Multiagent simulation of evolutive plate tectonics applied to the thermal evolution of the Earth

Combes, Manuel; Grigné, Cécile; Husson, Laurent; Conrad, Clinton P.; Yaouanq, Sébastien Le; Parenthoën, Marc; Tisseau, Chantal; Tisseau, Jacques

doi:10.1029/2011gc004014

Cited by 8 publications

(8 citation statements)

References 91 publications

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“…Working within the limitations of mantle convection modeling, the latter physical requirement imposes constraints on core‐mantle boundary (CMB) heat flux. By influencing surface heat flux and focusing the flux of cold material, plate tectonics principally controls the temperature of the mantle by the process of subduction (e.g., Coltice et al, ; Combes et al, ; Monnereau & Quéré, ). Globally, the rate of subduction, spatial distribution of subduction zones, and longevity of subduction (once initiated) act together to influence mantle temperatures (Bercovici et al, ).…”

Section: Introductionmentioning

confidence: 99%

The Sensitivity of Core Heat Flux to the Modeling of Plate‐Like Surface Motion

Langemeyer

Lowman

Tackley

2018

Geochem Geophys Geosyst

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The generation of a magnetic field and the presence of tectonic plates are fundamental aspects of Earth's evolution. Viable dynamic models of terrestrial mantle convection therefore require the existence of heat transport from the core and a surface characterized by piecewise uniform surface velocity domains (i.e., plates). To test the compatibility of these two requirements, we varied energy input, rheology, and compositional heterogeneity in more than 70 mantle convection simulations. Calculations are performed in a spherical annulus geometry. By systematic investigation, we demonstrate that Earth‐like core heat flux can be obtained with self‐consistent model plates. We find that, given an initial condition where model parameters are chosen to ensure a mobile surface, the mobility is not strongly influenced when H is varied by up to a factor of three. Consequently, in spherical models with steady core temperatures and internal heating rates, the latter quantity can be used to regulate core heat flow to fit within the bounds inferred for terrestrial values. In contrast, core heat flow is strongly sensitive to model yield stress. We systematically vary thermal viscosity contrast, an intrinsic depth‐dependent viscosity and the depth‐dependence of a stress‐dependent rheology and analyze how each factor affects both surface velocities and core heat flux. Finally, we show that the addition of an intrinsically dense component comprising 5% or less of the mantle volume does not affect surface mobility or plateness, although it can have a profound impact on heat loss from the core.

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Section: Introductionmentioning

confidence: 99%

The Sensitivity of Core Heat Flux to the Modeling of Plate‐Like Surface Motion

Langemeyer

Lowman

Tackley

2018

Geochem Geophys Geosyst

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“…We use the prefactor  2.1 c yielding an oceanic lithospheric thickness of 10 km for  τ 1 Myr and 95 km for  τ 80 Myr. A small scale convection mechanism can be used as an option in the MACMA model, in order to limit seafloor thickness after a critical age (for details, see Combes et al [2012]).…”

Section: The Macma Modelmentioning

confidence: 99%

“…The resulting shear force F , which also depends on mantle viscosity, has to overcome a fixed yield strength

F_{normallim}

in order for the continent to break up (see Combes et al. (2012) and Appendix for calculation details). This simplified oceanization parameterization does not reflect complex interactions between continents and mantle flow (e.g., O'Neill et al., 2009) but yields a physically reasonable behavior as a function of T : (1) a plateau in the shear force F is reached after a transient period lasting a few hundreds of Myr (see Figure 1c), (2) wider continents induce larger shear forces F and are therefore breaking more easily than narrow continents, (3) there is a minimum width for a continent to break, which depends on the chosen value of

F_{normallim}

and on the thermal state of the mantle, and (4) because of a lower viscosity in a hotter mantle, the shear force F after a given duration and for a given continental width was lower in the past, implying that the minimum size for a continent to break was larger in the past.…”

Section: The Macma Modelmentioning

confidence: 99%

“…With this approach, the geometry of plate tectonics is not fixed but free to adapt as the temperature and plate speeds evolve. Combes et al (2012) conducted several experiments that yielded moderate cooling rates comprised between 55 and 110 K/Gyr over the past 3 Gyr, but the initial conditions and the main parameters of the model were not varied on a wide range of possibilities. Here, we present a full analysis of Earth's thermal evolutions obtained with this approach and compare them with numerous available geochemical and geological data.…”

Section: Introductionmentioning

confidence: 99%

“…In the present study, we look into Earth's thermal evolution with aiming at explaining not only past moderate cooling rates, but also past plate speeds and rates of tectonic events such as continental collisions. We use a two‐dimensional (2D) model of plate tectonics (Multi‐Agent Convective Mantle [MACMA]) (Combes et al., 2012) based on a force balance for each plate and on empirical parameterizations to treat local plate reorganizations. The model includes mobile plate boundaries that can collide, vanish or be created, asymmetric subduction zones, and their consequent overriding plates, together with breakable insulating continents, bordered by active or passive margins.…”

Section: Introductionmentioning

confidence: 99%

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Thermal History of the Earth: On the Importance of Surface Processes and the Size of Tectonic Plates

Grigné

Combes

2020

Geochem Geophys Geosyst

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The Earth's interior has been cooling over the past 3 billion years. Chemical analyses of ancient rocks show that the mantle was then about 250 degrees hotter than today, corresponding to a fairly low amount of heat released until now. However, when the mantle was hotter in the past, it was less viscous, and the dragging forces on tectonic plates were weak: plate motion was probably much faster. Heat from the Earth's interior is released mainly at oceanic ridges, where new seafloor is created. The faster the plates move, the more heat is released. How so little heat has been released with significantly faster plates in the past? Several authors proposed complex phenomena playing on plate tectonics to "slow down" plates in the past. Here, we propose a new model including surface processes controlling plates creation and disappearance, leading to evolving plate sizes. We show that the geometry of plates is a key factor: for a hotter Earth in the past, plates were larger, so that ridges were less numerous and a moderate amount of heat was released, even if plates were faster. This new paradigm (larger plates in the past) is compatible with observations in geological data.

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The cooling models of Earth’s early mantle

Zhang

Liu

2023

Acta Geochim

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Multiagent simulation of evolutive plate tectonics applied to the thermal evolution of the Earth

Cited by 8 publications

References 91 publications

The Sensitivity of Core Heat Flux to the Modeling of Plate‐Like Surface Motion

The Sensitivity of Core Heat Flux to the Modeling of Plate‐Like Surface Motion

Thermal History of the Earth: On the Importance of Surface Processes and the Size of Tectonic Plates

The cooling models of Earth’s early mantle

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