Other
Scientific paper
Dec 2008
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2008agufmdi51a..05v&link_type=abstract
American Geophysical Union, Fall Meeting 2008, abstract #DI51A-05
Other
8125 Evolution Of The Earth (0325), 8130 Heat Generation And Transport, 8149 Planetary Tectonics (5475)
Scientific paper
In the past decade, several studies have documented the effectiveness of plastic yielding in causing a basic approximation of plate tectonic behavior in mantle convection models with strongly temperature dependent viscosity, strong enough to form a rigid lid in the absence of yielding. The vast majority of such research to date has been in either two-dimensional, or three-dimensional cartesian geometry. Also, scalings for mixed internally and bottom heated convection are not well established. In our previous study (van Heck and Tackley, 2008), mantle convection calculations were performed to investigate the planforms of self consistent tectonic plates in three-dimensional spherical geometry. We found, for internally heated convection and fixed Rayleigh number, that when yield stress of the lithosphere is low a "great circle"-subduction zone forms. At low-intermediate yield stresses plates, spreading centers and subduction zones formed and were destroyed over time. At high-intermediate yield stresses two plates form, separated by a great circle boundary that is a spreading centre on one side and a subduction zone on the other side. At high yield stresses a rigid lid was observed. Here, the planforms found by van Heck and Tackley (2008) are investigated further, leading to a more general understanding of how different parameters determine which planform prevails. New calculations are performed to investigate the effect of varying Rayleigh number and different internal/bottom heating ratios. Several diagnostics are used to analyze how successful each model is in producing tectonic plates. Cases with zero internal heating are compared to cases which have both internal heating and bottom heating. The results are compared to analytical scalings for boundary regimes as well as scalings for heat flux. This allows us to scale to different planets of different sizes and can be applied to the evolution of Earth, Mars and Venus as well as terrestrial extra-solar planets. Also, we can study the tectonic evolution of a cooling planet. As radioactive heat production decreases over time the tectonic mode (e.g. changes in plate size, rigid lid convection to tectonic plates, smoothly evolving plates to more episodic, time dependent, tectonics) is likely to change. Grigné et al. (2005) showed that surface heat flux depends on the wavelength of convection so the scalings for heat flux will not only depend on the internal/bottom heating ratio but also on the planform since the wavelength of convection (i.e. plate size) changes for different planforms (van Heck and Tackley, 2008).
Tackley Paul
van Heck Hein
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