Global tectonic evolution of Venus, from exogenic to endogenic over time, and implications for early Earth processes

Vicki L Hansen

doi:10.1098/rsta.2017.0412

Global tectonic evolution of Venus, from exogenic to endogenic over time, and implications for early Earth processes

Vicki L Hansen

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21 Scopus citations

Abstract

Venus provides a rich arena in which to stretch one's tectonic imagination with respect to non-plate tectonic processes of heat transfer on an Earth-like planet. Venus is similar to Earth in density, size, inferred composition and heat budget. However, Venus' lack of plate tectonics and terrestrial surficial processes results in the preservation of a unique surface geologic record of non-plate tectonomagmatic processes. In this paper, I explore three global tectonic domains that represent changes in global conditions and tectonic regimes through time, divided respectively into temporal eras. Impactors played a prominent role in the ancient era, characterized by thin global lithosphere. The Artemis superstructure era highlights sublithospheric flow processes related to a uniquely large super plume. The fracture zone complex era, marked by broad zones of tectonomagmatic activity, witnessed coupled spreading and underthrusting, since arrested. These three tectonic regimes provide possible analogue models for terrestrial Archaean craton formation, continent formation without plate tectonics, and mechanisms underlying the emergence of plate tectonics. A bolide impact model for craton formation addresses the apparent paradox of both undepleted mantle and growth of Archaean crust, and recycling of significant Archaean crust to the mantle.

Original language	English (US)
Article number	20170412
Journal	Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences
Volume	376
Issue number	2132
DOIs	https://doi.org/10.1098/rsta.2017.0412
State	Published - Nov 13 2018
Externally published	Yes

Bibliographical note

Funding Information:
Data accessibility. This article has no additional data. Competing interests. I declare I have no competing interests. Funding. I received no funding for this study. Acknowledgements. V.L.H. thanks colleague I. López for collaborative Venus geologic mapping and discussion, J. W. Goodge for reviews of early versions of the manuscript, and editor C. J. Hawkesworth, R. E. Ernst and an anonymous referee. V.L.H. also thanks the Institute of Advanced Studies, University of Western Australia for support as a Gledden Senior Visiting Fellow, and M. Keep and A. I. Kemp for Venus–early Earth discussions at UWA and the glorious outback. V.L.H. is grateful for support from the McKnight Foundation, and the University of Minnesota. The author has no financial conflicts of interests, or other conflicts of interest with regard to this work.

Publisher Copyright:
© 2018 The Author(s) Published by the Royal Society. All rights reserved.

Keywords

Archaean
Continents
Cratons
Crustal plateaux
Plate tectonics
Venus

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title = "Global tectonic evolution of Venus, from exogenic to endogenic over time, and implications for early Earth processes",

abstract = "Venus provides a rich arena in which to stretch one's tectonic imagination with respect to non-plate tectonic processes of heat transfer on an Earth-like planet. Venus is similar to Earth in density, size, inferred composition and heat budget. However, Venus' lack of plate tectonics and terrestrial surficial processes results in the preservation of a unique surface geologic record of non-plate tectonomagmatic processes. In this paper, I explore three global tectonic domains that represent changes in global conditions and tectonic regimes through time, divided respectively into temporal eras. Impactors played a prominent role in the ancient era, characterized by thin global lithosphere. The Artemis superstructure era highlights sublithospheric flow processes related to a uniquely large super plume. The fracture zone complex era, marked by broad zones of tectonomagmatic activity, witnessed coupled spreading and underthrusting, since arrested. These three tectonic regimes provide possible analogue models for terrestrial Archaean craton formation, continent formation without plate tectonics, and mechanisms underlying the emergence of plate tectonics. A bolide impact model for craton formation addresses the apparent paradox of both undepleted mantle and growth of Archaean crust, and recycling of significant Archaean crust to the mantle.",

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Global tectonic evolution of Venus, from exogenic to endogenic over time, and implications for early Earth processes

Abstract

Bibliographical note

Keywords

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