Mapping mantle flow during retreating subduction: Laboratory models analyzed by feature tracking

Funiciello, Francesca; Moroni, Monica; Piromallo, Claudia; Faccenna, Claudio; Cenedese, A.; Bui, Hanh

doi:10.1029/2005jb003792

Cited by 201 publications

(243 citation statements)

References 71 publications

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“…Thus, besides promoting single-sided subduction, a free surface results in a more characteristic curvature of the subduction trenches along the surface [Schellart et al, 2007]. This feature is formed due to toroidal mantle flow from the region of high pressure below the inclined sinking slab around its edges towards the region of low pressure above the slab, as has been shown by, e.g., analogue modeling [Funiciello et al, 2006] and as found in nature [Zandt and Humphreys, 2008].…”

Section: Sphericity and Three-dimensionalitymentioning

confidence: 74%

A free plate surface and weak oceanic crust produce single‐sided subduction on Earth

Crameri

Tackley

Meilick

et al. 2012

Geophysical Research Letters

161

132

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[1] Earth's lithosphere is characterized by the relative movement of almost rigid plates as part of global mantle convection. Subduction zones on present-day Earth are strongly asymmetric features composed of an overriding plate above a subducting plate that sinks into the mantle. While global self-consistent numerical models of mantle convection have reproduced some aspects of plate tectonics, the assumptions behind these models do not allow for realistic single-sided subduction. Here we demonstrate that the asymmetry of subduction results from two major features of terrestrial plates: (1) the presence of a free deformable upper surface and (2) the presence of weak hydrated crust atop subducting slabs. We show that assuming a free surface, rather than the conventional free-slip surface, allows the dynamical behavior at convergent plate boundaries to change from double-sided to single-sided. A weak crustal layer further improves the behavior towards steady single-sided subduction by acting as lubricating layer between the sinking and the overriding plate. This is a first order finding of the causes of single-sided subduction, which by its own produces important features like the arcuate curvature of subduction trenches. Citation: Crameri, F., P. J. Tackley, I. Meilick, T. V.Gerya, and B. J. P. Kaus (2012), A free plate surface and weak oceanic crust produce single-sided subduction on Earth, Geophys. Res. Lett., 39, L03306,

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Section: Sphericity and Three-dimensionalitymentioning

confidence: 74%

A free plate surface and weak oceanic crust produce single‐sided subduction on Earth

Crameri

Tackley

Meilick

et al. 2012

Geophysical Research Letters

161

132

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“…In 3-D, additional variations in trench motion occur because of along-strike plate bending in response to flow around the plate edges (Funiciello et al, 2006;Schellart et al, 2007;Loiselet et al, 2009;Stegman et al, 2010a;Li and Ribe, 2012), leading to lower retreat of the plate edges and, for very wide plates, a trench stagnation point can develop in the center. Lateral changes in slab buoyancy can also lead to variations in trench motions, which depend on the scale of the features of different buoyancy and their relative contribution to overall slab pull (Martinod et al, 2005;Goes et al, 2008;Mason et al, 2010;Magni et al, 2014;Goes et al, 2014).…”

Section: Subducting-plate Density and Strength: Controls On Trench Momentioning

confidence: 99%

Subduction-transition zone interaction: A review

et al. 2017

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Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. 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.

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“…the extensional tectonics of the southeastern Tyrrhenian region; however, the back-arc extension model and the model for a transform boundary (i.e., more properly a transfer zone linking two destructive margins) across the northeastern Sicily may better fit some of the data presented in this paper. Fore instance, the location of the Tindari Fault System right above the western edge of the Ionian narrow slab, where a complex pattern of mantle return flow is expected [Gvirtzman and Nur, 1999;Marani and Trua, 2002;Faccenna et al, 2004Faccenna et al, , 2005, may well explain its ongoing transtensional kinematics by a combination of pure extension induced by the back-arc processes and of strikeslip movements induced by the mantle flows around the narrow slab [Funiciello et al, 2006]. Moreover, the ongoing transtensional displacements along the Tindari Fault System may support the model of a transfer zone across the northeastern Sicily; however, the evidence that the present activity of the Tindari Fault System is restricted to its northern portion suggests that if such transfer zone is truly developing, this should be in its inception stage.…”

Section: Implications For the Regional Tectonicsmentioning

confidence: 99%

Tectonics and seismicity of the Tindari Fault System, southern Italy: Crustal deformations at the transition between ongoing contractional and extensional domains located above the edge of a subducting slab

et al. 2006

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The Tindari Fault System (southern Tyrrhenian Sea, Italy) is a regional zone of brittle deformation located at the transition between ongoing contractional and extensional crustal compartments and lying above the western edge of a narrow subducting slab. Onshore structural data, an offshore seismic reflection profile, and earthquake data are analyzed to constrain the present geometry of the Tindari Fault System and its tectonic evolution since Neogene, including the present seismicity. Results show that this zone of deformation consists of a broad NNW trending system of faults including sets of right‐lateral, left‐lateral, and extensional faults as well as early strike‐slip faults reworked under late extension. Earthquakes and other neotectonic data provide evidence that the Tindari Fault System is still active in the central and northern sectors and mostly accommodates extensional or right‐lateral transtensional displacements on a diffuse array of faults. From these data, a multiphase tectonic history is inferred, including an early phase as a right‐lateral strike‐slip fault and a late extensional reworking under the influence of the subduction‐related processes, which have led to the formation of the Tyrrhenian back‐arc basin. Within the present, regional, geodynamic context, the Tindari Fault System is interpreted as an ongoing accommodation zone between the adjacent contractional and extensional crustal compartments, these tectonic compartments relating to the complex processes of plate convergence occurring in the region. The Tindari Fault System might also be included in an incipient, oblique‐extensional, transfer zone linking the ongoing contractional belts in the Calabrian‐Ionian and southern Tyrrhenian compartments.

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Mapping mantle flow during retreating subduction: Laboratory models analyzed by feature tracking

Cited by 201 publications

References 71 publications

A free plate surface and weak oceanic crust produce single‐sided subduction on Earth

A free plate surface and weak oceanic crust produce single‐sided subduction on Earth

Subduction-transition zone interaction: A review

Tectonics and seismicity of the Tindari Fault System, southern Italy: Crustal deformations at the transition between ongoing contractional and extensional domains located above the edge of a subducting slab

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