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Hindered Trench Migration Due To Slab Steepening Controls the Formation of the Central Andes (2022)

Pons, Michaël ; Sobolev, Stephan V. ; Liu, Sibiao ; [et al.]

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Publication Date: 2024-03-05

Description: The formation of the Central Andes dates back to ∼50 Ma, but its most pronounced episode, including the growth of the Altiplano‐Puna Plateau and pulsatile tectonic shortening phases, occurred within the last 25 Ma. The reason for this evolution remains unexplained. Using geodynamic numerical modeling we infer that the primary cause of the pulses of tectonic shortening and growth of the Central Andes is the changing geometry of the subducted Nazca plate, and particularly the steepening of the mid‐mantle slab segment which results in a slowing down of the trench retreat and subsequent increase in shortening of the advancing South America plate. This steepening first happens after the end of the flat slab episode at ∼25 Ma, and later during the buckling and stagnation of the slab in the mantle transition zone. Processes that mechanically weaken the lithosphere of the South America plate, as suggested in previous studies, enhance the intensity of the shortening events. These processes include delamination of the mantle lithosphere and weakening of foreland sediments. Our new modeling results are consistent with the timing and amplitude of the deformation from geological data in the Central Andes at the Altiplano latitude.

Description: Plain Language Summary: The Central Andes is a subduction‐type orogeny that formed as a result of the interaction between the Nazca oceanic plate and the South American continental plate over the last 50 million years. Growth of the Andes is primarily the result of crustal shortening. Nevertheless, “geological” data compiled from previous studies have shown that phases of drastic pulsatile shortening occur at 15 and 5 Ma. In this study, we used high‐resolution 2D numerical geodynamic simulations to investigate the link between oceanic and continental plate dynamics and their interaction. We find that when the oceanic plate steepens in the mantle transition zone, the trench retreat is hindered. Coupled with the weakening of the continental plate through the slab flattening and subsequent delamination of the lithospheric mantle, this leads to pulsatile shortening phases of a magnitude equivalent to that suggested by the data.

Description: Key Points: The steepening of the slab due to slab buckling hinders the trench retreating and explains the main pulsatile phases of the deformation during the last 25 Ma. The absolute motion of the overriding plate controls the regime of subduction dynamics. Flat slab and eclogitization are required to weaken and then shorten the overriding plate when the slab steepens and the trench is hindered.

Description: Deutsche Forschungsgemeinschaft http://dx.doi.org/10.13039/501100001659

Description: German Federal State of Brandenburg

Description: ERC Synergy

Description: North‐German Supercomputing Alliance

Description: https://doi.org/10.5880/GFZ.2.5.2022.001

Description: https://github.com/Minerallo/aspect/tree/Paper_slab_buckling_Andes

Description: https://doi.org/10.5880/GFZ.2.5.2022.001

Description: https://github.com/fastscape-lem/fastscapelib-fortran

Keywords: ddc:551.8 ; Central Andes ; subduction dynamics ; geodynamics ; shortening ; steepening ; flat‐slab

Language: English

Type: doc-type:article

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CITATION GEO-LEO

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3D geodynamic data-driven model of the Southern Central Andes (2023)

Pons, Michaël ; Rodriguez Piceda, Constanza ; Sobolev, Stephan ; [et al.]

GFZ Data Services

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Publication Date: 2023-07-27

Description: Abstract

Description: In the southern Central Andes (~32°S), subduction of the Nazca oceanic plate beneath the South American continental plate becomes horizontal. The growth of the Altiplano-Puna Plateau is covalently related to the southward migration of the flat subduction, but the role of subduction geometry and the plate strength on current and long-term deformation of the Andes remains poorly explored. This study takes a data-driven approach of integrating the previous structural and thermal model of the lithosphere of the southern central Andes into a 3D geodynamic model to explore the different parameters contributing to the localization of deformation. We simulate visco-plastic deformation using the geodynamic code ASPECT. The repository includes parameter files and input files for the reference model (S1) and the following alternative simulations: a series of models with variation in friction at the subduction interface (S2a-d), a series of models with variation in sedimentary strength (S3a-d), a series that studies the effect of topography (S4), and a series that studies the effect of plate velocities. In addition, a readme file gives all the instructions to run them.

Description: Methods

Description: We have built a series of 3D data-driven geodynamic model using the finite element code ASPECT (Advanced Solver for Problems in Earth's ConvecTion, version 2.3.0-pre, Kronbichler et al., 2012; Heister et al., 2017; Rose et al., 2017; Bangerth et al., 2021) to simulate brittle and ductile deformation. We have incorporated present-day compositional thicknesses, densities, and temperature fields based on lithospheric-scale models of Rodriguez Piceda et al (2020, 2021a, 2021b, 2022) and ran the simulation for 250,000 years, prescribing plate velocities of 5 cm/yr to the oceanic plate and 1 cm/yr to the continental plate (Sdrolias et al., 2006; Becker et al., 2015), with open borders on the left and right of the asthenosphere.

Keywords: Southern Andes ; Deformation ; subduction ; Geodynamic ; EARTH SCIENCE 〉 SOLID EARTH 〉 TECTONICS 〉 PLATE TECTONICS 〉 PLATE BOUNDARIES ; EARTH SCIENCE SERVICES 〉 MODELS 〉 GEOLOGIC/TECTONIC/PALEOCLIMATE MODELS

Type: Model , Model

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Controls of the Foreland Deformation Pattern in the Orogen‐Foreland Shortening System: Constraints From High‐Resolution Geodynamic Models (2022)

Liu, Sibiao ; Sobolev, Stephan V. ; Babeyko, Andrey Y. ; [et al.]

AGU (American Geophysical Union) | Wiley

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Publication Date: 2024-02-07

Description: Controls on the deformation pattern (shortening mode and tectonic style) of orogenic forelands during lithospheric shortening remain poorly understood. Here, we use high-resolution 2D thermomechanical models to demonstrate that orogenic crustal thickness and foreland lithospheric thickness significantly control the shortening mode in the foreland. Pure-shear shortening occurs when the orogenic crust is not thicker than the foreland crust or thick, but the foreland lithosphere is thin (〈70–80 km, as in the Puna foreland case). Conversely, simple-shear shortening, characterized by foreland underthrusting beneath the orogen, arises when the orogenic crust is much thicker. This thickened crust results in high gravitational potential energy in the orogen, which triggers the migration of deformation to the foreland under further shortening. Our models present fully thick-skinned, fully thin-skinned, and intermediate tectonic styles in the foreland. The first tectonics forms in a pure-shear shortening mode whereas the others require a simple-shear mode and the presence of thick (〉∼4 km) sediments that are mechanically weak (friction coefficient 〈∼0.05) or weakened rapidly during deformation. The formation of fully thin-skinned tectonics in thick and weak foreland sediments, as in the Subandean Ranges, requires the strength of the orogenic upper lithosphere to be less than one-third as strong as that of the foreland upper lithosphere. Our models successfully reproduce foreland deformation patterns in the Central and Southern Andes and the Laramide province.

Type: Article , PeerReviewed , info:eu-repo/semantics/article

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Hindered Trench Migration Due To Slab Steepening Controls the Formation of the Central Andes (2022)

Pons, Michaël ; Sobolev, Stephan V. ; Liu, Sibiao ; [et al.]

AGU | Wiley

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Publication Date: 2024-02-07

Description: The formation of the Central Andes dates back to ∼50 Ma, but its most pronounced episode, including the growth of the Altiplano-Puna Plateau and pulsatile tectonic shortening phases, occurred within the last 25 Ma. The reason for this evolution remains unexplained. Using geodynamic numerical modeling we infer that the primary cause of the pulses of tectonic shortening and growth of the Central Andes is the changing geometry of the subducted Nazca plate, and particularly the steepening of the mid-mantle slab segment which results in a slowing down of the trench retreat and subsequent increase in shortening of the advancing South America plate. This steepening first happens after the end of the flat slab episode at ∼25 Ma, and later during the buckling and stagnation of the slab in the mantle transition zone. Processes that mechanically weaken the lithosphere of the South America plate, as suggested in previous studies, enhance the intensity of the shortening events. These processes include delamination of the mantle lithosphere and weakening of foreland sediments. Our new modeling results are consistent with the timing and amplitude of the deformation from geological data in the Central Andes at the Altiplano latitude. Key Points The steepening of the slab due to slab buckling hinders the trench retreating and explains the main pulsatile phases of the deformation during the last 25 Ma The absolute motion of the overriding plate controls the regime of subduction dynamics Flat slab and eclogitization are required to weaken and then shorten the overriding plate when the slab steepens and the trench is hindered

Type: Article , PeerReviewed , info:eu-repo/semantics/article

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