Impact of upper mantle convection on lithosphere hyperextension and subsequent horizontally forced subduction initiation

Candioti, Lorenzo G.; Schmalholz, Stefan M.; Duretz, Thibault

doi:10.5194/se-11-2327-2020

Cited by 9 publications

(37 citation statements)

References 106 publications

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“…(A9). Previous work has demonstrated that this choice, in combination with suitable flow law parameters, results in a viscosity structure that is consistent with geophysical constraints with respect to the convection dynamics of the mantle and the thermal thickness of the overlying, horizontal lithosphere (Candioti et al, 2020). Similar average grain sizes of the order of 1 mm in the upper mantle have been predicted by whole mantle convection models that include state-of-the-art grain size evolution models (Dannberg et al, 2017;Schierjott et al, 2020).…”

Section: Model Configurationsupporting

confidence: 62%

“…However, thermal softening, caused by shear heating, is active, resulting from the conservation of energy and temperature-dependent viscous flow stress. The algorithm has already been used to model deformation processes at various scales (Yamato et al, 2015;Duretz et al, 2016b;Yamato et al, 2019;Petri et al, 2019;Bessat et al, 2020) including upper mantle convection coupled to lithospheric-scale defor-L. G. Candioti et al: Buoyancy versus shear forces in building orogenic wedges mation (Candioti et al, 2020). Appendix A provides a detailed description of the algorithm.…”

Section: Mathematical Model and Numerical Algorithmmentioning

confidence: 99%

“…We here follow the modelling approach of Candioti et al (2020) and we employ a 1600 km wide and 680 km deep (see Fig. 2) model domain.…”

Section: Model Configurationmentioning

confidence: 99%

“…A popular geodynamic model explaining the formation of collisional orogens, such as the Western Alps, the Pyrenees or the Himalayas, is the wedge model (e.g. Chapple, 1978;Dahlen et al, 1984;Platt, 1986;Willett et al, 1993;Vanderhaeghe et al, 2003;Malavieille, 2010;Dal Zilio et al, 2020b). The first mechanical models of so-called critical wedges considered a frictional deformation (stresses are controlled by a specific yield criterion) and were L. G. Candioti et al: Buoyancy versus shear forces in building orogenic wedges originally applied to accretionary wedges.…”

Section: Introductionmentioning

confidence: 99%

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Buoyancy versus shear forces in building orogenic wedges

et al. 2021

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Abstract. The dynamics of growing collisional orogens are mainly controlled by buoyancy and shear forces. However, the relative importance of these forces, their temporal evolution and their impact on the tectonic style of orogenic wedges remain elusive. Here, we quantify buoyancy and shear forces during collisional orogeny and investigate their impact on orogenic wedge formation and exhumation of crustal rocks. We leverage two-dimensional petrological–thermomechanical numerical simulations of a long-term (ca. 170 Myr) lithosphere deformation cycle involving subsequent hyperextension, cooling, convergence, subduction and collision. Hyperextension generates a basin with exhumed continental mantle bounded by asymmetric passive margins. Before convergence, we replace the top few kilometres of the exhumed mantle with serpentinite to investigate its role during subduction and collision. We study the impact of three parameters: (1) shear resistance, or strength, of serpentinites, controlling the strength of the evolving subduction interface; (2) strength of the continental upper crust; and (3) density structure of the subducted material. Densities are determined by linearized equations of state or by petrological-phase equilibria calculations. The three parameters control the evolution of the ratio of upward-directed buoyancy force to horizontal driving force, FB/FD=ArF, which controls the mode of orogenic wedge formation: ArF≈0.5 causes thrust-sheet-dominated wedges, ArF≈0.75 causes minor wedge formation due to relamination of subducted crust below the upper plate, and ArF≈1 causes buoyancy-flow- or diapir-dominated wedges involving exhumation of crustal material from great depth (>80 km). Furthermore, employing phase equilibria density models reduces the average topography of wedges by several kilometres. We suggest that during the formation of the Pyrenees ArF⪅0.5 due to the absence of high-grade metamorphic rocks, whereas for the Alps ArF≈1 during exhumation of high-grade rocks and ArF⪅0.5 during the post-collisional stage. In the models, FD increases during wedge growth and subduction and eventually reaches magnitudes (≈18 TN m−1) which are required to initiate subduction. Such an increase in the horizontal force, required to continue driving subduction, might have “choked” the subduction of the European plate below the Adriatic one between 35 and 25 Ma and could have caused the reorganization of plate motion and subduction initiation of the Adriatic plate.

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Section: Model Configurationsupporting

confidence: 62%

Section: Mathematical Model and Numerical Algorithmmentioning

confidence: 99%

“…We here follow the modelling approach of Candioti et al (2020) and we employ a 1600 km wide and 680 km deep (see Fig. 2) model domain.…”

Section: Model Configurationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Buoyancy versus shear forces in building orogenic wedges

et al. 2021

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“…Experiments with dry dislocation creep result in extensive brittle-plastic deformation of the lithosphere 43,44 . Experiments with composite diffusion-dislocation creep and small constant grain size (1 mm) results in a lithosphere thinned by convective erosion (<90 km) driven by low asthenosphere viscosities of <10 18 Pa•s 16,45 . For constant grain sizes larger than 1 cm, dislocation creep becomes the main deformation mechanism throughout the entire upper manlte 16 .…”

Section: Effects Of Grain Size On Lithospheric Strengthmentioning

confidence: 99%

Self-Consistent Grain Size Evolution controls Strain Localization during Rifting

Ruh¹,

Tokle²

2021

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Geodynamic numerical models often employ solely grain-size-independent dislocation creep to describe upper mantle dynamics. However, observations from nature and rock deformation experiments suggest that shear zones can transition to a grain-size-dependent creep mechanism due to dynamic grain size evolution, with important implications for the overall strength of plate boundaries. We apply a two-dimensional thermo-mechanical numerical model with a composite diffusion-dislocation creep rheology coupled to a dynamic grain size evolution model based on the paleowattmeter. Results indicate average olivine grain sizes of 3–12 cm for the upper mantle below the LAB, while in the lithosphere grain size ranges from 0.3–3 mm at the Moho to 6–15 cm at the LAB. Such a grain size distribution results in dislocation creep being the dominant deformation mechanism in the upper mantle. However, deformation-related grain size reduction below 100 μm activates diffusion creep along lithospheric-scale shear zones during rifting, affecting the overall strength of tectonic plate boundaries.

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