Abstract
AbstractAs subducting plates reach the base of the upper mantle, some appear to flatten and stagnate, while others seemingly go through unimpeded. This variable resistance to slab sinking has been proposed to affect long-term thermal and chemical mantle circulation. A review of observational constraints and dynamic models highlights that neither the increase in viscosity between upper and lower mantle (likely by a factor 20–50) nor the coincident endothermic phase transition in the main mantle silicates (with a likely Clapeyron slope of –1 to –2 MPa/K) suffice to stagnate slabs. However, together the two provide enough resistance to temporarily stagnate subducting plates, if they subduct accompanied by significant trench retreat. Older, stronger plates are more capable of inducing trench retreat, explaining why backarc spreading and flat slabs tend to be associated with old-plate subduction. Slab viscosities that are ∼2 orders of magnitude higher than background mantle (effective yield stresses of 100–300 MPa) lead to similar styles of deformation as those revealed by seismic tomography and slab earthquakes. None of the current transition-zone slabs seem to have stagnated there more than 60 m.y. Since modeled slab destabilization takes more than 100 m.y., lower-mantle entry is apparently usually triggered (e.g., by changes in plate buoyancy). Many of the complex morphologies of lower-mantle slabs can be the result of sinking and subsequent deformation of originally stagnated slabs, which can retain flat morphologies in the top of the lower mantle, fold as they sink deeper, and eventually form bulky shapes in the deep mantle.
Highlights
In the first part of the paper (Section 2), we review observational constraints on slab morphology from seismic tomography and slab seismicity, and constraints on subduction dynamics from the plate motion record
Mechanisms of Benioff earthquakes and the morphologies of upper-mantle slabs inferred from seismicity and seismic tomography provide direct evidence that the transition zone hinders flow, because many slabs are deformed, and several flattened at the base of the upper mantle (e.g., Lay, 1994; Li et al, 2008)
The many modeling studies done, on how slabs interact with the mantle transition zone, show that there are two main sets of factors (Fig. 1) that can affect whether slabs stagnate or penetrate: (1) the mantle resistance to flow through the upper-lower mantle boundary; and (2) the shape and strength of the slab as it starts interacting with this boundary, where the ability of the trench to retreat plays a crucial role in the former
Summary
Do not; (2) on what time scales slabs are stagnant in the transition zone if they have flattened; (3) how slab-transition zone interaction is reflected in plate motions; and (4) how lower-mantle fast seismic anomalies can be correlated with past subduction. Mechanisms of Benioff earthquakes and the morphologies of upper-mantle slabs inferred from seismicity and seismic tomography provide direct evidence that the transition zone hinders flow, because many slabs are deformed, and several flattened at the base of the upper mantle (e.g., Lay, 1994; Li et al, 2008). It has been debated (1) what causes some slabs to flatten while others
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