The Physics of Changing Tectonic Regimes: Implications for the Temporal Evolution of Mantle Convection and the Thermal History of Venus

Weller, M. B.; Kiefer, W. S.

doi:10.1029/2019je005960

Cited by 61 publications

(68 citation statements)

References 123 publications

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“…We discuss the implications of our results for the design of future missions to Venus and for the potential habitability of exoplanets inside the inner edge of the traditional "habitable zone" in Section 7. Finally, recently published complimentary work by Weller and Kiefer (2019) supports many of our conclusions.…”

Section: Introductionsupporting

confidence: 86%

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Venusian Habitable Climate Scenarios: Modeling Venus through time and applications to slowly rotating Venus-Like Exoplanets

Way

Genio

2019

Preprint

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Section: Introductionsupporting

confidence: 86%

“…8.) This stagnant lid mode may then allow very large mantle upwelling and/or downwelling centers that would produce some of the features we see on Venus' surface today produced over hundreds of millions of years, as described most recently in the works of e.g Rolf et al (2018); Weller and Kiefer (2019).…”

Section: )mentioning

confidence: 88%

Venusian Habitable Climate Scenarios: Modeling Venus through time and applications to slowly rotating Venus-Like Exoplanets

Way

Genio

2019

Preprint

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“…8. This stagnant lid mode may then allow very large mantle upwelling and/or downwelling centers that would produce some of the features we see on Venus' surface today produced over hundreds of millions of years, as described most recently in the works of, for example, Rolf et al (2018) and Weller and Kiefer (2019).…”

Section: Resultsmentioning

confidence: 91%

Venusian Habitable Climate Scenarios: Modeling Venus Through Time and Applications to Slowly Rotating Venus‐Like Exoplanets

2020

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One popular view of Venus' climate history describes a world that has spent much of its life with surface liquid water, plate tectonics, and a stable temperate climate. Part of the basis for this optimistic scenario is the high deuterium to hydrogen ratio from the Pioneer Venus mission that was interpreted to imply Venus had a shallow ocean's worth of water throughout much of its history. Another view is that Venus had a long-lived (∼100 million years) primordial magma ocean with a CO 2 and steam atmosphere. Venus' long-lived steam atmosphere would sufficient time to dissociate most of the water vapor, allow significant hydrogen escape, and oxidize the magma ocean. A third scenario is that Venus had surface water and habitable conditions early in its history for a short period of time (<1 Gyr), but that a moist/runaway greenhouse took effect because of a gradually warming Sun, leaving the planet desiccated ever since. Using a general circulation model, we demonstrate the viability of the first scenario using the few observational constraints available. We further speculate that large igneous provinces and the global resurfacing hundreds of millions of years ago played key roles in ending the clement period in its history and presenting the Venus we see today. The results have implications for what astronomers term "the habitable zone," and if Venus-like exoplanets exist with clement conditions akin to modern Earth, we propose to place them in what we term the "optimistic Venus zone." Plain Language SummaryWe have little data on our neighbor Venus to help us understand its climate history. Yet Earth and Venus are sister worlds: They initially formed close to one another and have nearly the same mass and radius. Despite the differences in their current atmospheres and surface temperatures, they likely have similar bulk compositions, making comparison between them extremely valuable for illuminating their distinct climate histories. We analyze our present data on Venus alongside knowledge about Earth's climate history to make a number of exciting claims. Evaluating several snapshots in time over the past 4+ billion years, we show that Venus could have sustained liquid water and moderate temperatures for most of this period. Cloud feedbacks from a slowly rotating world with surface liquid water reservoirs were the keys to keeping the planet clement. Contrast this with its current surface temperature of 450 • and an atmosphere dominated by carbon dioxide and nitrogen. Our results demonstrate that it was not the gradual warming of the Sun over the eons that contributed to Venus present hothouse state. Rather, we speculate that large igneous provinces and the global resurfacing hundreds of millions of years ago played key roles in ending the clement period in its history.

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“…(2018) tended to mobilize the surface globally, but the authors did not closely investigate whether parts of the surface resist recycling during these events. Such a tendency has recently been modeled by Weller and Kiefer (2020). In any case, what is observed on the present surface of Venus would be strongly shaped by an overturn event.…”

Section: Introductionmentioning

confidence: 84%

Dynamics of Lithospheric Overturns and Implications for Venus's Surface

et al. 2020

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Across the solar system, planetary surfaces and specifically their volcano-tectonic structures offer windows into the dynamic evolution of planetary interiors. Volcanism and tectonism rejuvenate the planetary surface depending on the rate and style of magmatic and tectonic processes. While the present Earth's surface is, at the large scale, dominated by ocean-plate tectonics (Crameri et al., 2019), other bodies' surfaces are either dominated by extensive volcanism (e.g., Io) or show very little to no sign of recent activity. The latter is the case for the classical stagnant-lid bodies, Mars, Mercury, and the Moon, which feature a strong immobile lithosphere; the global-scale convection is or was (if convection ceased at some point) restricted to the Abstract Venus is currently characterized by stagnant-lid mantle convection, but could have previously experienced episodes of global resurfacing due to lithospheric overturn. Using numerical models of Venus's interior, we attempt to explain Venus's surface characteristics in the context of interior evolution and to understand how Venus's tectonic history has diverged from Earth's. For both the stagnant-and the episodic-lid regime, we explore the role of reference mantle viscosity; for the latter regime, we also explore the role of the lithospheric yield stress. Our stagnant-lid models predict thicker crust and younger surface than typically inferred from cratering statistics. When considering resurfacing episodes, the yield stress influences the frequency of overturns, which limits crustal thickness to better agree with previous independent estimates. Surface age is variable and depends on overturn frequency and resurfacing rate between overturns but reaches larger values just before an upcoming overturn event compared to values in the stagnant-lid cases. Both regimes predict substantial lateral variations in surface age, instead of an end-member uniform surface age indicating the cessation time of the last overturn, because ongoing volcanic resurfacing is spatially heterogeneous and dominates over tectonic resurfacing. Reviewing the crater-based surface age variations suggests that the model-predicted age spreads in the episodic scenario could be consistent with Venus's cratering record. Moreover, we find that a small fraction of crust can resist recycling during overturns. These outcomes indicate that overturn events may allow for surface age variations that reproduce Venus's surface better than stagnant-lid models. Plain Language Summary In contrast to Earth, Venus currently does not feature plate tectonics inhibiting effective crustal recycling into the planetary interior. Yet, its surface features only few and almost randomly distributed craters, which suggests a globally young and more homogeneous surface age than on other planetary surfaces. To date, it remains unclear whether these surface characteristics are generated in an equilibrium style of resurfacing due to volcanism or whether largescale tectonic overturns are required to explain the observations. Her...

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The Physics of Changing Tectonic Regimes: Implications for the Temporal Evolution of Mantle Convection and the Thermal History of Venus

Cited by 61 publications

References 123 publications

Venusian Habitable Climate Scenarios: Modeling Venus through time and applications to slowly rotating Venus-Like Exoplanets

Venusian Habitable Climate Scenarios: Modeling Venus through time and applications to slowly rotating Venus-Like Exoplanets

Venusian Habitable Climate Scenarios: Modeling Venus Through Time and Applications to Slowly Rotating Venus‐Like Exoplanets

Dynamics of Lithospheric Overturns and Implications for Venus's Surface

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