Recent and active faults and folds in the central-eastern Internal Zones of the Betic Cordillera

Pedrera, Antonio; Galindo-Zaldı́var, Jesús; Marín‐Lechado, Carlos; García-Tortosa, Francisco J.; Ruano, Patricia; Garrido, Alejandra; Azañón, José Miguel; Peláez, José A.; Giaconia, Flavio

doi:10.5209/rev_jige.2012.v38.n1.39213

Cited by 30 publications

(23 citation statements)

References 74 publications

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“…The continent to ocean transition between the Alboran and Algero-Balearic basins at the Palomares margin does not show the typical passive margin basement morphology with tilted blocks that have been recognized at nonvolcanic passive margins like the western Iberian one [e.g., Reston et al, 2007] or at the , 2012;Giaconia et al, 2012aGiaconia et al, , 2012bPedrera et al, 2012;Giaconia et al, 2013]. The set of structures is consistent with the present stress field and fits in an oblique convergence model where a NW-SE trending shortening affects the NNE-SSW oriented Palomares margin.…”

Section: The Palomares Margin In the Tectonic Evolution Of The Westersupporting

confidence: 80%

“…Main tectonic structures associated to the late Miocene (post latemost Tortonian) to present‐day compressional tectonic inversion of the Betics, Rif, Alboran, and Algero‐Balearic basins, both onshore and offshore. The fault traces and kinematic data are taken from previous authors [ Martínez‐Díaz et al , ; Booth‐Rea et al , , ; Masana et al , ; Booth‐Rea et al , ; Marín‐Lechado et al , ; Masana et al , ; Domzig et al , ; Gràcia et al , ; Pedrera et al , ; Moreno et al , ; Pedrera et al , ; Sanz de Galdeano et al , ; Gràcia et al , ; Alfaro et al , ; Pedrera et al , ; Perea et al , ; Sanz de Galdeano et al , ; Giaconia et al , ; Maillard and Mauffret , ; Martínez‐García et al , ; d'Acremont et al , ]. AbF, Abubacer fault; AlF, Al‐Idrisi fault; AMF, Alhama de Murcia fault; ARF, Alboran Ridge fault, BFS, Baza basin fault system, BSFZ, Bajo Segura fault zone; CFZ, Carboneras fault zone; GrFS, Granada basin fault system; GuFS, Guadix basin fault system; PFZ, Palomares fault zone; PoFZ, Polopos fault zone; TFZ; Terreros fault zone; XB, Xauen bank; YF, Yusuf fault.…”

Section: Discussionmentioning

confidence: 99%

“…Tectonics 10.1002/2015TC003861 Figure 2. Structural map where the main tectonic structures active during the Quaternary are shown: the Albox fault (AF), the Alhama de Murcia fault (AMF), the Carboneras fault zone (CFZ), the Palomares fault zone (PFZ), the Polopos fault zone (PoFZ), and the Terreros fault zone (TFZ) (see Figure 1 for location) [Booth-Rea et al, 2004a, 2004bMasana et al, 2004;Marín-Lechado et al, 2005;Masana et al, 2005;Gràcia et al, 2006;Pedrera et al, 2006Pedrera et al, , 2009Sanz de Galdeano et al, 2010;Booth-Rea et al, 2012;Giaconia et al, 2012aGiaconia et al, , 2012bPedrera et al, 2012;Giaconia et al, 2013]. Furthermore, focal mechanisms, local stress tensors (from both focal mechanisms and fault slickenline inversion data) [Stich et al, 2003;Fernández-Ibáñez et al, 2007;Giaconia et al, 2013], and GPS geodetic data [Echeverria et al, 2013] are shown.…”

Section: Introductionmentioning

confidence: 99%

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Compressional tectonic inversion of the Algero-Balearic basin: Latemost Miocene to present oblique convergence at the Palomares margin (Western Mediterranean)

et al. 2015

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Interpretation of new multichannel seismic reflection profiles indicates that the Palomares margin was formed by crustal-scale extension and coeval magmatic accretion during middle to late Miocene opening of the Algero-Balearic basin. The margin formed at the transition between thinned continental crust intruded by arc volcanism and back-arc oceanic crust. Deformation produced during the later positive inversion of the margin offshore and onshore is partitioned between~N50°E striking reverse faults and associated folds like the Sierra Cabrera and Abubacer anticlines and N10-20°E sinistral strike-slip faults like Palomares and Terreros faults. Parametric subbottom profiles and multibeam bathymetry offshore, structural analysis, available GPS geodetic displacement data, and earthquake focal mechanisms jointly indicate that tectonic inversion of the Palomares margin is currently active. The Palomares margin shows a structural pattern comparable to the north Maghrebian margins where Africa-Eurasia plate convergence is accommodated by NE-SW reverse faults, NNW-SSE sinistral faults, and WNW-ESE dextral ones. Contractive structures at this margin contribute to the general inversion of the Western Mediterranean since~7 Ma, coeval to inversion at the Algerian margin. Shortening at the Alboran ridge and Al-Idrisi faults occurred later, since 5 Ma, indicating a westward propagation of the compressional inversion of the Western Mediterranean.

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Section: The Palomares Margin In the Tectonic Evolution Of The Westersupporting

confidence: 80%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Compressional tectonic inversion of the Algero-Balearic basin: Latemost Miocene to present oblique convergence at the Palomares margin (Western Mediterranean)

et al. 2015

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“…10 shows they run on a horizontal profile obtained by inversion with the general GROWTH inversion method. Alignments following the NW -SE faults can be seen in these sections, according to the NNW -SSE normal faults shown by some authors (Sanz de Galdeano et al 2010;Pedrera et al, 2012). This N 140-160 E direction also coincides with old faults that occurred during the Miocene period (Martínez-Martínez and Azañón, 1997).…”

Section: Figurementioning

confidence: 86%

Structure of Alluvial Valleys from 3-D Gravity Inversion: The Low Andarax Valley (Almería, Spain) Test Case

Camacho

Carmona

García‐Jerez

et al. 2014

Pure Appl. Geophys.

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This paper presents a gravimetric study ( We interpret several low density alignments as corresponding to SE faults striking about N 140-145ºE. Some detected basement elevations (as one, previously known by boreholes, in Viator village) are apparently connected with the fault pattern. The outcomes of this work are:(1) new gravimetric data, (2) new methodological options, and (3) resulting structural conclusions.3

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“…Therefore, an important piece of the Iberian margin became part of the upper Alborán plate, hindering the ongoing subduction of the Iberian margin and promoting the transmission of collision‐related compressional stresses into the foreland since middle Miocene time. In the overriding Alborán plate, mechanical coupling caused the formation of crustal‐scale open folds, NNE‐SSW to NE‐SW left‐lateral fault mostly deforming the easternmost Betic Cordillera, and high‐dipping NW‐SE normal faults restricted to the uppermost crust and broadly distributed [e.g., Pedrera et al ., , , ]. Compressional stresses were also transmitted into the eastern part of the lower plate inducing the formation of reverse faults and related monoclines along the forebulge of the Guadalquivir Basin.…”

Section: Discussionmentioning

confidence: 99%

Deformation style and controlling geodynamic processes at the eastern Guadalquivir foreland basin (Southern Spain)

et al. 2017

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The tectonic structure of the Guadalquivir foreland basin becomes complex eastward evolving from a single depocenter to a compartmented basin. The deformation pattern within the eastern Guadalquivir foreland basin has been characterized by combining seismic reflection profiles, boreholes, and structural field data to output a 3‐D model. High‐dipping NNE‐SSW to NE‐SW trending normal and reverse fault arrays deform the Variscan basement of the basin. These faults generally affect Tortonian sediments, which show syntectonic features sealed by the latest Miocene units. Curved and S‐shaped fault traces are abundant and caused by the linkage of nearby fault segments during lateral fault propagation. Preexisting faults were reactivated either as normal or reverse faults depending on their position within the foreland. At Tortonian time, reverse faults deformed the basin forebulge, while normal faults predominated within the backbulge. Along‐strike variation of the Betic foreland basin geometry is supported by an increasing mechanical coupling of the two plates (Alborán Domain and Variscan basement) toward the eastern part of the cordillera. Thus, subduction would have progressed in the western Betics, while it would have failed in the eastern one. There, the initially subducted Iberian paleomargin (Nevado‐Filábride Complex) was incorporated into the upper plate promoting the transmission of collision‐related compressional stresses into the foreland since the middle Miocene. Nowadays, compression is still active and produces low‐magnitude earthquakes likely linked to NNE‐SSW to NE‐SW preexiting faults reactivated with reverse oblique‐slip kinematics. Seismicity is mostly concentrated around fault tips that are frequently curved in overstepping zones.

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Recent and active faults and folds in the central-eastern Internal Zones of the Betic Cordillera

Cited by 30 publications

References 74 publications

Compressional tectonic inversion of the Algero-Balearic basin: Latemost Miocene to present oblique convergence at the Palomares margin (Western Mediterranean)

Compressional tectonic inversion of the Algero-Balearic basin: Latemost Miocene to present oblique convergence at the Palomares margin (Western Mediterranean)

Structure of Alluvial Valleys from 3-D Gravity Inversion: The Low Andarax Valley (Almería, Spain) Test Case

Deformation style and controlling geodynamic processes at the eastern Guadalquivir foreland basin (Southern Spain)

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