only samples available from the surface of Mars. Among them, olivine-phyric shergottites are basalts containing large zoned olivine crystals with highly magnesian cores 26 Mg = À0.27 ± 0.04‰). The flat forsterite profiles of megacryst cores associated with anti-correlated fractionation of Fe-Mg isotopes indicate that these elements have been rehomogenized by diffusion at high temperature. We present a 1-D model of simultaneous diffusion and crystal growth that reproduces the observed element and isotope profiles. The simulation results suggest that the cooling rate during megacryst core crystallization was slow (43 ± 21°C/year), and consistent with pooling in a deep crustal magma chamber. The megacryst rims then crystallized 1-2 orders of magnitude faster during magma transport toward the shallower site of final emplacement. Megacryst cores had a forsterite content 3.2 ± 1.5 mol% higher than their current composition and some were in equilibrium with the whole-rock composition of NWA 1068 (Fo 80 ± 1.5). NWA 1068 composition is thus close to a primary melt (i.e. in equilibrium with the mantle) from which other enriched shergottites derived.

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“…Therefore, they have suggested a lower Fe/Mg ratio for the source of shergottites in comparison with Dreibus and Wänke (1985). Collinet et al (2015) demonstrated that the parental melt of Adirondack-class basalts of Gusev crater may be produced by ∼25 wt% partial melting of the mantle at 1.5 GPa using Dreibus and Wänke (1985) composition. Despite admitted sources of uncertainties and unknowns, the model of Dreibus and Wänke (1985) still serves as a reference model until today.…”

Section: Interior Composition From Martian Meteorites and Cosmochemicmentioning

confidence: 99%

“…It also suggests an iron-rich mantle, with differences regarding the Mg/Si ratio that has consequences on the mantle mineralogy. The validity of the geochemical models was also addressed from laboratory experiments to determine if the elements abundances of martian basalts can be formed through the magmatic differentiation of parent magma derived from mantle partial melting at high pressure (Agee and Draper 2004;Collinet et al 2015). For instance, Agee and Draper (2004) have shown that it is possible to reproduce the super-chondritic CaO/Al 2 O 3 ratio of martian basalts from partial melting at ∼5 GPa, but find it difficult to match their FeO content.…”

Section: Interior Composition From Martian Meteorites and Cosmochemicmentioning

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

Cited by 47 publications

References 67 publications

The composition of Mars

The composition of Mars

Crystallization history of enriched shergottites from Fe and Mg isotope fractionation in olivine megacrysts

Mars: a small terrestrial planet

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