Person:
Muñoz Martín, Alfonso

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First Name
Alfonso
Last Name
Muñoz Martín
URI
https://hdl.handle.net/20.500.14352/75220
Affiliation
Universidad Complutense de Madrid
Faculty / Institute
Ciencias Geológicas
Department
Geodinámica, Estratigrafía y Paleontología
Area
Geodinámica Interna
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1994 - 199922000 - 20093
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Author: Vicente Muñoz, Gerardo de × Start date: 1994 × Item Type: Publication × Has files: true × Subject: 551.24(234.1) ×

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Now showing 1 - 5 of 5
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    Origen y relación entre las deformaciones y esfuerzos alpinos en la zona centro-oriental de la Península Ibérica
    (Revista de la Sociedad Geológica de España, 1998) Muñoz Martín, Alfonso; Vicente Muñoz, Gerardo de
    En este trabajo se realiza una correlación entre los principales datos estructurales, cinemáticos, paleogeográficos, y de resultados de modelos de elementos finitos obtenidos en el borde oriental de la Cuenca del Tajo, con numerosos trabajos previos realizados por otros autores. La integración de estas fuentes de información ha permitido establecer una evolución conjunta para el sector centro-oriental de la placa Ibérica en dos episodios principales: a) El primero está relacionado con una fuerte actividad en el margen N de la placa Ibérica, desde los 5 1 Ma hasta los 38 Ma (Eoceno inferior - Oligoceno inferior), en la que se produciría la estructuración Pirenaica principal. Durante este periodo se desarrollarían, relacionados con el antepaís pirenaico, los siguientes cinturones de deformación bajo un campo de esfuerzos general NNE-SSO a NE-SO: la Rama Aragonesa de la Cordillera Ibérica y el sector meridional de la Sierra de Altomira y, en menor medida, la Rama Castellana de la Cordillera Ibérica y el Sistema Central. Durante el Oligoceno superior- Mioceno inferior (entre los 38 Ma y los 24 Ma) se desarrolló una etapa intermedia con actividad tectónica simultánea en los márgenes N y S de la placa Ibérica. Asociada a esta etapa se desarrolló un campo de paleoesfuerzos local compresivo E-O en la zona de antepaís común de los Pirineos y las Béticas, responsable de la estructuración principal de los sectores central y septentrional de la Sierra de Altomira. La Sierra de Altomira se interpreta como un escape o extrusión de la cobertera hacia el O, favorecido por la presencia de niveles incompetentes del Triásico superior. En este periodo comienzó también el desarrollo de la actividad extensiva en el borde oriental de la península en relación a la apertura del Golfo de Valencia. b) Finalmente, durante el Mioceno medio - actualidad, se desarrolla una mayor actividad en el margen S de la placa Ibérica (estructuración de las Cordilleras Béticas), si bien permanece una cierta actividad en el margen N, como lo demuestra la presencia de sismicidad moderada a lo largo del margen Cantábrico-Pirenaico. Durante este periodo se desarrollaron una serie de deformaciones intraplaca en el antepaís Bético bajo un campo de esfuerzos regional NO-SE: El Sistema Central y la Rama Castellana de la Cordillera Ibérica. Este proceso aparece complicado por dos procesos tectónicos que generaron extensión: 1) Al este en relación a los procesos de rifting del Golfo de Valencia, y al oeste de la Cordillera Ibérica, y a partir del Mioceno superior, en relación a flexiones corticales NE-SO transversales a la dirección regional de σ HMAX. [ABSTRACT] A correlation amongst macro and mesostructural analysis results, kinematic and paleogeographic data, paleostresses and finite element models results has been established in the eastern border of the Tajo Basin. This comparison allows us to establish an evolutionary pattern for the central part of the Iberian plate in two main episodes: a) The first one was related to a strong tectonic activity in the northern border of the Iberian plate during the Lower Eocene to the Upper Oligocene (Pirenees uplift). In this period, the following intraplate chains were formed in the Pyrenees foreland under a regional NNE-SSO compressive stress field: the Aragonian Branch of the Iberian Range and the southern part of the Altomira Range, and to a lesser extent, the Castillian Branch of the Iberian Range and the Spanish Central System. During the Upper Oligocene and Lower Miocene a transition between the two main episodes, with tectonic activity in both borders of the Iberian plate (Pyrenees and Betics), took place. Related to this episode a E-O local compressive stress field is developed in the eastern border of the Tajo Basin (Altomira Stress field). This stress field generated a N-S fold and thrust belt west verging that affected the Mesozoic cover. Thus, the Altomira Range is interpreted as a cover extrusion westwards in a regional N-S compression supported by the presence of evaporitic Upper Triassic rocks and the presence of normal basement faults. During this period extension processes in the eastern border of the Iberian plate began associated with the opening of the Valencia Through. b) Finally, from Middle Miocene to Present the main tectonic activity has been developed in the southern border of the Iberian Plate (Betics). However, sorne tectonic activity remained in the northern border of the Iberian plate as it is shown by sorne moderate seismic activity along the Pyrenees and the Cantabrian margino In this period sorne intraplate deformations were developed in the Betic foreland under a NW-SE regional stress field: Spanish Central System and the Castillian Branch of the Iberian Range. This main sketch is complicated by two different extensional processes: 1) doming related to opening of the Valencia Trough, and 2) superficial extension along NE-SO litospheric folding formed perpendicular to the regional Valencia Through. b) Finally, from Middle Miocene to Present the main tectonic activity has been developed in the southern border of the Iberian Plate (Betics). However, sorne tectonic activity remained in the northern border of the Iberian plate as it is shown by sorne moderate seismic activity along the Pyrenees and the Cantabrian margino In this period sorne intraplate deformations were developed in the Betic foreland under a NW-SE regional stress field: Spanish Central System and the Castillian Branch of the Iberian Range. This main sketch is complicated by two different extensional processes: 1) doming related to opening of the Valencia Trough, and 2) superficial extension along NE-SO litospheric folding formed perpendicular to the regional σHMAX.
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    Características de los tensores de esfuerzos activos entre la Dorsal Centroatlántica y la Península Ibérica
    (Geotemas, 2000) Vicente Muñoz, Gerardo de; Martín Velázquez, Silvia; Rodríguez Pascua, Miguel Angel; Muñoz Martín, Alfonso; Arcila, M.; Andeweg, Bernd
    The orientation of the principal stresses and the principal stress difference ratio has been determined along the southwestern boundary of the Euroasiatic plate with Northamerican and African plates by inversion method of focal mechanisms of earthquakes. The ridge push (30~ to 65Q N) ranges from E-W to ESE-WSW, with R values that show a triaxial extensional stress. The state of stress changes to strike-slip regime in the transform fault zones, and the Shmax strike turns clockwise to NW in the dextral strike-slip faults and counterclockwise to the NE in the sinistral ones. Along the margin between the Euroasiatic-African plates, from the Azores triple junction to Algeria, Shmax keeps a constant NW-SE strike but the stress ratio values range from triaxial extensional stress state, to the West, to uniaxial compresive stress state, to the East, passing through a strike-slip regime in the middle zone. In this context and with a widely NWSE Shmax, strike-slip and extensional stresses prevail in most Iberian peninsula, whereas southwards it is dominated by uniaxial compresive stresses.
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    Oblique strain partitioning and transpression on an inverted rift: The Castilian Branch of the Iberian Chain
    (Tectonophysics, 2009) Vicente Muñoz, Gerardo de; Vegas, Ramón; Muñoz Martín, Alfonso; Wees, Jan Dierik van; Casas Sáinz, Antonio; Sopeña, Alfonso; Sánchez-Moya, Yolanda; Arche, Alfredo; López Gómez, José; Olaiz Campos, Antonio José; Fernández Lozano, Javier
    The Iberian Chain is a wide intraplate deformation zone formed by the tectonic inversion during the Pyrenean orogeny of a Permian –Mesozoic basin developed in the eastern part of the Iberian Massif. The N – S convergence between Iberia and Eurasia from the Late Cretaceous to the Lower Miocene times produced signi cant intraplate deformation. The NW –SE oriented Castilian Branch of the Iberian Chain can be considered as a “key zone ” where the proposed models for the Cenozoic tectonic evolution of the Iberian Chain can be tested. Structural style of basin inversion suggests mainly strike slip d–isplacements along previous NW –SE normal faults, developed mostly during the Mesozoic. To con rm this hypothesis, structural and basin evolution analysis, macrostructural Bouguer gravity anomaly analysis, detailed mapping and paleostress inversions have been used to prove the important role of strike slip deformation. In addition, we demonstrate that two main folding trends almost perpendicular (NE SW t–o E W an–d NW SE) w–ere simultaneously active in a wide transpressive zone. The two fold trends were generated by dierent mechanical behaviour, including buckling and bending under constrictive strain conditions. We propose that strain partitioning occurred with oblique compression and transpression during the Cenozoic.
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    Cálculo de magnitudes de esfuerzos mediante elementos finitos en el macizo de El Berrocal (Sistema Central Español)
    (Boletín geológico y minero, 2005) Martín Velázquez, S.; Vicente Muñoz, Gerardo de; Elorza, F.J.; Muñoz Martín, Alfonso
    Se ha analizado la distribución de las magnitudes de esfuerzos actuales mediante el método de los elementos finitos a lo largo de una sección NO-SE transversal al macizo granítico de El Berrocal (Sistema Central Español), en la que se incluye la superficie topográfica, las variaciones litológicas y las cargas tectónicas compresivas. La estructura geológica profunda se ha obtenido a partir de una modelización gravimétrica. En un modelo sencillo, con una reología media cortical y una topografía plana, se han establecido previamente las condiciones de contorno y las propiedades mecánicas de los materiales necesarias para reproducir estados de esfuerzos litostáticos y tectónicos con elementos finitos. Aplicando una carga vertical gravitacional y una carga horizontal litostática, sólo se obtienen esfuerzos verticales iguales a los horizontales si el coeficiente de Poisson es de 0,49. Cuando se incluye además una carga tectónica se consigue un estado de esfuerzos tectónicos en régimen compresivo. Sin embargo, al modelizar el caso real del macizo de El Berrocal, la carga topográfica produce una desviación de los esfuerzos respecto al estado litostático y para obtener un régimen compresivo hay que aplicar como mínimo un empuje tectónico de 13 MPa.
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    Evolución y estructuras alpinas en la zona del centro peninsular
    (Cuadernos do Laboratorio Xeolóxico de Laxe, 1994) Vicente Muñoz, Gerardo de; González Casado, J.M.; Calvo Sorando, José Pedro; Muñoz Martín, Alfonso; Giner, J.; Rodríguez Pascua, M.A.
    In this paper we propose a model of tectonic and sedimentary evolution of the Spanish Central System, Toledo Mountains, Iberian - Altomira Ranges and Madrid Basin during the CenozoiCo This model hase been established from the analysis of: balanced cross sections, macro and microstructural data (analysis of brittle deformation) and the sedimentary record of Madrid Basin. These structural units, have been evolved during the Neogene, under the stress fields transmitted from the active Iberian Plate borders, the Betic and the Pyrenees. The superposition of these two regional stress tensors produces locally the «Altomira» stress field. The evolution and superposition of these regional stress fields is a gradual and long term process.