Oblique subduction modelling indicates along-trench tectonic transport of sediments

Malatesta, Cristina; Gerya, Taras; Crispini, Laura; Federico, Laura; Capponi, Giovanni

doi:10.1038/ncomms3456

Cited by 41 publications

(42 citation statements)

References 32 publications

(50 reference statements)

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“…The lateral tectonic migration of sediments is active during the entire subduction process and occurs at different depths both in the accretionary prism and along the slab. As described by Malatesta et al (2013), such migration causes the formation of a trench with variable sediment amount along its axis. The domain from which sediments are removed as they enter the subduction zone generally exhibits a tiny accretionary prism ( Figure 1c).…”

Section: Reference Modelmentioning

confidence: 99%

“…In the last years a variety of models studied subduction zones in 3D using either physical (e.g., Boutelier et al, 2014;Dominguez et al, 2000;Duarte et al 2013;Funiciello et al, 2008;Malavieille and Trullenque, 2009), semianalytical (Royden and Husson, 2006) or numerical methods (e.g., Capitanio et al, 2007;Jadamec and Billen, 2010;Malatesta et al, 2013;Manea et al, 2014;Schellart et al, 2007;Stegman et al, 2010;Sternai et al, 2014;Yamato et al, 2009;Hampel, 2015, 2016); these works tested several subduction-related topics as e.g. the deformation mechanisms and the influencing parameters of accretionary wedges, the role of margins geometry, interplate rheology and mantle processes on upper plate deformation and on subduction kinematics and dynamics.…”

Section: Introductionmentioning

confidence: 99%

“…The evolution of subduction-related processes in an oblique setting is therefore more complex compared to the case of orthogonal platesconvergence (e.g., Boutelier et al, 2012;Malatesta et al, 2013;McCaffrey, 1992). For this reason, 2D models, lacking the third dimension, are not suitable to fully reproduce these particular patterns and 3D models should be used.…”

Section: Introductionmentioning

confidence: 99%

“…In our previous work (Malatesta et al, 2013) we discussed the along-trench tectonic transport of sediments at oblique oceanic subduction zones. In this new work we use similar highresolution 3D thermomechanical modelling approach, to study if and how long-term deformation, topographic evolution and tectonic erosion of the upper plate can vary along the same margin, when involved in an oblique subduction during its early history (15)(16)(17)(18)(19)(20).…”

Section: Introductionmentioning

confidence: 99%

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Interplate deformation at early‐stage oblique subduction: 3‐D thermomechanical numerical modeling

et al. 2016

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Oblique subduction zones are complex settings where the simultaneous action of trench‐normal and trench‐parallel components of convergence can produce heterogeneous deformational pattern of the upper plate and affect the accretional/erosional behavior of the plate margin. Here we present three‐dimensional thermomechanical numerical models that highlight some processes occurring in the early history (15–20 Myr) of intraoceanic oblique subduction zones, which so far represent the less studied case. These models have been compared with a simulation of a slab sinking under a continental plate. We test subduction starting in oceans floored by two classes of lithosphere: layered (fast spreading oceans) and serpentinite rich (slow to ultraslow spreading oceans). Two main domains develop along the margin of both type of oceanic plates: (a) a domain with a mostly stable trench, a shortening upper plate, characterized by the formation of a topographic relief, and (b) a domain with retreating trench and extending upper plate. In general, we observed that varying the subduction obliquity, the margin could either (i) record an erosional to a balanced accretion/erosion regime or (ii) be characterized by a predominant balanced accretion/erosion regime. In both cases, even where the sediment amount in the trench is high, the upper plate experiences tectonic erosion. We suggest that the formation of topographic reliefs on the fore arc is possibly related to the low amount of sediment in the trench, affecting interplate friction and promoting the upper plate indentation against the slab. The Puysegur subduction zone and the central Andes can be possibly natural examples of such a regime.

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Section: Reference Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Interplate deformation at early‐stage oblique subduction: 3‐D thermomechanical numerical modeling

et al. 2016

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“…To demonstrate ASPECT's promise in this field, we here present 3D models of free-plate intraoceanic subduction. Recent 3D subduction models have been applied in the study of along-strike effects such as oblique convergence (Malatesta et al, 2013), toroidal flow (Schellart and 10 Moresi, 2013), varying lithospheric structure (Mason et al, 2010;van Hunen and Allen, 2011;Capitanio and Faccenda, 2012;Duretz et al, 2014), slab width (Stegman et al, 2006;Schellart et al, 2007;Stegman et al, 2010) and the presence of lateral plates (Yamato et al, 2009). Four-dimensional (3D plus time) modeling allows us to investigate more realistically the generics of subduction (e.g.…”

Section: Viscoplastic Subduction Modelsmentioning

confidence: 99%

Implementing nonlinear viscoplasticity in ASPECT: benchmarking and applications to 3D subduction modeling

Glerum

Thieulot

Fraters

et al. 2017

Preprint

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Abstract. ASPECT (Advanced Solver for Problems in Earth's ConvecTion) is a massively parallel finite element code originally designed for modeling thermal convection in the mantle with a Newtonian rheology. The code is characterized by modern numerical methods, high-performance parallelism and extensibility. This last characteristic is illustrated in this work: we have extended the use of ASPECT from global thermal convection modeling to upper mantle-scale applications of subduction.Subduction modeling generally requires the tracking of multiple materials with different properties and with nonlinear 5 viscous and viscoplastic rheologies. To this end, we implemented a frictional plasticity criterion that is combined with a viscous diffusion and dislocation creep rheology. Because ASPECT uses compositional fields to represent different materials (and, since recently, tracers), all material parameters are made dependent on a user-specified number of fields.The goal of this paper is primarily to describe and validate our implementations of complex, multi-material rheology by reproducing the results of four well-known two-dimensional benchmarks: the indentor benchmark, the brick experiment, the 10 sandbox experiment and the slab detachment benchmark. Furthermore, we aim to provide hands-on examples for prospective users by demonstrating the use of multi-material viscoplasticity with three-dimensional, thermomechanical models of oceanic subduction, putting ASPECT on the map as a community code for high-resolution, nonlinear rheology subduction modeling.

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Oblique closure of the northeastern Paleo-Tethys in central China

Liu

Qian

et al. 2015

Tectonics

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A branch of the Paleo-Tethys Ocean once separated the north China plate from the south China plate. However, the mode of closure of the northeastern Paleo-Tethys Ocean during the Late Paleozoic to Early Mesozoic has been debated. One reason for this debate is that the collisional suture zone was later buried by large-scale thrust faults in the southern Qinling-Dabieshan orogen, which made it difficult to reconstruct the amalgamation of the supercontinent in central China. New regional geologic mapping provides stratigraphic and structural constraints on the mechanism of this ocean closure. Our results indicate that dextral transpressional suturing in the southern Qinling-Dabieshan foreland fold-thrust belt resulted in the formation of the northern Yangtze foreland basin, where the stratigraphy precisely shows the time-transgressive closure of the ocean, and the orogenic sediments shed over 1000 km westward from eastern China to the closing Paleo-Tethys. Therefore, we propose an oblique subduction model to describe the closure of the Paleo-Tethys Ocean. Our findings suggest that prolonged slab pull during the oblique subduction of the oceanic plate continued to drive deep continental subduction, thereby forming high-and ultrahigh-pressure metamorphic rocks and leading to sustained ocean closure.

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Oblique subduction modelling indicates along-trench tectonic transport of sediments

Cited by 41 publications

References 32 publications

Interplate deformation at early‐stage oblique subduction: 3‐D thermomechanical numerical modeling

Interplate deformation at early‐stage oblique subduction: 3‐D thermomechanical numerical modeling

Implementing nonlinear viscoplasticity in ASPECT: benchmarking and applications to 3D subduction modeling

Oblique closure of the northeastern Paleo-Tethys in central China

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