Controls on the Thermomechanical Evolution of Hyperextended Lithosphere at Magma‐Poor Rifted Margins: The Example of Espirito Santo and the Kwanza Basins

Lavier, L. L.; Ball, Philip; Manatschal, Giänreto; Heumann, M. J.; MacDonald, Justin; Matt, Veit; Schneider, Craig L.

doi:10.1029/2019gc008580

Cited by 18 publications

(34 citation statements)

References 133 publications

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“…Such weak levels might have nevertheless been used as decoupling levels during convergence (Tugend et al, 2014;Manatschal et al, 2021). Models of formation of magma-poor passive margins suggest that weakening of the crust and weakening of the upper mantle by serpentinisation during extension can lead to lower crust and mantle exhumation with low-angle extensional shear zones (Lavier et al, 1999(Lavier et al, , 2019. Although large uncertainties remain on the mechanical stratification of the pre-convergence crust, it was thus probably in average rather weak with several decoupling levels and a weak upper crust.…”

Section: Crustal Root and Body Forces Rheological Issuesmentioning

confidence: 99%

Geodynamic evolution of a wide plate boundary in the Western Mediterranean, near-fieldversusfar-field interactions

Jolivet

Baudin

Calassou

et al. 2021

BSGF - Earth Sci. Bull.

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The present-day tectonic setting of the Western Mediterranean region, from the Pyrénées to the Betics and from the Alps to the Atlas, results from a complex 3-D geodynamic evolution involving the interactions between the Africa, Eurasia and Iberia plates and asthenospheric mantle dynamics underneath. In this paper, we review the main tectonic events recorded in this region since the Early Cretaceous and discuss the respective effects of far-field and near-field contributions, in order to unravel the origin of forces controlling crustal deformation. The respective contributions of mantle-scale, plate-scale and local processes in the succession of tectonic stages are discussed. Three periods can be distinguished: (1) the first period (Tethyan Tectonics), from 110 to 35 Ma, spans the main evolution of the Pyrenean orogen and the early evolution of the Betics, from rifting to maximum shortening. The rifting between Iberia and Europe and the subsequent progressive formation of new compressional plate boundaries in the Pyrénées and the Betics, as well as the compression recorded all the way to the North Sea, are placed in the large-scale framework of the African and Eurasian plates carried by large-scale mantle convection; (2) the second period (Mediterranean Tectonics), from 32 to 8 Ma, corresponds to a first-order change in subduction dynamics. It is most typically Mediterranean with a dominant contribution of slab retreat and associated mantle flow in crustal deformation. Mountain building and back-arc basin opening are controlled by retreating and tearing slabs and associated mantle flow at depth. The 3-D interactions between the different pieces of retreating slabs are complex and the crust accommodates the mantle flow underneath in various ways, including the formation of metamorphic core complexes and transfer fault zones; (3) the third period (Late-Mediterranean Tectonics) runs from 8 Ma to the Present. It corresponds to a new drastic change in the tectonic regime characterized by the resumption of N-S compression along the southern plate boundary and a propagation of compression toward the north. The respective effects of stress transmission through the lithospheric stress-guide and lithosphere-asthenosphere interactions are discussed throughout this period.

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Section: Crustal Root and Body Forces Rheological Issuesmentioning

confidence: 99%

Geodynamic evolution of a wide plate boundary in the Western Mediterranean, near-fieldversusfar-field interactions

Jolivet

Baudin

Calassou

et al. 2021

BSGF - Earth Sci. Bull.

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“…Their results show that the fluid history as well as the related temperatures were very similar between both sites, suggesting that both sites had similar high heat flow during hyperextension and mantle exhumation. Thus, the high T max values from the Pyrenean-Cantabrian domain are certainly linked to a high heat flow during hyperextension, which is to be expected in (sediment-rich) hyperextended domains and predicted by numerical modelling (e.g., Lavier et al, 2019;Lescoutre et al, 2019;. Thus, while the heat flow may have been similar to that of other hyperextended and exhumed mantle domains, the high T max values may have been anomalous in the Biscay-Pyrenean domain.…”

Section: The Thermal State Of Hyperextended Rift Basins In the Biscay-pyrenean Domain 91 Thermal Structure Of Hyperextended And Exhumed Dmentioning

confidence: 85%

The role of inheritance in forming rifts and rifted margins and building collisional orogens: a Biscay-Pyrenean perspective

Manatschal¹,

Chenin²,

Lescoutre³

et al. 2021

BSGF - Earth Sci. Bull.

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The aim of this paper is to provide a conceptual framework that integrates the role of inheritance in the study of rifts, rifted margins and collisional orogens based on the work done in the OROGEN project, which focuses on the Biscay-Pyrenean system. The Biscay-Pyrenean rift system resulted from a complex multistage rift evolution that developed over a complex lithosphere pre-structured by the Variscan orogenic cycle. There is a general agreement that the Pyrenean-Cantabrian orogen resulted from the reactivation of an increasingly mature rift system along-strike, ranging from a mature rifted margin in the west to an immature and segmented hyperextended rift in the east. However, different models have been proposed to explain the preceding syn-rift evolution and its influence on the subsequent reactivation. Results from the OROGEN project show a sequential reactivation of rift inherited decoupling horizons and identify the specific role of exhumed mantle, hyperextended and necking domains during reactivation. They also highlight the contrasting fate of segment centres vs. segment boundaries during convergence, explaining the non-cylindricity of internal parts of collisional orogens. Results from the OROGEN project also suggest that the role of inheritance is more important during the initial stages of subduction and collision, which may explain the complexity of internal parts of orogenic systems. In contrast, once tectonic systems get more mature, orogenic evolution becomes mostly controlled by first-order physical processes as described in the Coulomb Wedge theory for instance. This may account for the simpler and more continuous architecture of external parts of collisional orogens. It may also explain why most numerical models can reproduce mature orogenic and rift architectures with better accuracy compared to the initial stages of such systems. Thus, while inheritance may not explain steady-state processes, it is a prerequisite for comprehending the initial stages of tectonic systems. The new concepts developed from the OROGEN research are now ready to be tested at other orogenic systems that result from the reactivation of rifted margins, such as the Alps, the Colombian cordilleras and the Caribbean, Taiwan, Oman, Zagros or Timor.

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“…However, two mechanisms that complement each other are preferred by the community. These are the magma assisted diking or weakening of the mantle (Buck, 2006;Piccardo et al, 2007) and depth-dependent thinning (DDT) (Huismans & Beaumont, 2011;Huismans & Beaumont, 2008Kusznir et al, 2005;Lavier et al, 2019;Royden & Keen, 1980). DDT is the process by which the mantle lithosphere initially thins passively and weakens through the localization of deformation along lithosphere-scale shear zones and the upwelling of a buoyant mantle (Huismans & Beaumont, 2011).…”

Section: Introductionmentioning

confidence: 99%

“…This latter mechanism is preferred for magma poor margins where little volcanism is expressed at the rift surface before the transition to oceanic crust. Observations of exhumed or denuded mantle lithosphere in the southern European Alps (Lanzo peridotite) show that melt migration through porous mantle lithosphere at depths between 50 and 15 km can also weaken the mantle by reducing viscosity (Kaczmarek & Müntener, 2008;Piccardo et al, 2007) and likely lead to DDT (Huismans & Beaumont, 2011;Lavier et al, 2019;Ros et al, 2017;Svartman Dias et al, 2015). The mantle lithosphere in this model thins and delaminates, reducing the lithosphere's yield stress and allowing the continental rift to split the lithosphere into two plates (Davis & Kusznir, 2016;Svartman Dias et al, 2015.…”

Section: Introductionmentioning

confidence: 99%

Mantle Deformation Processes during the Rift-to-Drift Transition at Magma-Poor Margins

Montiel¹,

Masini²,

Lavier

et al. 2023

Preprint

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The rift-to-drift transition at rifted margins is an area of active investigation due to unresolved issues of the ocean-continent transition (OCT). Deep structures that characterize modern OCTs are often difficult to identify by seismic observations, while terrestrial exposures are preserved in fragments separated by tectonic discontinuities. Numerical modeling is a powerful method for contextualizing observations within rifted margin evolution. In this article, we synthesize geological observations from fossil ocean-continent transitions preserved in ophiolites, a recent seismic experiment on the Ivorian Margin of West Africa, and GeoFLAC models to characterize mantle deformation and melt production for magma-poor margins. Across varied surface heat fluxes, mantle potential temperatures, and extension rates our model results show important homologies with geological observations. We propose that the development of large shear zones in the mantle, melt infiltration, grain size reduction, and anastomosing detachment faults control the structure of OCTs. We also infer through changes in fault orientation that upwelling, melt-rich asthenosphere is an important control on the local stress environment. During the exhumation phase of rifting, continentward-dipping shear zones couple with seaward-dipping detachment faults to exhume the subcontinental and formerly asthenospheric mantle. The mantle forms into core-complex-like domes of peridotite at or near the surface. The faults that exhume these peridotite bodies are largely anastomosing and exhibit magmatic accretion in their footwalls. A combination of magmatic accretion and volcanic activity derived from the shallow melt region constructs the oceanic lithosphere in the footwalls of the out-of-sequence, continentward-dipping detachment faults in the oceanic crust and subcontinental mantle.

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Controls on the Thermomechanical Evolution of Hyperextended Lithosphere at Magma‐Poor Rifted Margins: The Example of Espirito Santo and the Kwanza Basins

Cited by 18 publications

References 133 publications

Geodynamic evolution of a wide plate boundary in the Western Mediterranean, near-fieldversusfar-field interactions

Geodynamic evolution of a wide plate boundary in the Western Mediterranean, near-fieldversusfar-field interactions

The role of inheritance in forming rifts and rifted margins and building collisional orogens: a Biscay-Pyrenean perspective

Mantle Deformation Processes during the Rift-to-Drift Transition at Magma-Poor Margins

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