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Geophysical evidence for an enriched molten silicate layer above Mars’s core

Author

Listed:
  • Henri Samuel

    (Université Paris Cité, Institut de physique du globe de Paris, CNRS)

  • Mélanie Drilleau

    (Institut Supérieur de l’Aéronautique et de l’Espace ISAE-SUPAERO)

  • Attilio Rivoldini

    (Royal Observatory of Belgium)

  • Zongbo Xu

    (Université Paris Cité, Institut de physique du globe de Paris, CNRS)

  • Quancheng Huang

    (Colorado School of Mines
    University of Maryland)

  • Raphaël F. Garcia

    (Institut Supérieur de l’Aéronautique et de l’Espace ISAE-SUPAERO)

  • Vedran Lekić

    (University of Maryland)

  • Jessica C. E. Irving

    (University of Bristol)

  • James Badro

    (Université Paris Cité, Institut de physique du globe de Paris, CNRS)

  • Philippe H. Lognonné

    (Université Paris Cité, Institut de physique du globe de Paris, CNRS)

  • James A. D. Connolly

    (ETH Zurich)

  • Taichi Kawamura

    (Université Paris Cité, Institut de physique du globe de Paris, CNRS)

  • Tamara Gudkova

    (Schmidt Institute of Physics of the Earth, Russian Academy of Sciences)

  • William B. Banerdt

    (California Institute of Technology)

Abstract

The detection of deep reflected S waves on Mars inferred a core size of 1,830 ± 40 km (ref. 1), requiring light-element contents that are incompatible with experimental petrological constraints. This estimate assumes a compositionally homogeneous Martian mantle, at odds with recent measurements of anomalously slow propagating P waves diffracted along the core–mantle boundary2. An alternative hypothesis is that Mars’s mantle is heterogeneous as a consequence of an early magma ocean that solidified to form a basal layer enriched in iron and heat-producing elements. Such enrichment results in the formation of a molten silicate layer above the core, overlain by a partially molten layer3. Here we show that this structure is compatible with all geophysical data, notably (1) deep reflected and diffracted mantle seismic phases, (2) weak shear attenuation at seismic frequency and (3) Mars’s dissipative nature at Phobos tides. The core size in this scenario is 1,650 ± 20 km, implying a density of 6.5 g cm−3, 5–8% larger than previous seismic estimates, and can be explained by fewer, and less abundant, alloying light elements than previously required, in amounts compatible with experimental and cosmochemical constraints. Finally, the layered mantle structure requires external sources to generate the magnetic signatures recorded in Mars’s crust.

Suggested Citation

  • Henri Samuel & Mélanie Drilleau & Attilio Rivoldini & Zongbo Xu & Quancheng Huang & Raphaël F. Garcia & Vedran Lekić & Jessica C. E. Irving & James Badro & Philippe H. Lognonné & James A. D. Connolly , 2023. "Geophysical evidence for an enriched molten silicate layer above Mars’s core," Nature, Nature, vol. 622(7984), pages 712-717, October.
    • Handle: RePEc:nat:nature:v:622:y:2023:i:7984:d:10.1038_s41586-023-06601-8
    DOI: 10.1038/s41586-023-06601-8
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    Cited by:

    1. S. C. Steele & R. R. Fu & A. Mittelholz & A. I. Ermakov & R. I. Citron & R. J. Lillis, 2024. "Weak magnetism of Martian impact basins may reflect cooling in a reversing dynamo," Nature Communications, Nature, vol. 15(1), pages 1-16, December.

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