Evolution of the slab bending radius and the bending dissipation in three-dimensional subduction models with a variable slab to upper mantle viscosity ratio

W. P. Schellart*

*Corresponding author for this work

Research output: Contribution to JournalArticleAcademicpeer-review

Abstract

Three-dimensional laboratory subduction models are presented investigating the influence of the slab/upper mantle viscosity ratio (ηSPUM) on the slab bending radius (RB), with ηSPUM = 66-1375. Here, RB is non-dimensionalized by dividing it by the upper mantle thickness (TUM). The results show that RB/TUM varies with time, reaching a maximum when the subduction velocity is maximum. Furthermore, RB/TUM increases approximately linearly with increasing ηSPUM for the investigated viscosity range. The model results show that the slab bending force (FBe) and the energy dissipation during bending (F{cyrillic}Be) are small compared to the negative buoyancy force of the slab (FBu) and the potential energy release during sinking (F{cyrillic}Bu). Maxima in F{cyrillic}Be/F{cyrillic}Bu (≈ FBe/FBu) are reached in the early stage of subduction when RB/TUM is minimum and the slab tip is at 220-440 km depth. Maximum F{cyrillic}Be/F{cyrillic}Bu increases with increasing ηSPUM, with F{cyrillic}Be/F{cyrillic}Bu(max) = 0.06, 0.11, 0.18 and 0.22 for ηSPUM = 66, 217, 709 and 1375, respectively. For subduction depths > 220-440 km, F{cyrillic}Be/F{cyrillic}Bu = 0.02-0.11 for all viscosity ratios. Assuming that in nature ηSPUM < 1000, and that viscous dissipation during plan view curvature of the slab is ≤ 1%, the models predict that in nature most of the slab's potential energy is used to drive mantle flow (on average 88%-97% and minimally 81%), whilst only a small component is used to bend the subducting plate at the hinge (on average 2-11% and maximally 18%). Applying the model predictions for RB/TUM and F{cyrillic}Be/F{cyrillic}Bu to natural subduction zones implies that in nature ηSPUM = 1-7 × 102 and ηUM = 0.8-2.7 × 1020 Pa·s. Finally, the laboratory models, which use glucose syrup and silicone oil as modelling materials, highlight the importance of accurate control on temperature during an experiment. New material investigations show that the viscosity of these two materials decreases exponentially with temperature in the range 3-33 °C, their density decreases approximately linearly with temperature, and their coefficient of thermal volumetric expansion is 3.8-4.2 × 10- 4 C- 1 (glucose syrup) and 9.2 × 10- 4 C- 1 (silicone oil).

Original languageEnglish
Pages (from-to)309-319
Number of pages11
JournalEarth and Planetary Science Letters
Volume288
Issue number1-2
DOIs
Publication statusPublished - 30 Oct 2009

Keywords

  • bending dissipation
  • bending force
  • bending radius
  • coefficient of volumetric thermal expansion
  • density
  • glucose syrup
  • potential energy
  • silicone
  • slab
  • Subduction
  • upper mantle viscosity
  • viscosity

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