Curved fold‐and‐thrust accretion during the extrusion of a synorogenic viscous allochthonous sheet: The Estepa Range (External Zones, Western Betic Cordillera, Spain)

Pedrera, Antonio; Marín‐Lechado, Carlos; Martos-Rosillo, Sergio; Roldán, Francisco Javier

doi:10.1029/2012tc003119

Cited by 20 publications

(24 citation statements)

References 130 publications

(163 reference statements)

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“…Below several Jurassic‐Cretaceous Subbetic reliefs of the more frontal part (such as Sierra de Estepa; sites 6–7, eastern profile), the resistivity profile shows additional underlying repeated sequences of more resistive Subbetic sheets separated by the conductive mélange matrix bands (clays, sandstones and gypsum). Furthermore, the Subbetic of the Estepa range has a well‐defined structure characterized by curved folds mainly developed above NW–WNW directed thrusts [ Pedrera et al , 2012]. These ranges, apparently chaotically placed within the mélange unit, were previously described as large isolated blocks floating over the plastic mélange.…”

Section: Discussionmentioning

confidence: 99%

“…The Prebetic outcrops eastward of the study area, and is characterized by a typical imbricate thrust system of para‐autochthonous shallow‐water carbonate facies with terrigenous continental deposits [ García‐Hernández et al , 1980]. The Subbetic is constituted by allocthonous pelagic units detached from its Variscan basement and was folded and thrusted under a nearly uniform WNW‐NW transport direction during Early to Middle Miocene [ Pedrera et al , 2012]. It may be subdivided into External, Median and Internal zones on the basis of paleogeographic criteria.…”

Section: Main Tectonic Complexesmentioning

confidence: 99%

“…It may be subdivided into External, Median and Internal zones on the basis of paleogeographic criteria. Accretion styles vary between the well‐structured Internal Subbetics and the more complex Median and External Subbetics [ Pedrera et al , 2012]. The accretion process induced the extrusion of a synorogenic viscous tectonic mélange mainly constituted by Triassic clays and evaporites, also including carbonate and marly Jurassic, Cretaceous, and Tertiary rocks.…”

Section: Main Tectonic Complexesmentioning

confidence: 99%

“…In the literature, the name and the processed involved in the formation of these chaotic units has been source of controversy [ Staub , 1934; Cruz‐San Julián , 1974; Pérez López and Sanz de Galdeano , 1994; Roldán García , 1995; Berástegui et al , 1998; Vera , 2004; Roldán et al , 2012]. In an attempt to unify definitions, we will refer to this unit as the frontal mélange unit [ Pedrera et al , 2012].…”

Section: Main Tectonic Complexesmentioning

confidence: 99%

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Constraints on the frontal crustal structure of a continental collision from an integrated geophysical research: The central‐western Betic Cordillera (SW Spain)

Ruíz-Constán¹,

Pedrera²,

Galindo-Zaldı́var³

et al. 2012

Geochem Geophys Geosyst

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Mélange rocks outcrop widely in the central and western frontal sectors of the Betic Cordillera, as in many other collisional orogens where they form part of the accretionary wedges. Extrusion of Triassic plastic clays and evaporites was favored by the progressive accretion of the Betic External Zones, mixing rocks of different provenance and forming a synorogenic frontal mélange unit. MT data coupled with gravity data are a valid combined methodology to characterize the geometry of these mélange units, since the characterization of plastic rocks geometry is usually uncertain using seismic techniques. The results correlate well with known geological features (sedimentary basins, calcareous ranges, evaporitic rocks) and reveal the deep geometry. A resistive body, slightly dipping toward the SE, points to the continuity of the Iberian Massif below the Guadalquivir basin (2°) and the External Zones (6–8°). To the south, gravity models show the Iberian continental crust subducting below the Internal Zones with a roughly 20–35° slope. The main conductive bodies are related to the location of evaporitic rocks involved in the frontal mélange. They overlie the Iberian Massif and, southwards, the frontal Jurassic and Cretaceous limestone sequences of the External and Median Subbetics. In this setting, thick plastic rock units placed above the foreland could act as a lubricant facilitating continental subduction, and being progressively accreted toward a frontal mélange.

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Section: Discussionmentioning

confidence: 99%

Section: Main Tectonic Complexesmentioning

confidence: 99%

Section: Main Tectonic Complexesmentioning

confidence: 99%

Section: Main Tectonic Complexesmentioning

confidence: 99%

See 2 more Smart Citations

Constraints on the frontal crustal structure of a continental collision from an integrated geophysical research: The central‐western Betic Cordillera (SW Spain)

Ruíz-Constán¹,

Pedrera²,

Galindo-Zaldı́var³

et al. 2012

Geochem Geophys Geosyst

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“…A thin-skin foldand-thrust belt developed along the South Iberian margin. Main deformation events in the western segment of the South Iberian margin range from the post-early Burdigalian to the Serravallian (Crespo- Blanco and Campos, 2001;Pedrera et al, 2012). Coeval to accretion within the frontal part of the cordillera, extension occurs at the rear of the hinterland, leading to the formation of the Alboran Basin, with an important depocenter in its western part (Comas et al, 1992(Comas et al, , 1999.…”

Section: Geological Settingmentioning

confidence: 98%

Structural controls on karstic conduits in a collisional orogen (Sierra de las Nieves, Betic Cordillera, S Spain)

et al. 2015

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Seismic transpressive basement faults and monocline development in a foreland basin (Eastern Guadalquivir, SE Spain)

et al. 2013

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We examine the late Tortonian to present‐day deformation of an active seismic sector of the eastern Iberian foreland basement of the Betic Cordillera, in southern Spain. Transpressive faults affecting Paleozoic basement offset up to Triassic rocks. Late Triassic clays and evaporites constitute a décollement level decoupling the basement rocks and a ~100 m thick cover of Jurassic carbonates. Monoclines trending NE‐SW to ENE‐WSW deform the Jurassic cover driven by the propagation of high‐angle transpressive right‐lateral basement faults. They favor the migration of clays and evaporites toward the propagated fault tip, i.e., the core of the anticline, resulting in fluid overpressure, fluid flow, and precipitation of fibrous gypsum parallel to a vertical σ3. The overall geometry of the studied monoclines, as well as the intense deformation within the clays and evaporites, reproduces three‐layer discrete element models entailing a weak middle unit sandwiched between strong layers. Late Tortonian syn‐folding sediments recorded the initial stages of the fault‐propagation folding. Equivalent unexposed transpressive structures and associated monoclines reactivated under the present‐day NW‐SE convergence are recognized and analyzed in the Sabiote‐Torreperogil region, using seismic reflection, gravity, and borehole data. A seismic series of more than 2100 low‐magnitude earthquakes was recorded within a very limited area of the basement of this sector from October 2012 to May 2013. Seismic activity within a major NE‐SW trending transpressive basement fault plane stimulated rupture along a subsidiary E‐W (~N95°E) strike‐slip relay fault. The biggest event (mbLg 3.9, MW 3.7) occurred at the junction between them in a transpressive relay sector.

show abstract

Curved fold‐and‐thrust accretion during the extrusion of a synorogenic viscous allochthonous sheet: The Estepa Range (External Zones, Western Betic Cordillera, Spain)

Cited by 20 publications

References 130 publications

Constraints on the frontal crustal structure of a continental collision from an integrated geophysical research: The central‐western Betic Cordillera (SW Spain)

Constraints on the frontal crustal structure of a continental collision from an integrated geophysical research: The central‐western Betic Cordillera (SW Spain)

Structural controls on karstic conduits in a collisional orogen (Sierra de las Nieves, Betic Cordillera, S Spain)

Seismic transpressive basement faults and monocline development in a foreland basin (Eastern Guadalquivir, SE Spain)

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