Extending the Solidus for a Model Iron‐Rich Martian Mantle Composition to 25 GPa

The solidus for the mantle of Mars is an important geophysical parameter in modeling the thermal history and evolution of the planet. This study provides solidus data for a simplified model Martian mantle composition from the midmantle (8 GPa) to the core–mantle boundary (25 GPa) using multianvil ex...

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Bibliographic Details
Published inGeophysical research letters Vol. 45; no. 19; pp. 10,211 - 10,220
Main Authors Duncan, Megan S., Schmerr, Nicholas C., Bertka, Constance M., Fei, Yingwei
Format Journal Article
LanguageEnglish
Published Washington John Wiley & Sons, Inc 16.10.2018
Subjects
Composition
Computer simulation
Data
Direct melting
Evolution
Geophysics
Iron
Mantle plumes
Mars
Mars volcanoes
Mathematical models
Melting
Mineral assemblages
Modelling
Peridotite
Phase transitions
Planetary evolution
Planetary mantles
SNC meteorites
Solidus
Volcanoes
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Summary:The solidus for the mantle of Mars is an important geophysical parameter in modeling the thermal history and evolution of the planet. This study provides solidus data for a simplified model Martian mantle composition from the midmantle (8 GPa) to the core–mantle boundary (25 GPa) using multianvil experiments. Combining this work with previous studies, the solidus for the entire mantle of Mars is constrained to within 70 °C. The major mineral assemblages and phase transitions observed are consistent with those predicted for an iron‐rich Martian mantle. The solidus for the Martian composition falls above the solidus of MORB and below that of terrestrial peridotite, providing direct melting data for geophysical modeling of the Martian interior. Our solidus also predicts that a Martian mantle plume should produce melt at depths over a range of 200–350 km in the mantle. Plain Language Summary We simulated the interior of Mars by using high‐pressure and high‐temperature devices to determine how hot Mars must be to melt the solid rock inside the entire planet. We know that inside of Mars has melted (is melting?) because we observe large volcanoes on the surface, of various sizes and ages. We compared our results to data gained from the study of Martian meteorites, and determined that Mars could be melting today, in which case the upcoming InSight mission to Mars should see a signature of melting. Key Points We constrained the solidus of the Martian mantle from 8‐ to 25‐GPa experiments using a bulk silicate Mars composition We find that the solidus for the Martian composition falls between the solidus of MORB and terrestrial peridotite Our solidus predicts that a Martian mantle plume should produce melt at depths over a range of 200–350 km
ISSN:0094-8276
1944-8007
DOI:10.1029/2018GL078182