2012
DOI: 10.5194/se-3-467-2012
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Dynamics of interplate domain in subduction zones: influence of rheological parameters and subducting plate age

Abstract: Abstract. The properties of the subduction interplate domain are likely to affect not only the seismogenic potential of the subduction area but also the overall subduction process, as it influences its viability. Numerical simulations are performed to model the long-term equilibrium state of the subduction interplate when the diving lithosphere interacts with both the overriding plate and the surrounding convective mantle. The thermomechanical model combines a nonNewtonian viscous rheology and a pseudo-brittle… Show more

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Cited by 22 publications
(35 citation statements)
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“…We test the effect of the box bottom condition, either closed and free-slip or open to mantle in-and outflows. When the box bottom is open, a vertical resistance against flow is imposed along the box base, mimicking a viscosity jump 10 times higher than above (Ribe and Christensen, 1994;Arcay, 2017). The results show that the bottom mechanical condition does not modify the future evolution of the fracture zone.…”
Section: Initial Thermal Structure and Boundary Conditionsmentioning
confidence: 97%
See 1 more Smart Citation
“…We test the effect of the box bottom condition, either closed and free-slip or open to mantle in-and outflows. When the box bottom is open, a vertical resistance against flow is imposed along the box base, mimicking a viscosity jump 10 times higher than above (Ribe and Christensen, 1994;Arcay, 2017). The results show that the bottom mechanical condition does not modify the future evolution of the fracture zone.…”
Section: Initial Thermal Structure and Boundary Conditionsmentioning
confidence: 97%
“…The tracer density is uniform over the simulation box (∼ 3.2 per km 2 ), verifying that at least nine tracers fill the smallest meshes. This numerical discretization has been tested and validated in a previous study (Arcay, 2017). Note that because the total pressure is not directly solved by the code in Christensen (1992), the lithostatic pressure is used instead in Eq.…”
Section: Numerical Code and Resolutionmentioning
confidence: 99%
“…100; Fig. 8), possibly too extreme [Arcay, 2012]. Indeed, this f  value of 100 may apply to a strongly hydrated mantle (when serpentine is predicted to be stable) but might not correspond to an amphibole-bearing mantle (i.e., modeled here for water content as low as 0.5%wt).…”
Section: Accepted Manuscriptmentioning
confidence: 93%
“…The second one corresponds to a stiffer mantle (rheology labeled St; [Arcay, 2012;Arcay, 2017, in revision] and is used to discuss the influence of the anhydrous viscosity law on the time scale of arc thermal thinning. To take into account the influence of water content ([OH -]) on rheology, we apply a strength reduction depending exponentially on water content (Fig.…”
Section: Rheological Modelmentioning
confidence: 99%
“…During subduction, the sinking slab and the overlying plate form a kinetically and mechanically decoupled plate interface or subduction channel controlled by the thermal structure of subduction (Arcay, , ; Arcay et al, ; Furukawa, ; Wada & Wang, ; Wada et al, ). A common maximum depth of slab‐mantle decoupling (MDD) of approximately 80 km is inferred for all subduction zones (Syracuse et al, ; Wada & Wang, ).…”
Section: Introductionmentioning
confidence: 99%