Stratified layer in Martian mantle: Global thermochemical convection models

The core dynamos of Mars and the Moon have distinctly different histories. Mars had no core dynamo at the end of accretion. It took ∼100 Myr for the core to create a strong dynamo that magnetized the martian crust. Giant impacts during 4.2–4.0 Ga crippled the core dynamo intermittently until a thick stagnant lithosphere developed on the surface and reduced the heat flux at the core–mantle boundary, killing the dynamo at ∼3.8 Ga. On the other hand, the Moon had a strong core dynamo at the end of accretion that lasted ∼100 Myr and magnetized its primordial crust. Either precession of the core or thermochemical convection in the mantle or chemical convection in the core created a strong core dynamo that magnetized the sources of the isolated magnetic anomalies in later times. Mars and the Moon indicate dynamo reversals and true polar wander. The polar wander of the Moon is easier to explain compared to that of Mars. It was initiated by the mass deficiency at South Pole Aitken basin, which moved the basin southward by ∼68° relative to the dipole axis of the core field. The formation of mascon maria at later times introduced positive mass anomalies at the surface, forcing the Moon to make an additional ∼52° degree polar wander. Interaction of multiple impact shock waves with the dynamo, the abrupt angular momentum transfer to the mantle by the impactors, and the global overturn of the core after each impact were probably the factors causing the dynamo reversal.

Download Full-text

Constraints on core–mantle boundary topography from models of thermal and thermochemical convection

Geophysical Journal International ◽

10.1093/gji/ggx402 ◽

2017 ◽

Vol 212 (1) ◽

pp. 164-188 ◽

Cited By ~ 9

Author(s):

Frédéric Deschamps ◽

Yves Rogister ◽

Paul J Tackley

Keyword(s):

Mantle Boundary ◽

Core Mantle Boundary ◽

Thermochemical Convection

Download Full-text

Thermochemical convection in the mantle with oceanic crust recirculation

Izvestiya Physics of the Solid Earth ◽

10.1134/s1069351310110029 ◽

2010 ◽

Vol 46 (11) ◽

pp. 922-930 ◽

Cited By ~ 4

Author(s):

V. P. Trubitsyn

Keyword(s):

Oceanic Crust ◽

Thermochemical Convection

Download Full-text

The stability and structure of primordial reservoirs in the lower mantle: insights from models of thermochemical convection in three-dimensional spherical geometry

Geophysical Journal International ◽

10.1093/gji/ggu295 ◽

2014 ◽

Vol 199 (2) ◽

pp. 914-930 ◽

Cited By ~ 35

Author(s):

Yang Li ◽

Frédéric Deschamps ◽

Paul J. Tackley

Keyword(s):

Lower Mantle ◽

Three Dimensional ◽

Spherical Geometry ◽

The Stability ◽

Thermochemical Convection

Download Full-text

Methods for thermochemical convection in Earth's mantle with force-balanced plates

Geochemistry Geophysics Geosystems ◽

10.1029/2007gc001692 ◽

2007 ◽

Vol 8 (11) ◽

pp. n/a-n/a ◽

Cited By ~ 17

Author(s):

J. P. Brandenburg ◽

P. E. van Keken

Keyword(s):

Earth’S Mantle ◽

Thermochemical Convection

Download Full-text

An experimental approach to thermochemical convection in the Earth's core

Geophysical Research Letters ◽

10.1029/92gl01883 ◽

1992 ◽

Vol 19 (20) ◽

pp. 1995-1998 ◽

Cited By ~ 40

Author(s):

Philippe Cardin ◽

Peter Olson

Keyword(s):

Experimental Approach ◽

Earth’S Core ◽

Earth's Core ◽

Thermochemical Convection

Download Full-text

Numerical simulation of asthenospheric flow around cratonic keels

10.5194/egusphere-egu2020-9668 ◽

2020 ◽

Author(s):

Edgar Santos ◽

Victor Sacek

Keyword(s):

Upper Mantle ◽

Numerical Models ◽

Relative Displacement ◽

Planetary Science ◽

Small Scale ◽

Time Interval ◽

Mantle Flow ◽

Continental Margins ◽

Thermochemical Convection ◽

Synthetic Models

<p>In this work, we studied the mantle flow around cratonic keels using numerical models to simulate the thermochemical convection in the terrestrial mantle taking into account the relative displacement between the lithosphere and asthenosphere. The numerical simulations were performed using the finite element code developed by Sacek (2017) to solve the Stokes Flow for an incompressible Newtonian fluid. Several synthetic models in 2D and 3D were constructed considering different keel geometries and different regimes of relative displacement between the lithosphere and asthenosphere. In the present numerical experiments, we adopted a rheology in which the viscosity of the mantle is controlled by temperature, pressure and composition, assuming that the cratonic keel is compositionally more viscous than the surrounding asthenosphere, using a factor f to rescale the lithospheric viscosity compared to the asthenospheric one. We tested different f values, reference viscosity for the asthenosphere, and relative velocity between the lithosphere and the base of the upper mantle, quantifying the amount of deformation of the cratonic keel in each scenario. In general, we conclude that for a relatively low compositional factor (f < 20), the lithospheric keel can be significantly deformed in a time interval of few tens of million years when the lithosphere is moving horizontally relative to the base of the upper mantle, does not preserving its initial geometry. The synthetic models can be helpful for a better understanding of the interaction in the lithosphere-asthenosphere interface such as the deformation and flow patterns in the mantle around the keels, the rate of erosion of the root of the continental lithosphere due to the convection in the upper mantle and how it affects the thermal flow to the surface.</p><p>Sacek, V. (2017). Post-rift influence of small-scale convection on the landscape evolution at divergent continental margins. Earth and Planetary Science Letters, 459, 48-57.</p>

Download Full-text