Evolution of U-Pb and Sm-Nd systems in numerical models of mantle convection and plate tectonics

In its bulk properties, Venus appears similar to Earth, but both planets have developed substantially different geodynamic regimes. Earth has plate tectonics with a continuously renewed surface and its crustal distribution is very dichotomous in composition, thickness, and age. Venus, on the other hand, presently displays a period of a stagnant-lid regime, which may or may not was interrupted by catastrophic events of tectonic recycling during its history. Venus&#8217; crustal thickness is not well constrained, but likely thicker than Earth&#8217;s oceanic crust; pronounced crustal dichotomy may be possible but evidence needs yet to be found. The age of the crust appears rather uniform, which traditionally has been taken as evidence that an episodic overturn must have taken place. However, recent arguments have challenged the episodic overturn hypothesis and favor a more continuous stagnant lid on Venus.&#160;To resolve the problem of Venus&#8217; geodynamic regime understanding the generation of Venus&#8217; crust in a dynamic context that also considers the underlying mantle is necessary. This can be achieved using numerical models of mantle convection tailored to Venus, which include the basic complexities of planetary mantle convection in terms of effective rheology, mineralogy and melting processes. Still, previous models have essentially failed to predict the thickness and age characteristics of Venus&#8217; crust. One possible reason is that these models only considered extrusive volcanism, which renews the surface directly, while intrusive magmatism does not. Yet, intrusion seems the dominant mode of magmatism at least on Earth, so we investigate its influence in our model and evaluate whether this ingredient is key to predict Venus&#8217; crustal characteristics.&#160;Using the code StagYY, we compute a suite of mantle convection models in 2D spherical annulus geometry that run through the entire solid-state history of Venus. We vary the partitioning of intrusive and extrusive volcanism from purely extrusive to dominantly intrusive and predict the present-day distributions of crustal thickness and surface age in the stagnant lid regime. With more intrusive magmatism, average crustal thickness is reduced by 20-25%, but mean crustal thickness still exceeds other independent estimates. The surface is on average much older, which is more consistent with mean age estimates from crater counting. However, lateral age variations also become stronger with dominantly intrusive volcanism, which indicates that volcanism keeps going on, but is more restricted spatially. Governing parameters like mantle reference viscosity and relative enrichment of heat-producing elements into the crust change the absolute values of mean crustal thickness and surface age, but do not improve surface age uniformity. This is somewhat at odds with Venus&#8217; seemingly uniform surface age, so suitable conditions for this possibility are further evaluated in models featuring episodic overturn events.

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Mobile or not mobile: exploring the linkage between deep mantle composition and early Earth surface mobility

10.5194/egusphere-egu2020-10638 ◽

2020 ◽

Author(s):

Keely A. O'Farrell ◽

Sean Trim ◽

Samuel Butler

Keyword(s):

Mantle Convection ◽

Plate Tectonics ◽

Numerical Models ◽

Early Earth ◽

Surface Dynamics ◽

Magma Ocean ◽

Surface Mobility ◽

Deep Mantle ◽

Deep Interior ◽

Tracer Methods

Numerical models of mantle convection help our understanding of the complex feedback between the plates and deep interior dynamics through space and time. Did the early Earth have plate tectonics, a stagnant lid, or something in between? The surface dynamics of the early Earth remain poorly understood. Current numerical models of mantle convection are constrained by present-day observations, but the behavior of the hotter, early Earth prior to the onset of plate tectonics is less certain. The early Earth may have possessed a large hot magma ocean trapped near the core-mantle boundary after formation during differentiation, and likely containing different elements from the surrounding mantle. We examine how composition-dependent properties in the deep mantle affect convection dynamics and surface mobility in high Rayleigh number models featuring plastic yielding. Our Newtonian models indicate that increased conductivity or decreased viscosity flattens basal topography while also increasing the potential for surface yielding. We vary the viscosity, thermal conductivity, and internal heating in a compositionally distinct basal magma ocean and explore the compositional topography, insulation effects and surface stresses for non-Newtonian rheology. Models are run using a variety of crustal compositions, such as the inclusion of primordial continental material before the onset of plate tectonics. We monitor the surface for plate-like behavior. Since convective vigour is very strong in the early Earth, specialized tracer methods are employed for increased accuracy. In our models, Stokes flow solutions are obtained using a multigrid method specifically designed to handle large viscosity contrasts and non-Newtonian rheology.

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PLANETARY SELF-ORGANIZATION

THE LIFE OF THE EARTH ◽

10.29003/m1481.0514-7468.2020_42_3/271-282 ◽

2020 ◽

Vol 42 (3) ◽

pp. 271-282

Author(s):

OLEG IVANOV

Keyword(s):

Dynamical System ◽

Heat Source ◽

Mantle Convection ◽

Plate Tectonics ◽

Rotation Speed ◽

Self Organization ◽

Heat Sources ◽

Kinematic Parameters ◽

The Earth ◽

New Type

The general characteristics of planetary systems are described. Well-known heat sources of evolution are considered. A new type of heat source, variations of kinematic parameters in a dynamical system, is proposed. The inconsistency of the perovskite-post-perovskite heat model is proved. Calculations of inertia moments relative to the D boundary on the Earth are given. The 9 times difference allows us to claim that the sliding of the upper layers at the Earth's rotation speed variations emit heat by viscous friction.This heat is the basis of mantle convection and lithospheric plate tectonics.

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Earth’s thermal evolution, mantle convection, and Hadean onset of plate tectonics

Journal of Asian Earth Sciences ◽

10.1016/j.jseaes.2017.05.037 ◽

2017 ◽

Vol 145 ◽

pp. 334-348 ◽

Cited By ~ 10

Author(s):

W.G. Ernst

Keyword(s):

Mantle Convection ◽

Plate Tectonics ◽

Thermal Evolution

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Numerical models of slab migration in continental collision zones

Solid Earth ◽

10.5194/se-3-293-2012 ◽

2012 ◽

Vol 3 (2) ◽

pp. 293-306 ◽

Cited By ~ 38

Author(s):

V. Magni ◽

J. van Hunen ◽

F. Funiciello ◽

C. Faccenna

Keyword(s):

Subduction Zone ◽

Plate Tectonics ◽

Numerical Models ◽

Continental Collision ◽

Force Balance ◽

Small Scale ◽

Dip Angle ◽

External Forces ◽

Stress Dependent ◽

Subduction System

Abstract. Continental collision is an intrinsic feature of plate tectonics. The closure of an oceanic basin leads to the onset of subduction of buoyant continental material, which slows down and eventually stops the subduction process. In natural cases, evidence of advancing margins has been recognized in continental collision zones such as India-Eurasia and Arabia-Eurasia. We perform a parametric study of the geometrical and rheological influence on subduction dynamics during the subduction of continental lithosphere. In our 2-D numerical models of a free subduction system with temperature and stress-dependent rheology, the trench and the overriding plate move self-consistently as a function of the dynamics of the system (i.e. no external forces are imposed). This setup enables to study how continental subduction influences the trench migration. We found that in all models the slab starts to advance once the continent enters the subduction zone and continues to migrate until few million years after the ultimate slab detachment. Our results support the idea that the advancing mode is favoured and, in part, provided by the intrinsic force balance of continental collision. We suggest that the advance is first induced by the locking of the subduction zone and the subsequent steepening of the slab, and next by the sinking of the deepest oceanic part of the slab, during stretching and break-off of the slab. These processes are responsible for the migration of the subduction zone by triggering small-scale convection cells in the mantle that, in turn, drag the plates. The amount of advance ranges from 40 to 220 km and depends on the dip angle of the slab before the onset of collision.

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Towards community-driven paleogeographic reconstructions: integrating open-access paleogeographic and paleobiology data with plate tectonics

Biogeosciences ◽

10.5194/bg-10-1529-2013 ◽

2013 ◽

Vol 10 (3) ◽

pp. 1529-1541 ◽

Cited By ~ 42

Author(s):

N. Wright ◽

S. Zahirovic ◽

R. D. Müller ◽

M. Seton

Keyword(s):

Ocean Circulation ◽

Plate Tectonics ◽

Numerical Models ◽

Plate Motion ◽

Temporal Data Mining ◽

Dynamic Topography ◽

Southeastern Australia ◽

Eastern Australia ◽

Spatio Temporal ◽

Fossil Data

Abstract. A variety of paleogeographic reconstructions have been published, with applications ranging from paleoclimate, ocean circulation and faunal radiation models to resource exploration; yet their uncertainties remain difficult to assess as they are generally presented as low-resolution static maps. We present a methodology for ground-truthing the digital Palaeogeographic Atlas of Australia by linking the GPlates plate reconstruction tool to the global Paleobiology Database and a Phanerozoic plate motion model. We develop a spatio-temporal data mining workflow to validate the Phanerozoic Palaeogeographic Atlas of Australia with paleoenvironments derived from fossil data. While there is general agreement between fossil data and the paleogeographic model, the methodology highlights key inconsistencies. The Early Devonian paleogeographic model of southeastern Australia insufficiently describes the Emsian inundation that may be refined using biofacies distributions. Additionally, the paleogeographic model and fossil data can be used to strengthen numerical models, such as the dynamic topography and the associated inundation of eastern Australia during the Cretaceous. Although paleobiology data provide constraints only for paleoenvironments with high preservation potential of organisms, our approach enables the use of additional proxy data to generate improved paleogeographic reconstructions.

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The interplay between recycled and primordial heterogeneities: predicting Earth's mantle dynamics via numerical modeling

10.5194/egusphere-egu21-10251 ◽

2021 ◽

Author(s):

Matteo Desiderio ◽

Anna J. P. Gülcher ◽

Maxim D. Ballmer

Keyword(s):

Lower Mantle ◽

Mantle Convection ◽

Large Scale ◽

Numerical Models ◽

Bulk Composition ◽

Oceanic Lithosphere ◽

Mantle Dynamics ◽

Density Anomaly ◽

Mantle Mineral ◽

Intrinsic Strength

According to geochemical and geophysical observations, Earth's lower mantle appears to be strikingly heterogeneous in composition. An accurate interpretation of these findings is critical to constrain Earth's bulk composition and long-term evolution. To this end, two main models have gained traction, each reflecting a different style of chemical heterogeneity preservation: the 'marble cake' and 'plum pudding' mantle. In the former, heterogeneity is preserved in the form of narrow streaks of recycled oceanic lithosphere, stretched and stirred throughout the mantle by convection. In the latter, domains of intrinsically strong, primordial material (enriched in the lower-mantle mineral bridgmanite) may resist convective entrainment and survive as coherent blobs in the mid mantle. Microscopic scale processes certainly affect macroscopic properties of mantle materials and thus reverberate on large-scale mantle dynamics. A cross-disciplinary effort is therefore needed to constrain present-day Earth structure, yet countless variables remain to be explored. Among previous geodynamic studies, for instance, only few have attempted to address how the viscosity and density of recycled and primordial materials affect their mutual mixing and interaction in the mantle.Here, we apply the finite-volume code STAGYY to model thermochemical convection of the mantle in a 2D spherical-annulus geometry. All models are initialized with a lower, primordial layer and an upper, pyrolitic layer (i.e., a mechanical mixture of basalt and harzburgite), as is motivated by magma-ocean solidification studies. We explore the effects of material properties on the style of mantle convection and heterogeneity preservation. These parameters include (i) the intrinsic strength of basalt (viscosity), (ii) the intrinsic density of basalt, and (iii) the intrinsic strength of the primordial material.Our preliminary models predict a range of different mantle mixing styles. A 'marble cake'-like regime is observed for low-viscosity primordial material (~30 times weaker than the ambient mantle), with recycled oceanic lithosphere preserved as streaks and thermochemical piles accumulating near the core-mantle boundary. Conversely, 'plum pudding' primordial blobs are also preserved when the primordial material is relatively strong, in addition to the 'marble cake' heterogeneities mentioned above. Most notably, however, the rheology and the density anomaly of basalt affect the appearance of both recycled and primordial heterogeneities. In particular, they control the stability, size and geometry of thermochemical piles, the enhancement of basaltic streaks in the mantle transition zone, and they influence the style of primordial material preservation. These results indicate the important control that the physical properties of mantle constituents exert on the style of mantle convection and mixing over geologic time. Our numerical models offer fresh insights into these processes and may advance our understanding of the composition and structure of Earth's lower mantle.

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The importance of phase morphology for rheology of ferropericlase-bridgmanite mixtures

10.5194/egusphere-egu21-4384 ◽

2021 ◽

Author(s):

Marcel Thielmann ◽

Gregor Golabek ◽

Hauke Marquardt

Keyword(s):

Lower Mantle ◽

Mantle Convection ◽

Effective Viscosity ◽

Large Scale ◽

Numerical Models ◽

Phase Morphology ◽

Strong Impact ◽

Analytical Approximations ◽

The Impact ◽

Strong Control

The rheology of the Earth&#8217;s lower mantle is poorly constrained due to a lack of knowledge of the rheological behaviour of its constituent minerals. In addition, the lower mantle does not consist of only a single, but of multiple mineral phases with differing deformation behaviour. The rheology of Earth&#8217;s lower mantle is thus not only controlled by the rheology of its individual constituents (bridgmanite and ferropericlase), but also by their interplay during deformation. This is particularly important when the viscosity contrast between the different minerals is large. Experimental studies have shown that ferropericlase may be significantly weaker than bridgmanite and may thus exert a strong control on lower mantle rheology.Here, we thus explore the impact of phase morphology on the rheology of a ferropericlase-bridgmanite mixture using numerical models. We find that elongated ferropericlase structures within the bridgmanite matrix significantly lower the effective viscosity, even in cases where no interconnected network of weak ferropericlase layers has been formed. In addition to the weakening, elongated ferropericlase layers result in a strong viscous anisotropy. Both of these effects may have a strong impact on lower mantle dynamics, which makes is necessary to develop upscaling methods to include them in large-scale mantle convection models. We develop a numerical-statistial approach to link the statistical properties of a ferropericlase-bridgmanite mixture to its effective viscosity tensor. With this approach, both effects are captured by analytical approximations that have been derived to describe the evolution of the effective viscosity (and its anisotropy) of a two-phase medium with aligned elliptical inclusions, thus allowing to include these microscale processes in large-scale mantle convection models.

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What drives tectonic plates?

Science Advances ◽

10.1126/sciadv.aax4295 ◽

2019 ◽

Vol 5 (10) ◽

pp. eaax4295 ◽

Cited By ~ 12

Author(s):

Nicolas Coltice ◽

Laurent Husson ◽

Claudio Faccenna ◽

Maëlis Arnould

Keyword(s):

Mantle Convection ◽

Plate Tectonics ◽

Dynamic Models ◽

Dynamic Balance ◽

Mantle Flow ◽

Consistent System ◽

Tectonic Plates ◽

Slowing Down ◽

Ill Posed

Does Earth’s mantle drive plates, or do plates drive mantle flow? This long-standing question may be ill posed, however, as both the lithosphere and mantle belong to a single self-organizing system. Alternatively, this question is better recast as follows: Does the dynamic balance between plates and mantle change over long-term tectonic reorganizations, and at what spatial wavelengths are those processes operating? A hurdle in answering this question is in designing dynamic models of mantle convection with realistic tectonic behavior evolving over supercontinent cycles. By devising these models, we find that slabs pull plates at rapid rates and tear continents apart, with keels of continents only slowing down their drift when they are not attached to a subducting plate. Our models show that the tectonic tessellation varies at a higher degree than mantle flow, which partly unlocks the conceptualization of plate tectonics and mantle convection as a unique, self-consistent system.

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