Mantle convection and evolution with growing continents

Walzer, Uwe; Hendel, Roland

doi:10.1029/2007jb005459

Cited by 30 publications

(12 citation statements)

References 135 publications

(186 reference statements)

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“…If the computed model temperature, T , approaches the melting temperature, T m , in a sufficiently large volume, i.e., if the condition of equation () is fulfilled, then chemical differentiation occurs. The new CC material will be welded to an existent continent if an oceanic plate has carried it to a continental margin [ Walzer and Hendel , ]. Our present model also incorporates those buoyancy forces that are generated by thermally induced deflections of the phase boundaries of the olivine‐wadsleyite transition and of the ringwoodite‐perovskite transition.…”

Section: Model Descriptionsupporting

confidence: 80%

“…In accordance with Komiya ], we assert that continental growth is determined by both efflux from the mantle and recycling of CC material back into the mantle. The corresponding tracer method is described in Walzer and Hendel ]. The results of our numerical model also show quiescent intervals of magmatic evolution (Figure ) in agreement with observation.…”

Section: Discussionmentioning

confidence: 99%

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Real episodic growth of continental crust or artifact of preservation? A 3‐D geodynamic model

Walzer

Hendel

2013

JGR Solid Earth

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[1] We investigate whether the observed zircon age distribution of continental crust (CC) is produced by real crustal growth episodes or is only an artifact of preservation. In connection with the second alternative of this question, other authors proposed that there was little episodicity in the production of new CC and that modeling corroborates this opinion. We conclude that a combination of the two answers might be possible. In matters of modeling, however, we ascertain that a dynamic modeling of the convection-differentiation system of the mantle reveals the high probability of magmatic episodes. We solve the full set of balance equations in a 3-D spherical-shell mantle. The heat-producing elements are redistributed by chemical differentiation. A realistic solidus model of mantle peridotite is essential for an applicable model. The solidus depends not only on depth but also on the volatile concentration. Furthermore, we introduced realistic profiles of Grüneisen parameter, viscosity, adiabatic temperature, thermal expansivity, and specific heat. Our model automatically produces lithospheric plates and growing continents. Regarding number, size, form, distribution, and surface velocity of the continents, no constraints have been prescribed. Regions of the input parameter space (Ra, y , k, f 3 ) that are favorable with respect to geophysical quantities show simultaneously not only episodicity of CC growth but also a reproduction of the observed zircon-age maxima referring to the instants of time. We also obtain Archean events for ages greater than 3000 Ma that are not or scarcely visible in the observed zircon ages. Sinusoidal parts of the evolution curve of qob, Ur, and E kin are superposed with a monotonous decrease. The volumetrically averaged mantle temperature, T mean , however, decreases smoothly and slowly, nearly without pronounced variations. Therefore, we can dismiss catastrophic mechanisms that simultaneously incorporate the whole mantle.

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Section: Model Descriptionsupporting

confidence: 80%

Section: Discussionmentioning

confidence: 99%

Real episodic growth of continental crust or artifact of preservation? A 3‐D geodynamic model

Walzer

Hendel

2013

JGR Solid Earth

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“…1i) (Condie 1998;Campbell & Allen 2008), possibly linked to large-scale mantle overturn events (Condie 2000;Rino et al 2004), and the cessation of, or decrease in, subduction flux (Silver & Behn 2008a). Recent models integrating chemical differentiation with mantle convection also predict the episodicity of juvenile crust formation (Walzer & Hendel 2008), as do large-scale mantle overturn events that are thought to take place on a timescale of several hundred million years (Davies 1995).…”

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confidence: 99%

Palaeoproterozoic supercontinents and global evolution: correlations from core to atmosphere

Reddy

Evans

2009

115

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The Palaeoproterozoic era was a time of profound change in Earth evolution and represented perhaps the first supercontinent cycle, from the amalgamation and dispersal of a possible Neoarchaean supercontinent to the formation of the 1.9-1.8 Ga supercontinent Nuna. This supercontinent cycle, although currently lacking in palaeogeographic detail, can in principle provide a contextual framework to investigate the relationships between deep-Earth and surface processes. In this article, we graphically summarize secular evolution from the Earth's core to its atmosphere, from the Neoarchaean to the Mesoproterozoic eras (specifically 3.0-1.2 Ga), to reveal intriguing temporal relationships across the various 'spheres' of the Earth system. At the broadest level our compilation confirms an important deep-Earth event at c. 2.7 Ga that is manifested in an abrupt increase in geodynamo palaeointensity, a peak in the global record of large igneous provinces, and a broad maximum in several mantle-depletion proxies. Temporal coincidence with juvenile continental crust production and orogenic gold, massive-sulphide and porphyry copper deposits, indicate enhanced mantle convection linked to a series of mantle plumes and/or slab avalanches. The subsequent stabilization of cratonic lithosphere, the possible development of Earth's first supercontinent and the emergence of the continents led to a changing surface environment in which voluminous banded iron-formations could accumulate on the continental margins and photosynthetic life could flourish. This in turn led to irreversible atmospheric oxidation at 2.4-2.3 Ga, extreme events in global carbon cycling, and the possible dissipation of a former methane greenhouse atmosphere that resulted in extensive Palaeoproterozoic ice ages. Following the great oxidation event, shallow marine sulphate levels rose, sediment-hosted and iron-oxide-rich metal deposits became abundant, and the transition to sulphide-stratified oceans provided the environment for early eukaryotic evolution. Recent advances in the geochronology of the global stratigraphic record have made these inferences possible. Frontiers for future research include more refined modelling of Earth's thermal and geodynamic evolution, palaeomagnetic studies of geodynamo intensity and continental motions, further geochronology and tectonic syntheses at regional levels, development of new isotopic systems to constrain geochemical cycles, and continued innovation in the search for records of early life in relation to changing palaeoenvironments.

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“…In order to overcome the contradictions associated with the geochemical data, we decided (1) to expand the thermal model of mantle convection by including the most significant chemical factors in it (Christensen and Yuen, 1984;Kobozev and Myasnikov, 1987;Christensen, 1997;McNamara and Zhong, 2004;Walzer and Hendel, 2008). We also planned (2) to simulate thermochemical convection mode, which can assemble the supercontinents.…”

Section: The Directions and The Objectives Of Researchmentioning

confidence: 98%

The history of supercontinents and oceans from the standpoint of thermochemical mantle convection

Lobkovsky

Kotelkin²

2015

Precambrian Research

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Mantle convection and evolution with growing continents

Cited by 30 publications

References 135 publications

Real episodic growth of continental crust or artifact of preservation? A 3‐D geodynamic model

Real episodic growth of continental crust or artifact of preservation? A 3‐D geodynamic model

Palaeoproterozoic supercontinents and global evolution: correlations from core to atmosphere

The history of supercontinents and oceans from the standpoint of thermochemical mantle convection

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