Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
1782506 | Planetary and Space Science | 2007 | 8 Pages |
Abstract
Ribbons are regularly spaced, between 2 and 6Â km, troughs that exist on venusian tesserae, which are mainly located in, and characterize to, venusian crustal plateaus. Independent of the geological or temporal relations with other features, regularly and similarly spaced ribbons on several tesserae strongly suggest a thermal control on the thickness of the deformed layer. This can be used to constraint the heat flow at the time of ribbon formation, which holds important implications for the viability of the hypotheses that address the origin and evolution of crustal plateaus. For a brittle-ductile transition â¼1-3Â km deep (as proposed from ribbon spacing), realistic strain rates, and a present-day surface temperature of 740Â K, the implied heat flow is very high, 130-780Â mWÂ mâ2. If Venus has experienced higher surface temperatures due to climate forcing by massive volcanism, then the heat flow could be greatly reduced. For surface temperatures of 850-900Â K the heat flow is 190-560, 60-230 and 20-130Â mWÂ mâ2 for brittle-ductile transition depths of 1, 2 and 3Â km, respectively. Heat flow values around 80-100Â mWÂ mâ2 are reasonable for venusian hotspots, based on terrestrial analogs, but hardly consistent with coldspot settings. High surface temperatures are also required to maintain the crustal solidus deeper than a few kilometers during the formation of ribbon terrains. For the obtained heat flows, a solidus deeper than â¼30Â km (the likely mean value for the crustal thickness) is difficult to achieve. This suggests that a substantial proportion of the crust beneath crustal plateaus was emplaced subsequently to the time when ribbon terrains were formed. Alternatively, at that time a magma reservoir inside the crust could have existed.
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Physical Sciences and Engineering
Earth and Planetary Sciences
Geophysics
Authors
Javier Ruiz,