Thermal and mechanical structure of the central Iberian Peninsula lithosphere

Tejero, Rosa; Ruíz, Javier

doi:10.1016/s0040-1951(02)00082-3

Cited by 35 publications

(75 citation statements)

References 37 publications

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“…This zone is related with instrumental seismicity of magnitude maximum as M4.2 (Escopete earthquake, 7 th June of 2007), shallow normal earthquakes (depth < 10 km) and located between the area bounded by the Tagus River and the Jarama River. This basement flexure is in agreement with the regional stress/strain tensor defined in this area by others authors De Vicente et al, 1996;Herraiz et al, 2000;Tejero and Ruiz, 2002;De Vicente et al, 2007Fernández-Lozano et al, 2011). Reverse earthquakes are deeper than normal earthquakes (16 km > depth > 10 km) in agreement with the geometry of the flexure and the strain field defined upper and down of the non deformation surface (strain deformation distribution in flexural folding with extrados/stretching and intrados/shortening).…”

Section: Discussionsupporting

confidence: 90%

“…Reverse earthquakes are deeper than normal earthquakes (16 km > depth > 10 km) in agreement with the geometry of the flexure and the strain field defined upper and down of the non deformation surface (strain deformation distribution in flexural folding with extrados/stretching and intrados/shortening). The interval of depth is according to the lower limit for the upper crust defined by Tejero and Ruiz (2002). However, new thermal models are required for describe the compressive and extensional distribution of the lithosphere within the Tagus Basin.…”

Section: Discussionmentioning

confidence: 99%

“…Thermal and rheological models for the SCS and adjacent areas were developed by Suriñach and Vegas (1988) and Tejero and Ruiz (2002), with a surface heat flow ranging between 80 and 60 mWm -2 , and with the Moho located at 31-34 km in depth. Jiménez-Díaz et al (2012) suggested a value ranging between 81-83 mWm -2 of the surface heat flow for the Tagus Basin, involving mantle processed to the continuous uplift of the SCS.…”

Section: Geodynamic and Geologic Backgroundmentioning

confidence: 99%

“…Pérez-López et al (2005) described the stress-field at the South Border of the SCS as strike-slip to uniaxial extension from Eocene to present. Martín-Velázquez et al (2009) modeled this stress-field by using finite elements and a punctual rheological model obeying the thermal model of Tejero and Ruiz (2002). The relevance of this model is the simulation of the stress state at the surface of the SCS, where the present topography plays as tectonic loading for faults.…”

Section: Geodynamic and Geologic Backgroundmentioning

confidence: 99%

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Recent tectonic model for the Upper Tagus Basin (central Spain)

Giner-Robles

Pérez‐López

Silva

et al. 2012

Journal of Iberian Geology

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Active tectonics within the Upper Tagus Basin is related to the lithospheric flexure affecting the Palaeozoic basement of the basin. This flexure displays NE-SW trending. Besides, this structure is in agreement with the regional active stress field defined by the maximum horizontal stress with NW-SE trending. In this tectonic framework, irregular clusters of instrumental seismicity (Mw< 5.0) fade in the zone bounded by the Tagus River and the Jarama River valleys. These clusters are related to major NW-SE trending faults of suspected strike-slip kinematics. Moreover, reverse faults with NE-SW trending are affected by the strike-slip system as well. Despite the reverse faults are in agreement with the present SHMAX orientation, though, they apparently are blocked as seismogenic sources (scarce instrumental seismicity recorded today). In addition, we have determined the regional and local stress/ strain fields and two different fracture patterns were observed. Hence, we have divided the area in two zones: (1) the lateral bands of the basin, defined by reverse faulting (NE-SW trending) and strike-slip faulting (NW-SE trending) and (2) the central zone of the basin characterized by shallow normal faulting and NE-SW trending strike-slip faults. Furthermore, surface faulting and liquefaction structures are described affecting Middle to Late Pleistocene fluvial deposits, suggesting intrabasinal palaeoseismic activity (5.5 < M < 6.5) during the Late Quaternary. The obtained structural and tectonic information has been used to classify and characterize the Upper Tagus Basin as a semi-stable intraplate seismogenic zone, featured by Pleistocene slip-rates < 0.02 mm/yr. This value is low but it affords the occurrence of Pleistocene paleoearthquakes.

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Section: Discussionsupporting

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: Geodynamic and Geologic Backgroundmentioning

confidence: 99%

Section: Geodynamic and Geologic Backgroundmentioning

confidence: 99%

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Recent tectonic model for the Upper Tagus Basin (central Spain)

Giner-Robles

Pérez‐López

Silva

et al. 2012

Journal of Iberian Geology

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“…The present lithospheric thickness in central Spain is arOlll1 d 110 km (Fernandez et a1. 1998;Tejero and Ruiz 2002) and the region seems to have been tectonic ally stable since Permian times. Moreover, alkaline melt generation occur red at great depth (the stability field of garnet in peridotites ranges down to around 80 km; Nickel 1986) close to the proposed lithosphere-asthenosphere boundary.…”

Section: Western Europe During Permianmentioning

confidence: 97%

Petrogenesis of Permian alkaline lamprophyres and diabases from the Spanish Central System and their geodynamic context within western Europe

García

Villaseca

Billström

et al. 2008

Contrib Mineral Petrol

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Structures and geometries of the Tajo Basin crust, Spain: Results of a magnetotelluric investigation compared to seismic and thermal models

2014

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The Tajo Basin and Betic Mountain Chain in the south central region of the Iberian Peninsula were chosen for investigation in the first phase of the magnetotelluric (MT) component of the PICASSO (Program to Investigate the Convective Alboran Sea System Overturn) project. The MT results provide information about the electrical conductivity distribution in previously unprobed subsurface regions, as well as complimenting and enhancing results of prior geological and geophysical investigations thereby enabling the definition of a petrological subsurface model and a comprehensive understanding about the tectonic setting. Two‐dimensional (2‐D) inversion of the MT data provides enhanced insight into Iberian subsurface geology in the crust. The most striking features of the final model are (i) a distinct vertical interface within the Variscan basement beneath the center of the Tajo Basin that is spatially associated with the boundary between regions with and without substantial Alpine deformation, and (ii) a middle to lower crustal conductive anomaly that can be related to remnants of asthenospheric intrusion in connection with Pliocene volcanic events in the Calatrava Volcanic Province. For the latter, effects of hydrous phases are inferred that may originate from dehydration processes within the subducting slab beneath Alboran Domain and Betic Mountain Chain.

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Thermal and mechanical structure of the central Iberian Peninsula lithosphere

Cited by 35 publications

References 37 publications

Recent tectonic model for the Upper Tagus Basin (central Spain)

Recent tectonic model for the Upper Tagus Basin (central Spain)

Petrogenesis of Permian alkaline lamprophyres and diabases from the Spanish Central System and their geodynamic context within western Europe

Structures and geometries of the Tajo Basin crust, Spain: Results of a magnetotelluric investigation compared to seismic and thermal models

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