Coupled core-mantle thermal evolution of early Mars

Details Coupled core-mantle thermal evolution of early Mars Coupled core-mantle thermal evolution of early Mars

Jul 2009

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2009jgre..11407004k&link_type=abstract

Journal of Geophysical Research, Volume 114, Issue E7, CiteID E07004

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6

Planetary Sciences: Solar System Objects: Mars, Planetary Sciences: Fluid Planets: Magnetic Fields And Magnetism, History Of Geophysics: Computational Geophysics

Scientific paper

Several arguments point out that at the end of planetary accretion, the core of Mars was likely to be much hotter than its mantle, resulting in the formation of a completely or partially molten thermal boundary layer at the base of the mantle. Here we address the following questions: How did the superheated core cool and what role did it play in the early mantle dynamics of Mars? We divide the coupled core-mantle evolution of early Mars into two stages. During the first stage, vigorous convection within the molten boundary layer removes the heat from the core so that the boundary layer expands up. As the boundary layer gets thicker, the temperature of the layer decreases. Eventually, the temperature of the molten boundary layer drops down to the temperature for the rheological transition (melt fraction ˜40%) within 100 years. This stage is described by a parameterized convection approach. The second stage is modeled in spherical shell geometry using the fully three-dimensional finite element code CitcomS. A single plume (“superplume”) forms by the instability of the thermal boundary layer. The superplume stage lasts much longer, on the scale of millions to hundreds of millions of years, depending on the mantle viscosity. During both stages of evolution the heat flux can easily satisfy the requirements for the dynamo.

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